Common UCUM units
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PublisherFHIR ProjectDescriptionCommonly encountered UCUM units (for purposes of helping populate look ups.
Expansion
| Code | Display | System |
|---|---|---|
| % | percent | http://unitsofmeasure.org |
| %/100{WBC} | percent / 100 WBC | http://unitsofmeasure.org |
| %{0to3Hours} | percent 0to3Hours | http://unitsofmeasure.org |
| %{Abnormal} | percent Abnormal | http://unitsofmeasure.org |
| %{Activity} | percent Activity | http://unitsofmeasure.org |
| %{BasalActivity} | percent BasalActivity | http://unitsofmeasure.org |
| %{Binding} | percent Binding | http://unitsofmeasure.org |
| %{Blockade} | percent Blockade | http://unitsofmeasure.org |
| %{Carboxyhemoglobin} | percent Carboxyhemoglobin | http://unitsofmeasure.org |
| %{Conversion} | percent Conversion | http://unitsofmeasure.org |
| %{Cound} | percent Cound | http://unitsofmeasure.org |
| %{EosSeen} | percent EosSeen | http://unitsofmeasure.org |
| %{Excretion} | percent Excretion | http://unitsofmeasure.org |
| %{Fat} | percent Fat | http://unitsofmeasure.org |
| %{FetalErythrocytes} | percent FetalErythrocytes | http://unitsofmeasure.org |
| %{Hemoglobin} | percent Hemoglobin | http://unitsofmeasure.org |
| %{HemoglobinA1C} | percent HemoglobinA1C | http://unitsofmeasure.org |
| %{HemoglobinSaturation} | percent HemoglobinSaturation | http://unitsofmeasure.org |
| %{Hemolysis} | percent Hemolysis | http://unitsofmeasure.org |
| %{HumanResponse} | percent HumanResponse | http://unitsofmeasure.org |
systemhttp://unitsofmeasure.org
Common UCUM units
Commonly encountered UCUM units (for purposes of helping populate look ups.
Copyright Statement:
UCUM is Copyright © 1999-2013 Regenstrief Institute, Inc. and The UCUM Organization, Indianapolis, IN. All rights reserved. See http://unitsofmeasure.org/trac//wiki/TermsOfUse for details.
This value set includes codes from the following code systems:
- Include these codes as defined in
http://unitsofmeasure.orgCode Display % percent %/100{WBC} percent / 100 WBC %{0to3Hours} percent 0to3Hours %{Abnormal} percent Abnormal %{Activity} percent Activity %{BasalActivity} percent BasalActivity %{Binding} percent Binding %{Blockade} percent Blockade %{Carboxyhemoglobin} percent Carboxyhemoglobin %{Conversion} percent Conversion %{Cound} percent Cound %{EosSeen} percent EosSeen %{Excretion} percent Excretion %{Fat} percent Fat %{FetalErythrocytes} percent FetalErythrocytes %{Hemoglobin} percent Hemoglobin %{HemoglobinA1C} percent HemoglobinA1C %{HemoglobinSaturation} percent HemoglobinSaturation %{Hemolysis} percent Hemolysis %{HumanResponse} percent HumanResponse %{Index} percent Index %{Inhibition} percent Inhibition %{Live} percent Live %{Negative Control} percent Negative Control %{Normal} percent Normal %{NormalControl} percent NormalControl %{NormalPooledPlasma} percent NormalPooledPlasma %{ofAvailable} percent ofAvailable %{ofBacteria} percent ofBacteria %{OfLymphocytes} percent OfLymphocytes %{OfWBCs} percent OfWBCs %{Oxygen} percent Oxygen %{Positive} percent Positive %{Precipitate} percent Precipitate %{Reactivity} percent Reactivity %{response} percent response %{risk} percent risk %{SpermMotility} percent SpermMotility %{Total} percent Total %{TotalProtein} percent TotalProtein %{Tot'Cholesterol} percent Tot'Cholesterol %{Tot'Hgb} percent Tot'Hgb %{Uptake} percent Uptake %{vol} VolumePercent %{WeightToWeight} percent WeightToWeight /(12.h) per 12 * hour /[arb'U] per arbitrary unit /[HPF] per high power field /[iU] per international unit /[LPF] per low power field /{Entity} per Entity /[HPF] per hpf /[LPF] per LPF /{oif} per oif /{Specimen} per Specimen /{tot} per tot /10*10 PerTenGiga /10*12 PerTrillion /10*12{rbc} PerTrillionRedBloodCells /10*6 PerMillion /10*9 PerBillion /100 per 100 /100{cells} per 100 cells /100{neutrophils} per 100 neutrophils /100{spermatozoa} per 100 spermatozoa /100{WBC} Per100WBC /100{WBCs} Per100WBC /a / year /cm[H2O] per centimeter of water /d per day /dL per deciliter /g per gram /g{creat} per gram creat /g{hgb} per gram hgb /g{tot'nit} per gram tot'nit /g{tot'prot} per gram tot'prot /g{wet'tis} per gram wet'tis /h per hour /kg per kilogram /kg{body'wt} per kilogram body wt /L per liter /m2 per square meter /mg per milligram /min per minute /mL per milliliter /mm3 per cubic millimeter /mmol per millimole /mo per month /s per second /U per enzyme unit /ug per microgram /uL per microliter /wk per week [APL'U] IgA anticardiolipin unit [APL'U]/mL IgA anticardiolipin unit per milliliter [arb'U] arbitrary unit [arb'U]/L arbitary unit / liter [arb'U]/mL arbitrary unit per milliliter [AU] allergy unit [BAU] bioequivalent allergen unit [beth'U] Bethesda unit [beth'U] Bethesda unit [CFU] colony forming unit [CFU]/L colony forming unit per liter [CFU]/mL colony forming unit per milliliter [Ch] French (catheter gauge) [cin_i] cubic inch [cup_us] cup [degF] degree Fahrenheit [dr_av] Dram (US and British) [drp] drop [drp]/[HPF] drop / HPF [drp]/h drop / hour [drp]/min drop / minute [drp]/mL drop / milliliter [drp]/s drop / second [fdr_us] fluid dram [foz_br] fluid ounce [foz_us] fluid ounce [ft_i] Feet [fth_i] fathom [gal_br] gallon [gal_us] Queen Anne's wine gallon [GPL'U] IgG anticardiolipin unit [gr] grain [in_i] inch (international) [iU] international unit [IU]/(2.h) international unit per 2 hour [IU]/(24.h) international unit per 24 hour [IU]/10*9{RBCs} international unit per billion red blood cells [IU]/d international unit per day [IU]/dL international unit per deciliter [IU]/g international unit per gram [IU]/g{Hb} international unit per gram of hemoglobin [iU]/g{Hgb} international unit / gram Hgb [IU]/h international unit per hour [IU]/kg international unit per kilogram [IU]/kg/d international unit per kilogram per day [IU]/L international unit per liter [IU]/min international unit per minute [IU]/mL international unit per milliliter [lb_av] pound (US and British) [mi_i] statute mile [mi_us] mile [min_us] minim [MPL'U] IgM anticardiolipin unit [nmi_i] nautical mile [oz_av] ounce (US and British) [oz_tr] ounce [pH] pH [pi].rad/min the number pi * radian / minute [ppb] part per billion [ppm] part per million [ppm]{v/v} part per million in volume per volume [pptr] part per trillion [ppth] parts per thousand [pptr] parts per trillion [psi] pound per square inch [pt_br] pint [qt_br] quart [qt_us] quart [sft_i] square foot (international) [sin_i] square inch (international) [ston_av] short ton U.S. ton [syd_i] square yard [tbs_us] tablespoon (US) [tb'U] tuberculin unit [todd'U] Todd unit [todd'U] Todd unit [tsp_us] teaspoon [yd_i] yard {# of calculi} # of calculi {# of donor informative markers} # of donor informative markers {# of fetuses} # of fetuses {# of informative markers} # of informative markers {#} # {2 or 3 times}/d 2 or 3 times / day {3 times}/d 3 times / day {4 times}/d 4 times / day {5 times}/d 5 times / day {absorbance} absorbance {Absorbance'U} Absorbance'U {Absorbance'U}/mL Absorbance'U / milliliter {activity} activity {ActivityCoefficient} ActivityCoefficient {AHF'U} AHF'U {AntibodyResponse'U} AntibodyResponse'U {Applicator} Applicator {APS'U} IgA antiphosphatidylserine unit {AspirinReaction'U} AspirinReaction'U {Bead} Bead {Beats}/min Beats / minute {Bottle} Bottle {Bowls}/d Bowls / day {Breaths}/min Breaths / minute {CAE'U} complement activity enzyme unit {CagRepeat} CagRepeat {Can} Can {Cans}/wk Cans / week {Capsule} Capsule {Cell} Cell {cells} cells {cells}/[HPF] cells per high power field {Cells}/mL Cells / milliliter {cells}/uL cells per microliter {CfTiter} CfTiter {cfu} cfu {cfu}/mL cfu / milliliter {CGG_repeats} CGG_repeats {CGG} CGG {CH100'U} complement CH100 unit {clock time} clock time {clock_time} clock_time {ComplementActivityEnzyme'U} ComplementActivityEnzyme'U {ComplementCH100'U} ComplementCH100'U {ComplementCH50'U} ComplementCH50'U {copies}/mL copies per milliliter {copies}/ug copies per microgram {Copies}/uL Copies / microliter {Count} Count {Counts}/min Counts / minute {Dalton} Dalton {DdTiter} DdTiter {DeltaOpticalDensity} DeltaOpticalDensity {Dilution} dilution {Disintegrations}/min Disintegrations / minute {Dose} Dose {Drinks}/d Drinks / day {Each} Each {Ehrlich'U} Ehrlich unit {Ehrlich'U}/(2.h) Ehrlich unit per 2 hour {Ehrlich'U}/100.g Ehrlich unit per 100 gram {Ehrlich'U}/d Ehrlich unit per day {Ehrlich'U}/dL Ehrilich unit per deciliter {Ehrlich'U}/mL Ehrlich'U / milliliter {EIAIndex} EIA index {EIATiter} EIA titer {EIA'U} EIA unit {EIA'U}/U EIA unit per enzyme Unit {ElisaIndex} ElisaIndex {ELISA'U} ELISA unit {Elisa'U}/mL Elisa'U / milliliter {ElisaValue} ElisaValue {ERY}/uL erythrocyte per microliter {Events} Events {FluorescenceIntensity'U} FluorescenceIntensity'U U{G} G unit {GliadinIndexValue} GliadinIndexValue {G-PortionPhospholipids} G-PortionPhospholipids {HaTiter} HaTiter {IfaIndex} IfaIndex {IfaTiter} IfaTiter {IgAAntiphosphatidyleserine'U} IgAAntiphosphatidyleserine'U {IgAPhospholipid'U} IgAPhospholipid'U {IgGAntiphosphatidyleserine'U} IgGAntiphosphatidyleserine'U {IgGIndex} IgGIndex {IgMAntiphosphatidyleserine'U} IgMAntiphosphatidyleserine'U {IgMIndex} IgMIndex {ImmuneComplex'U} immune complex unit {ImmuneStatusRatio} ImmuneStatusRatio {Immunity} Immunity {Index_val} Index_val {index} index {IndexValue} IndexValue {InhaledTobaccoUseAmountYears} InhaledTobaccoUseAmountYears {InhaledTobaccoUsePacks}/d InhaledTobaccoUsePacks / day {INR} international normalized ratio {INR'unit} INR'unit {JDF'U} Juvenile Diabetes Foundation unit {JDF'U}/L Juvenile Diabetes Foundation unit per liter {JuvenileDiabetesFound'U} JuvenileDiabetesFound'U {KCT'U} kaolin clotting time {KRONU'U}/L Kronus unit per liter {KRONU'U}/mL Kronus unit per milliliter {lgCopies}/ml lgCopies / milliliter {log_copies}/mL log (base 10) copies per milliliter {log_IU}/mL log (base 10) international unit per milliliter {LymeIndexValue} LymeIndexValue {M.o.M.} M.o.M. {M.o.M} multiple of the median {Markers} Markers {minidrp} minidrp {Molecule}/{Platelet} Molecule / Platelet {M-PortionPhospholipids} M-PortionPhospholipids {MPS'U} IgM antiphosphatidylserine unit {MPS'U}/mL IgM antiphosphatidylserine unit per milliliter {MultOfMean} MultOfMean {NonspecificOunce} NonspecificOunce {Number} Number {OD_unit} optical density unit {Once}/d Once / day {OpticalDensity} OpticalDensity {OpticalDensityIndex} OpticalDensityIndex {OpticalDensityRatio} OpticalDensityRatio {P2Y12 Reaction Units} P2Y12 Reaction Units {Package} Package {Packs}/d Packs / day {PackYears} PackYears {Patch} Patch {Percentile} Percentile {Pill} Pill {Pouches}/wk Pouches / week {RadioactiveT3UptakeRatio} RadioactiveT3UptakeRatio {ratio} ratio {RBC}/uL red blood cell per microliter {RecTiter} RecTiter {Relative'U} Relative'U {RelativeViscosity} RelativeViscosity {RPI'U} RPI'U {RubellaVirus} RubellaVirus {SatIndex} SatIndex {Scoop} Scoop {ScoreOf} ScoreOf {shift} shift {spermatozoa}/mL spermatozoa per milliliter {spray} spray {StandardDeviation} StandardDeviation {StandardIgA'U} StandardIgA'U {StandardIgG'U} StandardIgG'U {StandardIgM'U} StandardIgM'U {StdDeviation'U} StdDeviation'U {StimulatingIndex} StimulatingIndex {Streptozyme'U} Streptozyme'U {ThyroxinUptake'U} ThyroxinUptake'U {TIBC'U} TIBC'U {Times}/wk Times / week {Tine'U} Tine'U {titer} titer {ToxoplasmaIndexValue} ToxoplasmaIndexValue {Vial} Vial {Volume}/{Vvolume} Volume / Vvolume {WeeksDays} WeeksDays {WhiteBloodCell} WhiteBloodCell 1/d one per day 1/min one per minute 10*12/L trillion per liter 10*3 Thousand 10*3.{RBC} Thousand Red Blood Cells 10*3.U Thousand Per * Unit 10*3/L Thousand Per Liter 10*3/mL Thousand Per MilliLiter 10*3/uL Thousands Per MicroLiter 10*3{Copies}/mL Thousand Copies Per MilliLiter 10*-3{Polarization'U} (the number ten for arbitrary powers ^ -3) Polarization'U 10*5 OneHundredThousand 10*6 Million 10*6.[iU] MillionInternationalUnit 10*6.eq/mL MillionEquivalentsPerMilliLiter 10*6.U (the number ten for arbitrary powers ^ 6) * Unit 10*6/{Specimen} MillionPerSpecimen 10*6/kg million per kilogram 10*6/L million per liter 10*6/mL million per milliliter 10*6/mm3 (the number ten for arbitrary powers ^ 6) / (millimeter ^ 3) 10*6/uL million per microliter 10*-6{Immunofluorescence'U} (the number ten for arbitrary powers ^ -6) Immunofluorescence'U 10*8 TenToEighth 10*9/L billion per liter 10*9/mL billion per milliliter 10*9/uL billion per microliter 10.L/(min.m2) 10 liter per minute per square meter 10.L/min 10 liter per minute 10.uN.s/(cm.m2) 10 * microNewton * second / centimeter * (meter ^ 2) 10.uN.s/cm 10 * microNewton * second / centimeter 10.uN.s/cm2 10 * microNewton * second / (centimeter ^ 2) a year A/m Ampère / meter att technical atmosphere bar bar Cel degree Celsius cg centigram cL centiliter cm centimeter cm[H2O] centimeter of water cm[H2O]/(s.m) centimeter of water column / second * meter cm[H2O]/L/s centimeter of water per liter per second cm[Hg] centimeter of mercury cm2 square centimeter cm2/s square centimeter per second cm3 cubic centimeter cP centiPoise cSt centiStokes d day dB decibel deg degree deg/s degree per second dg decigram dL deciliter dm decimeter dm2/s2 square decimeter per square second eq equivalents eq/L equivalents / liter eq/mL equivalents / milliliter eq/mmol equivalents / millimole eq/umol equivalents / micromole erg erg eV electronvolt fg femtogram fL femtoliter fL/nL femtoliter / nanoliter fm femtometer fmol femtomole fmol/g femtomole per gram fmol/L femtomole per liter fmol/mg femtomole / milligram fmol/mL femtomole / milliliter g gram g.m gram * meter g.m/({hb}.m2) gram * meter / hb * (meter ^ 2) g.m/{hb} gram * meter / hb g/(100.g) gram per 100 gram g/(12.h) gram per 12 hour g/(24.h) gram per 24 hour g/(3.d) gram per 3 days g/(4.h) gram per 4 hour g/(48.h) gram per 48 hour g/(5.h) gram per 5 hour g/(6.h) gram per 6 hour g/(72.h) gram per 72 hour g/(8.h) gram / 8 * hour g/(8.kg.h) gram / 8 * kilogram * hour g/(kg.h) gram / kilogram * hour g/(kg.min) gram / kilogram * minute g/{TotalWeight} gram / TotalWeight g/d gram per day g/dL gram per deciliter g/g gram per gram g/g{Cre} gram / gram Cre g/g{creat} gram / gram creat g/g{tissue} gram per gram of tissue g/h gram per hour g/h/m2 gram per hour per square meter g/kg gram per kilogram g/kg/d gram per kilogram per day g/L gram per liter g/m2 grams Per Square Meter g/mg gram per milligram g/min gram per minute g/mL gram per milliliter g/mmol gram per millimole g/mmol{creat} gram / millimole creat g/mol gram per mole GBq gigaBecquerel h hour hL hectoliter Hz Hertz [iU] international unit J joule J/L joule per liter K Kelvin K/W Kelvin / Watt k[IU]/L kilo international unit per liter k[IU]/mL kilo international unit per milliliter kat/kg katal / kilogram kat/L katal / liter kBq kiloBecquerel kcal kilocalorie kcal/(8.h) kilocalorie / 8 * hour kcal/h kilocalorie per hour kg kilogram kg.m/s kilogram meter per second kg/(s.m2) kilogram per second per square meter kg/h kilogram per hour kg/L kilogram per liter kg/m2 kilogram / (meter ^ 2) kg/m3 kilogram / (meter ^ 3) kg/min kilogram / minute kg/mol kilogram per mole kg/s kilogram / second kL kiloliter km kilometer kPa kiloPascal ks kilosecond kU/g kiloenzyme Unit per gram kU/h kiloUnit / hour kU/L kiloenzyme Unit per liter kU/mL kilo enzyme unit per milliliter L liter L.s2/s liter * (second ^ 2) / second L/(8.h) liter per 8 hour L/(min.m2) liter per minute per square meter L/d liter per day L/h liter per hour L/kg liter per kilogram L/L liter per liter L/min liter per minute L/s liter / second lm/m2 lumen / (meter ^ 2) m meter m/s meter per second m/s2 meter per square second m[iU] milliinternational unit m[IU]/L milli international unit per liter m[IU]/mL milli international unit per milliliter m2 square meter m2/s square meter per second m3/s cubic meter per second mA milliAmpère mbar millibar mbar.s/L millibar second per liter MBq megaBecquerel mCi milliCurie meq milliequivalent meq/(12.h) milliequivalent per 12 hour meq/(2.h) milliequivalent per 2 hour meq/(24.h) milliequivalent per 24 hour meq/(8.h) milliequivalent per 8 hour meq/(8.h.kg) milliequivalents / 8 * hour * kilogram meq/(kg.d) milliequivalents / kilogram * day meq/{Specimen} milliequivalents / Specimen meq/d milliequivalent per day meq/dL milliequivalent per deciliter meq/g milliequivalent per gram meq/g{Cre} milliequivalents / gram Cre meq/h milliequivalent per hour meq/kg milliequivalent per kilogram meq/kg/h milliequivalent per kilogram per hour meq/kg/min milliequivalents / kilogram / minute meq/L milliequivalent per liter meq/m2 milliequivalent per square meter meq/min milliequivalent per minute meq/mL milliequivalent per milliliter mg milligram mg/(10.h) milligram per 10 hour mg/(12.h) milligram per 12 hour mg/(18.h) milligram per 18 hour mg/(2.h) milligram per 2 hour mg/(24.h) milligram per 24 hour mg/(72.h) milligram per 72 hour mg/(8.h) milligram per 8 hour mg/(8.h.kg) milligram / 8 * hour * kilogram mg/(kg.h) milligram / kilogram * hour mg/{Hgb}/g milligram / Hgb / gram mg/{Specimen} milligram / Specimen mg/{Tot'Volume} milligram / Tot'Volume mg/{Volume} milligram / Volume mg/d milligram per day mg/d/(173.10*-2.m2) milligram / day / 173 * (the number ten for arbitrary powers ^ -2) * (meter ^ 2) mg/dL milligram per deciliter mg/g milligram per gram mg/g{Cre} milligram / gram Cre mg/g{creat} milligram per gram of creatinine mg/h milligram per hour mg/kg milligram per kilogram mg/kg/(24.h) milligram / kilogram / 24 * hour mg/kg/d milligram per kilogram per day mg/kg/min milligram per kilogram per minute mg/L milligram per liter mg/m2 milligram per square meter mg/m3 milligram per cubic meter mg/mg milligram per milligram mg/mg{cre} milligram / milligram cre mg/min milligram per minute mg/mL milligram per milliliter mg/mmol milligram per millimole mg/mmol{Cre} milligram / millimole Cre mg/mmol{creat} milligram per millimole of creatinine mg/wk milligram per week mg{Phenylketones}/dL milligram Phenylketones / deciliter min minute mL milliliter mL/({h'b}.m2) milliliter / h'b * (meter ^ 2) mL/(10.h) milliliter per 10 hour mL/(12.h) milliliter per 12 hour mL/(2.h) milliliter per 2 hour mL/(24.h) milliliter per 24 hour mL/(4.h) milliliter per 4 hour mL/(72.h) milliliter per 72 hour mL/(8.h) milliliter per 8 hour mL/(kg.min) milliliter / kilogram * minute mL/[sin_i] milliliter per square inch (international) mL/{h'b} MilliLitersPerHeartbeat [SI Volume Units] mL/cm[H2O] milliliter / centimeter of water column mL/d milliliter per day mL/dL milliliter per deciliter mL/h milliliter per hour mL/kg milliliter per kilogram mL/kg/(8.h) milliliter per kilogram per 8 hour mL/kg/d milliliter per kilogram per day mL/kg/h milliliter per kilogram per hour mL/kg/min milliliter per kilogram per minute mL/L milliliter per liter mL/m2 milliliter per square meter mL/mbar milliliter per millibar mL/min milliliter per minute mL/min/(173.10*-2.m2) milliliter / minute / 173 * (the number ten for arbitrary powers ^ -2) * (meter ^ 2) mL/min/{1.73_m2} milliliter per minute per 1.73 square meter mL/min/m2 milliliter per minute per square meter mL/mm milliliter per millimeter mL/s milliliter per second mm millimeter mm/h millimeter per hour mm/min millimeter per minute mm[H2O] millimeter of water mm[Hg] millimeter of mercury mm2 square millimeter mm3 cubic millimeter mmol millimole mmol/(12.h) millimole per 12 hour mmol/(18.h) millimole per 18 hour mmol/(2.h) millimole per 2 hour mmol/(24.h) millimole per 24 hour mmol/(6.h) millimole per 6 hour mmol/(8.h) millimole per 8 hour mmol/(8.h.kg) millimole / 8 * hour * kilogram mmol/{Tot'Volume} millimole / Tot'Volume mmol/d millimole per day mmol/dL millimole per deciliter mmol/g millimole per gram mmol/g{creat} millimole per gram of creatinine mmol/g{hemoglobin} millimole per gram of hemoglobin mmol/h millimole per hour mmol/h/mg{Hb} millimole per hour per milligram of hemoglobin mmol/h/mg{protein} millimole per hour per milligram of protein mmol/kg millimole per kilogram mmol/kg/d millimole per kilogram per day mmol/kg/h millimole per kilogram per hour mmol/kg/min millimole per kilogram per minute mmol/kg{H2O} millimole per kilogram of water mmol/L millimole per liter mmol/L/s millimole per liter per second mmol/m millimole / meter mmol/m2 millimole per square meter mmol/min millimole per minute mmol/mmol millimole per millimole mmol/mol millimole per mole mmol/mol{creat} millimole per mole of creatinine mmol/s/L millimole per second per liter mo month mol mole mol/d mole per day mol/kg mole per kilogram mol/kg/s mole per kilogram per second mol/L mole per liter mol/m3 mole per cubic meter mol/mL mole per milliliter mol/mol mole per mole mol/mol{creat} mole / mole creat mol/s mole per second mosm milliosmole mosm/kg milliosmole per kilogram mosm/L milliosmole per liter mPa millipascal ms millisecond mU millienzyme Unit mU/g millienzyme Unit per gram mU/g{Hgb} milliUnit / gram Hgb mU/L millienzyme Unit per liter mU/mg milliUnit / milligram mU/mg{Cre} milliUnit / milligram Cre mU/min milliUnit / minute mU/mL millienzyme Unit per milliliter mU/mL/min millienzyme Unit per milliliter per minute mU/mmol{creatinine} millienzyme Unit per millimole of creatinine mU/mmol{RBCs} millienzyme Unit per millimole of red blood cells mV milliVolt N Newton N.cm Newton centimeter N.s Newton second nCi nanoCurie ng nanogram ng/(24.h) nanogram per 24 hour ng/(8.h) nanogram per 8 hour ng/(8.h.kg) nanogram / 8 * hour * kilogram ng/(kg.d) nanogram / kilogram * day ng/(kg.h) nanogram / kilogram * hour ng/(kg.min) nanogram / kilogram * minute ng/10*6 nanogram per million ng/d nanogram per day ng/dL nanogram per deciliter ng/dL/h nanogram / deciliter / hour ng/g nanogram per gram ng/g{Cre} nanogram / gram Cre ng/g{creat} nanogram per gram of creatinine ng/h nanogram per hour ng/kg nanogram per kilogram ng/kg/(8.h) nanogram per kilogram per 8 hour ng/kg/h nanogram per kilogram per hour ng/kg/min nanogram per kilogram per minute ng/L nanogram per liter ng/m2 nanogram per square meter ng/mg nanogram per milligram ng/mg/h nanogram per milligram per hour ng/mg{Protein} nanogram / milligram Protein ng/min nanogram per minute ng/mL nanogram per millliiter ng/mL/h nanogram per milliliter per hour ng/mL{rbc} nanogram / milliliter rbc ng/s nanogram per second nkat nanokatal nL nanoliter nm nanometer nm/s/L nanometer per second per liter nmol nanomole nmol/(24.h) nanomole per 24 hour nmol/d nanomole per day nmol/dL nanomole per deciliter nmol/g nanomole per gram nmol/g{Cre} nanomole / gram Cre nmol/g{creat} nanomole per gram of creatinine nmol/g{dry_wt} nanomole per gram of dry weight nmol/h/L nanomole per hour per liter nmol/h/mg{protein} nanomole per hour per milligram of protein nmol/h/mL nanomole per hour per milliliter nmol/L nanomole per liter nmol/L/mmol{creat} nanomole per liter per millimole of creatinine nmol/L/s nanomole per liter per second nmol/L{RBCs} nanomole per liter of red blood cells nmol/m/mg{protein} nanomole per meter per milligram of protein nmol/mg nanomole per milligram nmol/mg/h nanomole per milligram per hour nmol/min/mg{hemoglobin} nanomole per minute per milligram of hemoglobin nmol/min/mg{protein} nanomole per minute per milligram of protein nmol/min/mL nanomole per minute per milliliter nmol/mL nanomole per milliliter nmol/mL/h nanomole per milliliter per hour nmol/mL/min nanomole per milliliter per minute nmol/mmol nanomole per millimole nmol/mmol{Cre} nanomole / millimole Cre nmol/mmol{creat} nanomole per millimole of creatinine nmol/mol nanomole per mole nmol/nmol nanomole per nanomole nmol/s nanomole per second nmol/s/L nanomole per second per liter nmol/umol{creat} nanomole per micromole of creatinine ns nanosecond Ohm Ohm osm/kg osmole per kilogram osm/L osmole per liter Pa Pascal pg picogram pg/dL picogram per deciliter pg/L picogram per liter pg/mg picogram per milligram pg/mL picogram per milliliter pg/mm picogram per millimeter pkat picokatal pL picoliter pm picometer pmol picomole pmol/d picomole per day pmol/dL picomole per deciliter pmol/g picomole per gram pmol/h/mg{protein} picomole per hour per milligram of protein pmol/h/mL picomole per hour per milliliter pmol/L picomole per liter pmol/mg{protein} picomole per milligram of protein pmol/min picomole per minute pmol/min/mg{protein} picomole per minute per milligram of protein pmol/mL picomole per milliliter pmol/mmol picomole per millimole pmol/mmol{creat} picomole per millimole of creatinine pmol/mol picomole per mole pmol/umol picomole per micromole pmol/umol{creat} picomole per micromole of creatinine ps picosecond pT picotesla s second St Stokes t tonne U enzyme Unit U/(1.h) enzyme Unit per 1 hour U/(12.h) enzyme unit per 12 hour U/(18.h) enzyme Unit per 18 hour U/(2.h) enzyme unit per 2 hour U/(24.h) enzyme unit per 24 hour U/10*10{cells} enzyme unit per 10 billion cells U/10*12 enzyme unit per trillion U/10*6 enzyme unit per million U/10*9 enzyme unit per billion U/d enzyme unit per day U/dL enzyme unit per deciliter U/g enzyme unit per gram U/g{Cre} Unit / gram Cre U/g{Hb} enzyme unit per gram of hemoglobin U/g{hemoglobin} enzyme Unit per gram of hemoglobin U/g{Hgb} UnitsPerGramHemoglobin U/h enzyme unit per hour U/kg/h Unit / kilogram / hour U/kg{Hb} enzyme unit per kilogram of hemoglobin U/kg{hemoglobin} enzyme Unit per kilogram of hemoglobin U/L enzyme unit per liter U/min enzyme unit per minute U/mL enzyme unit per milliliter U/mL{RBC} Unit / milliliter RBC U/mL{RBCs} enzyme unit per milliliter of red blood cells U/mmol{creat} enzyme unit per millimole of creatinine U/mol enzyme Unit per mole U/s enzyme unit per second U/umol enzyme Unit per micromole u[IU] micro international unit u[IU]/L microinternational unit per liter u[IU]/mL micro international unit per milliliter ueq microequivalents ueq/L microequivalent per liter ueq/mL microequivalent per milliliter ug microgram ug/(24.h) microgram per 24 hour ug/(8.h) microgram per 8 hour ug/(kg.d) microgram / kilogram * day ug/(kg.h) microgram / kilogram * hour ug/{Specimen} microgram / Specimen ug/{TotalVolume} MicroGramsPerTotalVolume ug/d microgram per day ug/dL microgram per deciliter ug/dL{rbc} microgram / deciliter rbc ug/g microgram per gram ug/g{Cre} microgram / gram Cre ug/g{creat} microgram per gram of creatinine ug/g{DryWeight} microgram / gram DryWeight ug/g{Hgb} microgram / gram Hgb ug/g{Tissue} microgram / gram Tissue ug/h microgram per hour ug/kg microgram per kilogram ug/kg/(8.h) microgram per kilogram per 8 hour ug/kg/d microgram per kilogram per day ug/kg/h microgram per kilogram per hour ug/kg/min microgram per kilogram per minute ug/L microgram per liter ug/L/(24.h) microgram per liter per 24 hour ug/L{DDU} microgram / liter DDU ug/m2 microgram per square meter ug/mg microgram per milligram ug/mg{Cre} microgram / milligram Cre ug/mg{creat} microgram per milligram of creatinine ug/min microgram per minute ug/mL microgram per milliliter ug/mL{FEU} microgram / milliliter FEU ug/mmol microgram per millimole ug/ng microgram per nanogram ug{T4}/dL microgram T4 / deciliter ukat microkatal uL microliter uL/(2.h) microliter per 2 hour uL/h microliter per hour um micrometer um/s micrometer per second umol micromole umol/(24.h) micromole per 24 hour umol/d micromole per day umol/dL micromole per deciliter umol/g micromole per gram umol/g{Cre} micromole / gram Cre umol/g{creat} micromole per gram of creatinine umol/g{Hb} micromole per gram of hemoglobin umol/g{hemoglobin} micromole per gram of hemoglobin umol/g{Hgb} micromole / gram Hgb umol/h micromole per hour umol/h/g micromole / hour / gram umol/h/L micromole per hour per liter umol/h/mg{protein} micromole per hour per milligram of protein umol/kg micromole per kilogram umol/L micromole per liter umol/L/h micromole per liter per hour umol/L{rbc} micromole per liter of red blood cells umol/m micromole / meter umol/mg micromole per milligram umol/mg{Cre} micromole / milligram Cre umol/min micromole per minute umol/min/g micromole per minute per gram umol/min/g{prot} micromole / minute / gram prot umol/min/g{protein} micromole per minute per gram of protein umol/min/L micromole per minute per liter umol/mL micromole per milliliter umol/mL/min micromole per milliliter per minute umol/mmol micromole per millimole umol/mol micromole per mole umol/mol{Cre} micromole / mole Cre umol/mol{creat} micromole per mole of creatinine umol/mol{Hb} micromole per mole of hemoglobin umol/umol micromole per micromole uOhm microOhm us microsecond uU microUnit uU/g micro enzyme unit per gram uU/L micro enzyme unit per liter uU/mL micro enzyme unit per milliliter uV microvolt V volt wk week 10.uN.s/(cm5.m2) 10 micronewton second per centimeter to the fifth power per square meter 10*4/uL 10 thousand per microliter 24.h 24 hour A Ampère {ARU} aspirin response unit atm standard atmosphere ag/{cell} attogram per cell Bq Becquerel {binding_index} binding index [bdsk'U] Bodansky unit {CAG_repeats} CAG trinucleotide repeats cal calorie cm[H2O]/s/m centimeter of water per second per meter {delta_OD} change in (delta) optical density {copies} copies {count} count {CPM} counts per minute {CPM}/10*3{cell} counts per minute per thousand cells daL/min dekaliter per minute daL/min/m2 dekaliter per minute per square meter {dilution} dilution dyn.s/cm dyne second per centimeter dyn.s/(cm.m2) dyne second per centimeter per square meter {Ehrlich'U}/100.g Ehrlich unit per 100 gram {EIA_index} EIA index {EIA_titer} EIA titer {EV} EIA value U/10 enzyme unit per 10 U/10*10 enzyme unit per 10 billion U/(10.g){feces} enzyme unit per 10 gram of feces U/g{creat} enzyme unit per gram of creatinine U/g{protein} enzyme unit per gram of protein U{25Cel}/L enzyme unit per liter at 25 deg Celsius U{37Cel}/L enzyme unit per liter at 37 deg Celsius U/10*12{RBCs} enzyme unit per trillion red blood cells F Farad fmol/mg{cytosol_protein} femtomole per milligram of cytosol protein fmol/mg{protein} femtomole per milligram of protein {FIU} fluorescent intensity unit {fraction} fraction {GAA_repeats} GAA trinucleotide repeats {genomes}/mL genomes per milliliter {Globules}/[HPF] globules (drops) per high power field g.m/{beat} gram meter per heart beat g{creat} gram of creatinine g{Hb} gram of hemoglobin g{total_nit} gram of total nitrogen g{total_prot} gram of total protein g{wet_tissue} gram of wet tissue g/kg/(8.h) gram per kilogram per 8 hour g/(8.h){shift} gram per 8 hour shift g/cm3 gram per cubic centimeter g/g{globulin} gram per gram of globulin g/kg/(8.h){shift} gram per kilogram per 8 hour shift g/kg/h gram per kilogram per hour g/kg/min gram per kilogram per minute g/mol{creat} gram per mole of creatinine g/{specimen} gram per specimen g/{total_output} gram per total output g/{total_weight} gram per total weight Gy Gray {beats}/min heart beats per minute H Henry [HPF] high power field [GPL'U]/mL IgG anticardiolipin unit per milliliter** {GPS'U} IgG antiphosphatidylserine unit [MPL'U]/mL IgM anticardiolipin unit per milliliter** {ISR} immune status ratio {IFA_index} immunofluorescence assay index {IFA_titer} Immunofluorescence assay titer [in_i'H2O] inch (international) of water {index_val} index value {HA_titer} influenza hemagglutination titer [IU] international unit [IU]/L{37Cel} international unit per liter at 37 degrees Celsius [IU]/mg{creat} international unit per milligram of creatinine kat katal kU kilo enzyme unit kU/L{class} kilo enzyme unit per liter class kcal/d kilocalorie per day kcal/kg/(24.h) kilocalorie per kilogram per 24 hour kcal/[oz_av] kilocalorie per ounce (US & British) [ka'U] King Armstrong unit L/(24.h) liter per 24 hour L/s/s2 liter per second per square second {Log_copies}/mL log (base 10) copies per milliliter {Log_IU} log (base 10) international unit {Log_IU}/mL log (base 10) international unit per milliliter {Log} log base 10 [LPF] low power field lm lumen lm.m2 lumen square meter {Lyme_index_value} Lyme index value [mclg'U] Mac Lagan unit Ms megasecond ug/g{feces} microgram per gram of feces ug{FEU}/mL microgram fibrinogen equivalent unit per milliliter ug/(100.g) microgram per 100 gram ug/m3 microgram per cubic meter ug/dL{RBCs} microgram per deciliter of red blood cells ug/g{dry_tissue} microgram per gram of dry tissue ug/g{dry_wt} microgram per gram of dry weight ug/g{hair} microgram per gram of hair ug/g{Hb} microgram per gram of hemoglobin ug/g{tissue} microgram per gram of tissue ug/L{RBCs} microgram per liter of red blood cells ug/mL{class} microgram per milliliter class ug/mL{eqv} microgram per milliliter equivalent ug/mmol{creat} microgram per millimole of creatinine ug/{specimen} microgram per specimen ug/[sft_i] microgram per square foot (international) umol{BCE}/mol micromole bone collagen equivalent per mole umol/(2.h) micromole per 2 hour umol/(8.h) micromole per 8 hour umol/dL{GF} micromole per deciliter of glomerular filtrate umol/kg{feces} micromole per kilogram of feces umol/L{RBCs} micromole per liter of red blood cells umol/umol{creat} micromole per micromole of creatinine umol/mg{creat} micromole per milligram of creatinine umol/mmol{creat} micromole per millimole of creatinine umol/min/g{mucosa} micromole per minute per gram of mucosa mU/mmol{creat} milli enzyme unit per millimole of creatinine mU/g{Hb} milli enzyme unit per gram of hemoglobin mU/g{protein} milli enzyme unit per gram of protein mU/mg{creat} milli enzyme unit per milligram of creatinine mbar/L/s millibar per liter per second meq/g{creat} milliequivalent per gram of creatinine meq/{specimen} milliequivalent per specimen meq/{total_volume} milliequivalent per total volume mg{FEU}/L milligram fibrinogen equivalent unit per liter mg/(6.h) milligram per 6 hour mg/{collection} milligram per collection mg/d/{1.73_m2} milligram per day per 1.73 square meter mg/dL{RBCs} milligram per deciliter of red blood cells mg/g{dry_tissue} milligram per gram of dry tissue mg/g{feces} milligram per gram of feces mg/g{tissue} milligram per gram of tissue mg/g{wet_tissue} milligram per gram of wet tissue mg/kg/(8.h) milligram per kilogram per 8 hour mg/kg/h milligram per kilogram per hour mg/L{RBCs} milligram per liter of red blood cells mg/mg{creat} milligram per milligram of creatinine mg/{specimen} milligram per specimen mg/{total_output} milligram per total output mg/{total_volume} milligram per total volume mL{fetal_RBCs} milliliter of fetal red blood cells mL/(5.h) milliliter per 5 hour mL/(6.h) milliliter per 6 hour mL/{beat} milliliter per heart beat mL/{beat}/m2 milliliter per heart beat per square meter mmol/(5.h) millimole per 5 hour mmol/{ejaculate} millimole per ejaculate mmol/kg/(8.h) millimole per kilogram per 8 hour mmol/L{RBCs} millimole per liter of red blood cells mmol/mmol{urea} millimole per millimole of urea mmol/mmol{creat} millimole per millmole of creatinine mmol/{specimen} millimole per specimen mmol/{total_vol} millimole per total volume 10*6.[CFU]/L million colony forming unit per liter 10*6.[IU] million international unit 10*6/(24.h) million per 24 hour mPa.s millipascal second {minidrop}/min minidrop per minute {minidrop}/s minidrop per second {molecule}/{platelet} molecule per platelet {mm/dd/yyyy} month-day-year {mutation} mutation nU/mL nanoenzyme unit per milliliter nU/{RBC} nanoenzyme unit per red blood cell ng{FEU}/mL nanogram fibrinogen equivalent unit per milliliter ng/U nanogram per enzyme unit ng/mg{creat} nanogram per milligram of creatinine ng/mg{protein} nanogram per milligram of protein ng/mL{RBCs} nanogram per milliliter of red blood cells ng/10*6{RBCs} nanogram per million red blood cells nmol{BCE} nanomole bone collagen equivalent nmol{BCE}/L nanomole bone collagen equivalent per liter nmol{BCE}/mmol{creat} nanomole bone collagen equivalent per millimole of creatinine nmol{1/2cys}/mg{protein} nanomole of 1/2 cystine per milligram of protein nmol{ATP} nanomole of ATP nmol/dL{GF} nanomole per deciliter of glomerular filtrate nmol/mg{creat} nanomole per milligram of creatinine nmol/mg{protein} nanomole per milligram of protein nmol/mg{protein}/h nanomole per milligram of protein per hour nmol/min nanomole per minute nmol/min/mg{Hb} nanomole per minute per milligram of hemoglobin nmol/min/10*6{cells} nanomole per minute per million cells {#}/[HPF] number per high power field {#}/L number per liter {#}/[LPF] number per low power field {#}/uL number per microliter {#}/mL number per milliliter {#}/min number per minute Ohm.m Ohm meter osm osmole {Pan_Bio'U} panbio unit /10*4{RBCs} per 10 thousand red blood cells /m3 per cubic meter /{entity} per entity /g{Hb} per gram of hemoglobin /g{tot_nit} per gram of total nitrogen /g{tot_prot} per gram of total protein /g{wet_tis} per gram of wet tissue /[IU] per international unit /kg{body_wt} per kilogram of body weight /mm per millimeter /mmol{creat} per millimole of creatinine /{OIF} per oil immersion field /10*3 per thousand /10*3.{RBCs} per thousand red blood cells /10*12{RBCs} per trillion red blood cells %{loss_AChR} percent loss of acetylcholine receptor %{penetration} percent penetration %{abnormal} percent abnormal %{activity} percent activity %{aggregation} percent aggregation %{at_60_min} percent at 60 minute %{basal_activity} percent basal activity %{binding} percent binding %{blockade} percent blockade %{blocked} percent blocked %{bound} percent bound %{breakdown} percent breakdown %{deficient} percent deficient %{dose} percent dose %{excretion} percent excretion %{Hb} percent hemoglobin %{hemolysis} percent hemolysis %{index} percent index %{inhibition} percent inhibition %{loss} percent loss %{lysis} percent lysis %{normal} percent normal %{normal_pooled_plasma} percent normal pooled plasma %{bacteria} percent of bacteria %{baseline} percent of baseline %{cells} percent of cells %{RBCs} percent of red blood cells %{WBCs} percent of white blood cells %{positive} percent positive %{reactive} percent reactive %{recovery} percent recovery %{reference} percent reference %{residual} percent residual %{saturation} percent saturation %{total} percent total %{uptake} percent uptake %{viable} percent viable {percentile} percentile {phenotype} phenotype pA picoampere pg/{cell} picogram per cell pg/mg{creat} picogram per milligram of creatinine pg/{RBC} picogram per red blood cell pmol/(24.h) picomole per 24 hour pmol/{RBC} picomole per red blood cell [pt_us] pint %{relative} relative percent {relative_saturation} relative saturation {Rubella_virus} rubella virus {saturation} saturation s/{control} second per control S Siemens Sv Sievert {s_co_ratio} signal to cutoff ratio {STDV} standard deviation T Tesla 10*3{copies}/mL thousand copies per milliliter 10*3{RBCs} thousand red blood cells {TSI_index} thyroid-stimulating immunoglobulin index Wb Weber {WBCs} white blood cells 1 1* ' minute '' second %[slope] percent of slope %{Bound} PercentBound /100{Spermatozoa} Per100Spermatozoa /g{HGB} PerGramHemoglobin [acr_br] acre [acr_us] acre [Amb'a'1'U] Amb a 1 units [bbl_us] barrel [bf_i] board foot [Btu] British thermal unit [Btu_39] British thermal unit at 39 °F [Btu_59] British thermal unit at 59 °F [Btu_60] British thermal unit at 60 °F [Btu_IT] international table British thermal unit [Btu_m] mean British thermal unit [Btu_th] thermochemical British thermal unit [bu_br] bushel [bu_us] bushel [c] velocity of light [Cal] nutrition label Calories [car_Au] carat of gold alloys [car_m] metric carat [CCID_50] CELL CULTURE INFECTIOUS DOSE 50% [cft_i] cubic foot [ch_br] Gunter's chain [ch_us] Gunter's chain Surveyor's chain [cicero] cicero Didot's pica [cml_i] circular mil [cr_i] cord [crd_us] cord [cyd_i] cubic yard [D'ag'U] D-ANTIGEN UNITS [didot] didot Didot's point [diop] diopter [dpt_us] dry pint [dqt_us] dry quart [dr_ap] dram drachm [dye'U] Dye unit [e] elementary charge [eps_0] permittivity of vacuum [fdr_br] fluid dram [FFU] FOCUS-FORMING UNITS [ft_br] foot [ft_us] foot [fth_br] fathom [fth_us] fathom [fur_us] furlong [G] Newtonian constant of gravitation [gal_wi] historical winchester gallon [gil_br] gill [gil_us] gill [h] Planck constant [hd_i] hand [hnsf'U] Hounsfield unit [HP] horsepower [hp_C] HOMEOPATHIC POTENCY OF CENTESIMAL SERIES [hp_M] HOMEOPATHIC POTENCY OF MILLESIMAL SERIES [hp_Q] HOMEOPATHIC POTENCY OF QUINTAMILLESIMAL SERIES [hp_X] HOMEOPATHIC POTENCY OF DECIMAL SERIES [in_br] inch [in_i'Hg] inch of mercury column [in_us] inch [iU]/dL InternationalUnitsPerDeciLiter [iU]/g InternationalUnitsPerGram [iU]/kg InternationalUnitsPerKilogram [iU]/L InternationalUnitsPerLiter [iU]/mL InternationalUnitsPerMilliLiter [k] Boltzmann constant [kn_br] knot [kn_i] knot [knk'U] Kunkel unit [lb_ap] pound [lb_tr] pound [lbf_av] pound force [lcwt_av] long hunderdweight British hundredweight [Lf] LIMIT OF FLOCCULATION [ligne] ligne French line [lk_br] link for Gunter's chain [lk_us] link for Gunter's chain [lne] line [lton_av] long ton British ton [ly] light-year [m_e] electron mass [m_p] proton mass [mesh_i] mesh [MET] metabolic equivalent [mi_br] mile [mil_i] mil [mil_us] mil [min_br] minim [mu_0] permeability of vacuum [nmi_br] nautical mile [oz_ap] ounce (US and British) [pc_br] pace [pca] pica [pca_pr] Printer's pica [p'diop] prism diopter [PFU] PLAQUE-FORMING UNITS [pi] the number pi [pied] pied French foot [pk_br] peck [pk_us] peck [pnt] point [pnt_pr] Printer's point [PNU] PROTEIN NITROGEN UNITS [pouce] pouce French inch [PRU] peripheral vascular resistance unit [pwt_tr] pennyweight [rch_us] Ramden's chain Engineer's chain [rd_br] rod [rd_us] rod [rlk_us] link for Ramden's chain [S] Svedberg unit [sc_ap] scruple [sct] section [scwt_av] short hundredweight U.S. hundredweight [smgy'U] Somogyi unit [smi_us] square mile [smoot] Smoot [srd_us] square rod [stone_av] stone British stone [TCID_50] TISSUE CULTURE INFECTIOUS DOSE 50% [twp] township [USP'U] UNITED STATES PHARMACOPEIA UNIT [yd_br] yard [yd_us] yard {Cells}/uL CellsPerMicroLiter {Copies}/mL CopiesPerMilliLiter {Ct} crossing threshold {Ehrlich_U}/dL EhrlichUnitsPerDeciLiter {EhrlichU}/dL EhrlichUnitsPerDeciLiter [Arbitrary Concentration Units] {Elisa_U}/mL ElisaUnitsPerMilliLiter {ElisaU}/mL ElisaUnitsPerMilliLiter [Arbitrary Concentration Units] {kp_C} HOMEOPATHIC POTENCY OF CENTESIMAL KORSAKOVIAN SERIES {rbc} red blood cell count {Spermatozoa}/mL SpermatozoaPerMilliLiter {tbl} tablets {tot} particles total count 10* the number ten for arbitrary powers 10^ the number ten for arbitrary powers a_g mean Gregorian year a_j mean Julian year a_t tropical year Ao Ångström ar are AU astronomic unit b barn B bel B[kW] bel kilowatt B[mV] bel millivolt B[SPL] bel sound pressure B[uV] bel microvolt B[V] bel volt B[W] bel watt Bd baud Bi Biot bit bit bit_s bit By byte C Coulomb cal_[15] calorie at 15 °C cal_[20] calorie at 20 °C cal_IT international table calorie cal_m mean calorie cal_th thermochemical calorie cd candela Ci CURIE circ circle dyn dyne G Gauss g% gram percent g.m/{H.B.} gram meter per heartbeat Gal Gal Gb Gilbert gf gram-force gon gon grade k[iU]/mL KiloInternationalUnitsPerMilliLiter kg{wet'tis} kilogram of wet tissue Ky Kayser Lmb Lambert lx lux m[H2O] meter of water column m[Hg] meter of mercury column mg/{TotalVolume} MilliGramPerTotalVolume mg/mg{Cre} MilligramsPerMilligramCreatinine mg{creat} milligram of creatinine mho mho mmol/{TotalVolume} MilliMolesPerTotalVolume [Substance Units] mmol/mol{Cre} MilliMolesPerMoleCreatinine mo_g mean Gregorian month mo_j mean Julian month mo_s synodal month Mx Maxwell Np neper Oe Oersted P Poise pc parsec ph phot R Roentgen rad radian RAD radiation absorbed dose REM radiation equivalent man sb stilb sph spere sr steradian st stere u unified atomic mass unit uCi MICROCURIE W Watt
{
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"lastUpdated" : "2019-11-01T09:29:23.356+11:00"
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"publisher" : "FHIR Project",
"name" : "Common UCUM units",
"copyright" : "UCUM is Copyright © 1999-2013 Regenstrief Institute, Inc. and The UCUM Organization, Indianapolis, IN. All rights reserved. See http://unitsofmeasure.org/trac//wiki/TermsOfUse for details.",
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"div" : "<div xmlns=\"http://www.w3.org/1999/xhtml\">\n \n <h2>Common UCUM units</h2>\n \n <div>\n \n <p>Commonly encountered UCUM units (for purposes of helping populate look ups.</p>\n\n \n </div>\n \n <p>\n \n <b>Copyright Statement:</b>\n \n </p>\n \n <div>\n \n <p>UCUM is Copyright © 1999-2013 Regenstrief Institute, Inc. and The UCUM Organization, Indianapolis, IN. All rights reserved. See http://unitsofmeasure.org/trac//wiki/TermsOfUse for details.</p>\n\n \n </div>\n \n <p>This value set includes codes from the following code systems:</p>\n \n <ul>\n \n <li>Include these codes as defined in \n \n <a href=\"http://unitsofmeasure.org\">\n \n <code>http://unitsofmeasure.org</code>\n \n </a>\n \n <table class=\"none\">\n \n <tr>\n \n <td style=\"white-space:nowrap\">\n \n <b>Code</b>\n \n </td>\n \n <td>\n \n <b>Display</b>\n \n </td>\n \n </tr>\n \n <tr>\n \n <td>%</td>\n \n <td>percent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%/100{WBC}</td>\n \n <td>percent / 100 WBC</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{0to3Hours}</td>\n \n <td>percent 0to3Hours</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Abnormal}</td>\n \n <td>percent Abnormal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Activity}</td>\n \n <td>percent Activity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{BasalActivity}</td>\n \n <td>percent BasalActivity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Binding}</td>\n \n <td>percent Binding</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Blockade}</td>\n \n <td>percent Blockade</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Carboxyhemoglobin}</td>\n \n <td>percent Carboxyhemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Conversion}</td>\n \n <td>percent Conversion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Cound}</td>\n \n <td>percent Cound</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{EosSeen}</td>\n \n <td>percent EosSeen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Excretion}</td>\n \n <td>percent Excretion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Fat}</td>\n \n <td>percent Fat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{FetalErythrocytes}</td>\n \n <td>percent FetalErythrocytes</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Hemoglobin}</td>\n \n <td>percent Hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{HemoglobinA1C}</td>\n \n <td>percent HemoglobinA1C</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{HemoglobinSaturation}</td>\n \n <td>percent HemoglobinSaturation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Hemolysis}</td>\n \n <td>percent Hemolysis</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{HumanResponse}</td>\n \n <td>percent HumanResponse</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Index}</td>\n \n <td>percent Index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Inhibition}</td>\n \n <td>percent Inhibition</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Live}</td>\n \n <td>percent Live</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Negative Control}</td>\n \n <td>percent Negative Control</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Normal}</td>\n \n <td>percent Normal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{NormalControl}</td>\n \n <td>percent NormalControl</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{NormalPooledPlasma}</td>\n \n <td>percent NormalPooledPlasma</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{ofAvailable}</td>\n \n <td>percent ofAvailable</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{ofBacteria}</td>\n \n <td>percent ofBacteria</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{OfLymphocytes}</td>\n \n <td>percent OfLymphocytes</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{OfWBCs}</td>\n \n <td>percent OfWBCs</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Oxygen}</td>\n \n <td>percent Oxygen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Positive}</td>\n \n <td>percent Positive</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Precipitate}</td>\n \n <td>percent Precipitate</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Reactivity}</td>\n \n <td>percent Reactivity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{response}</td>\n \n <td>percent response</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{risk}</td>\n \n <td>percent risk</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{SpermMotility}</td>\n \n <td>percent SpermMotility</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Total}</td>\n \n <td>percent Total</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{TotalProtein}</td>\n \n <td>percent TotalProtein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Tot'Cholesterol}</td>\n \n <td>percent Tot'Cholesterol</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Tot'Hgb}</td>\n \n <td>percent Tot'Hgb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Uptake}</td>\n \n <td>percent Uptake</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{vol}</td>\n \n <td>VolumePercent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{WeightToWeight}</td>\n \n <td>percent WeightToWeight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/(12.h)</td>\n \n <td>per 12 * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[arb'U]</td>\n \n <td>per arbitrary unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[HPF]</td>\n \n <td>per high power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[iU]</td>\n \n <td>per international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[LPF]</td>\n \n <td>per low power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/{Entity}</td>\n \n <td>per Entity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[HPF]</td>\n \n <td>per hpf</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[LPF]</td>\n \n <td>per LPF</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/{oif}</td>\n \n <td>per oif</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/{Specimen}</td>\n \n <td>per Specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/{tot}</td>\n \n <td>per tot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*10</td>\n \n <td>PerTenGiga</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*12</td>\n \n <td>PerTrillion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*12{rbc}</td>\n \n <td>PerTrillionRedBloodCells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*6</td>\n \n <td>PerMillion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*9</td>\n \n <td>PerBillion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100</td>\n \n <td>per 100</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100{cells}</td>\n \n <td>per 100 cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100{neutrophils}</td>\n \n <td>per 100 neutrophils</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100{spermatozoa}</td>\n \n <td>per 100 spermatozoa</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100{WBC}</td>\n \n <td>Per100WBC</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100{WBCs}</td>\n \n <td>Per100WBC</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/a</td>\n \n <td>/ year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/cm[H2O]</td>\n \n <td>per centimeter of water</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/d</td>\n \n <td>per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/dL</td>\n \n <td>per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g</td>\n \n <td>per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{creat}</td>\n \n <td>per gram creat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{hgb}</td>\n \n <td>per gram hgb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{tot'nit}</td>\n \n <td>per gram tot'nit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{tot'prot}</td>\n \n <td>per gram tot'prot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{wet'tis}</td>\n \n <td>per gram wet'tis</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/h</td>\n \n <td>per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/kg</td>\n \n <td>per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/kg{body'wt}</td>\n \n <td>per kilogram body wt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/L</td>\n \n <td>per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/m2</td>\n \n <td>per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mg</td>\n \n <td>per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/min</td>\n \n <td>per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mL</td>\n \n <td>per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mm3</td>\n \n <td>per cubic millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mmol</td>\n \n <td>per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mo</td>\n \n <td>per month</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/s</td>\n \n <td>per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/U</td>\n \n <td>per enzyme unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/ug</td>\n \n <td>per microgram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/uL</td>\n \n <td>per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/wk</td>\n \n <td>per week</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[APL'U]</td>\n \n <td>IgA anticardiolipin unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[APL'U]/mL</td>\n \n <td>IgA anticardiolipin unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[arb'U]</td>\n \n <td>arbitrary unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[arb'U]/L</td>\n \n <td>arbitary unit / liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[arb'U]/mL</td>\n \n <td>arbitrary unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[AU]</td>\n \n <td>allergy unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[BAU]</td>\n \n <td>bioequivalent allergen unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[beth'U]</td>\n \n <td>Bethesda unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[beth'U]</td>\n \n <td>Bethesda unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[CFU]</td>\n \n <td>colony forming unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[CFU]/L</td>\n \n <td>colony forming unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[CFU]/mL</td>\n \n <td>colony forming unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Ch]</td>\n \n <td>French (catheter gauge)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cin_i]</td>\n \n <td>cubic inch</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cup_us]</td>\n \n <td>cup</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[degF]</td>\n \n <td>degree Fahrenheit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[dr_av]</td>\n \n <td>Dram (US and British)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[drp]</td>\n \n <td>drop</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[drp]/[HPF]</td>\n \n <td>drop / HPF</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[drp]/h</td>\n \n <td>drop / hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[drp]/min</td>\n \n <td>drop / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[drp]/mL</td>\n \n <td>drop / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[drp]/s</td>\n \n <td>drop / second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[fdr_us]</td>\n \n <td>fluid dram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[foz_br]</td>\n \n <td>fluid ounce</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[foz_us]</td>\n \n <td>fluid ounce</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ft_i]</td>\n \n <td>Feet</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[fth_i]</td>\n \n <td>fathom</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[gal_br]</td>\n \n <td>gallon</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[gal_us]</td>\n \n <td>Queen Anne's wine gallon</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[GPL'U]</td>\n \n <td>IgG anticardiolipin unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[gr]</td>\n \n <td>grain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[in_i]</td>\n \n <td>inch (international)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]</td>\n \n <td>international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/(2.h)</td>\n \n <td>international unit per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/(24.h)</td>\n \n <td>international unit per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/10*9{RBCs}</td>\n \n <td>international unit per billion red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/d</td>\n \n <td>international unit per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/dL</td>\n \n <td>international unit per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/g</td>\n \n <td>international unit per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/g{Hb}</td>\n \n <td>international unit per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]/g{Hgb}</td>\n \n <td>international unit / gram Hgb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/h</td>\n \n <td>international unit per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/kg</td>\n \n <td>international unit per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/kg/d</td>\n \n <td>international unit per kilogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/L</td>\n \n <td>international unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/min</td>\n \n <td>international unit per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/mL</td>\n \n <td>international unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lb_av]</td>\n \n <td>pound (US and British)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mi_i]</td>\n \n <td>statute mile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mi_us]</td>\n \n <td>mile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[min_us]</td>\n \n <td>minim</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[MPL'U]</td>\n \n <td>IgM anticardiolipin unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[nmi_i]</td>\n \n <td>nautical mile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[oz_av]</td>\n \n <td>ounce (US and British)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[oz_tr]</td>\n \n <td>ounce</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pH]</td>\n \n <td>pH</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pi].rad/min</td>\n \n <td>the number pi * radian / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ppb]</td>\n \n <td>part per billion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ppm]</td>\n \n <td>part per million</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ppm]{v/v}</td>\n \n <td>part per million in volume per volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pptr]</td>\n \n <td>part per trillion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ppth]</td>\n \n <td>parts per thousand</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pptr]</td>\n \n <td>parts per trillion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[psi]</td>\n \n <td>pound per square inch</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pt_br]</td>\n \n <td>pint</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[qt_br]</td>\n \n <td>quart</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[qt_us]</td>\n \n <td>quart</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[sft_i]</td>\n \n <td>square foot (international)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[sin_i]</td>\n \n <td>square inch (international)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ston_av]</td>\n \n <td>short ton U.S. ton</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[syd_i]</td>\n \n <td>square yard</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[tbs_us]</td>\n \n <td>tablespoon (US)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[tb'U]</td>\n \n <td>tuberculin unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[todd'U]</td>\n \n <td>Todd unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[todd'U]</td>\n \n <td>Todd unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[tsp_us]</td>\n \n <td>teaspoon</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[yd_i]</td>\n \n <td>yard</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{# of calculi}</td>\n \n <td># of calculi</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{# of donor informative markers}</td>\n \n <td># of donor informative markers</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{# of fetuses}</td>\n \n <td># of fetuses</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{# of informative markers}</td>\n \n <td># of informative markers</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}</td>\n \n <td>#</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{2 or 3 times}/d</td>\n \n <td>2 or 3 times / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{3 times}/d</td>\n \n <td>3 times / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{4 times}/d</td>\n \n <td>4 times / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{5 times}/d</td>\n \n <td>5 times / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{absorbance}</td>\n \n <td>absorbance</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Absorbance'U}</td>\n \n <td>Absorbance'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Absorbance'U}/mL</td>\n \n <td>Absorbance'U / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{activity}</td>\n \n <td>activity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ActivityCoefficient}</td>\n \n <td>ActivityCoefficient</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{AHF'U}</td>\n \n <td>AHF'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{AntibodyResponse'U}</td>\n \n <td>AntibodyResponse'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Applicator}</td>\n \n <td>Applicator</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{APS'U}</td>\n \n <td>IgA antiphosphatidylserine unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{AspirinReaction'U}</td>\n \n <td>AspirinReaction'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Bead}</td>\n \n <td>Bead</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Beats}/min</td>\n \n <td>Beats / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Bottle}</td>\n \n <td>Bottle</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Bowls}/d</td>\n \n <td>Bowls / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Breaths}/min</td>\n \n <td>Breaths / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CAE'U}</td>\n \n <td>complement activity enzyme unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CagRepeat}</td>\n \n <td>CagRepeat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Can}</td>\n \n <td>Can</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Cans}/wk</td>\n \n <td>Cans / week</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Capsule}</td>\n \n <td>Capsule</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Cell}</td>\n \n <td>Cell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{cells}</td>\n \n <td>cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{cells}/[HPF]</td>\n \n <td>cells per high power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Cells}/mL</td>\n \n <td>Cells / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{cells}/uL</td>\n \n <td>cells per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CfTiter}</td>\n \n <td>CfTiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{cfu}</td>\n \n <td>cfu</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{cfu}/mL</td>\n \n <td>cfu / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CGG_repeats}</td>\n \n <td>CGG_repeats</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CGG}</td>\n \n <td>CGG</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CH100'U}</td>\n \n <td>complement CH100 unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{clock time}</td>\n \n <td>clock time</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{clock_time}</td>\n \n <td>clock_time</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ComplementActivityEnzyme'U}</td>\n \n <td>ComplementActivityEnzyme'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ComplementCH100'U}</td>\n \n <td>ComplementCH100'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ComplementCH50'U}</td>\n \n <td>ComplementCH50'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{copies}/mL</td>\n \n <td>copies per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{copies}/ug</td>\n \n <td>copies per microgram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Copies}/uL</td>\n \n <td>Copies / microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Count}</td>\n \n <td>Count</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Counts}/min</td>\n \n <td>Counts / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Dalton}</td>\n \n <td>Dalton</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{DdTiter}</td>\n \n <td>DdTiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{DeltaOpticalDensity}</td>\n \n <td>DeltaOpticalDensity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Dilution}</td>\n \n <td>dilution</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Disintegrations}/min</td>\n \n <td>Disintegrations / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Dose}</td>\n \n <td>Dose</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Drinks}/d</td>\n \n <td>Drinks / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Each}</td>\n \n <td>Each</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}</td>\n \n <td>Ehrlich unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}/(2.h)</td>\n \n <td>Ehrlich unit per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}/100.g</td>\n \n <td>Ehrlich unit per 100 gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}/d</td>\n \n <td>Ehrlich unit per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}/dL</td>\n \n <td>Ehrilich unit per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}/mL</td>\n \n <td>Ehrlich'U / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EIAIndex}</td>\n \n <td>EIA index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EIATiter}</td>\n \n <td>EIA titer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EIA'U}</td>\n \n <td>EIA unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EIA'U}/U</td>\n \n <td>EIA unit per enzyme Unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ElisaIndex}</td>\n \n <td>ElisaIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ELISA'U}</td>\n \n <td>ELISA unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Elisa'U}/mL</td>\n \n <td>Elisa'U / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ElisaValue}</td>\n \n <td>ElisaValue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ERY}/uL</td>\n \n <td>erythrocyte per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Events}</td>\n \n <td>Events</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{FluorescenceIntensity'U}</td>\n \n <td>FluorescenceIntensity'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U{G}</td>\n \n <td>G unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{GliadinIndexValue}</td>\n \n <td>GliadinIndexValue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{G-PortionPhospholipids}</td>\n \n <td>G-PortionPhospholipids</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{HaTiter}</td>\n \n <td>HaTiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IfaIndex}</td>\n \n <td>IfaIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IfaTiter}</td>\n \n <td>IfaTiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IgAAntiphosphatidyleserine'U}</td>\n \n <td>IgAAntiphosphatidyleserine'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IgAPhospholipid'U}</td>\n \n <td>IgAPhospholipid'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IgGAntiphosphatidyleserine'U}</td>\n \n <td>IgGAntiphosphatidyleserine'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IgGIndex}</td>\n \n <td>IgGIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IgMAntiphosphatidyleserine'U}</td>\n \n <td>IgMAntiphosphatidyleserine'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IgMIndex}</td>\n \n <td>IgMIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ImmuneComplex'U}</td>\n \n <td>immune complex unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ImmuneStatusRatio}</td>\n \n <td>ImmuneStatusRatio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Immunity}</td>\n \n <td>Immunity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Index_val}</td>\n \n <td>Index_val</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{index}</td>\n \n <td>index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IndexValue}</td>\n \n <td>IndexValue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{InhaledTobaccoUseAmountYears}</td>\n \n <td>InhaledTobaccoUseAmountYears</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{InhaledTobaccoUsePacks}/d</td>\n \n <td>InhaledTobaccoUsePacks / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{INR}</td>\n \n <td>international normalized ratio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{INR'unit}</td>\n \n <td>INR'unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{JDF'U}</td>\n \n <td>Juvenile Diabetes Foundation unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{JDF'U}/L</td>\n \n <td>Juvenile Diabetes Foundation unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{JuvenileDiabetesFound'U}</td>\n \n <td>JuvenileDiabetesFound'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{KCT'U}</td>\n \n <td>kaolin clotting time</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{KRONU'U}/L</td>\n \n <td>Kronus unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{KRONU'U}/mL</td>\n \n <td>Kronus unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{lgCopies}/ml</td>\n \n <td>lgCopies / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{log_copies}/mL</td>\n \n <td>log (base 10) copies per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{log_IU}/mL</td>\n \n <td>log (base 10) international unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{LymeIndexValue}</td>\n \n <td>LymeIndexValue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{M.o.M.}</td>\n \n <td>M.o.M.</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{M.o.M}</td>\n \n <td>multiple of the median</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Markers}</td>\n \n <td>Markers</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{minidrp}</td>\n \n <td>minidrp</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Molecule}/{Platelet}</td>\n \n <td>Molecule / Platelet</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{M-PortionPhospholipids}</td>\n \n <td>M-PortionPhospholipids</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{MPS'U}</td>\n \n <td>IgM antiphosphatidylserine unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{MPS'U}/mL</td>\n \n <td>IgM antiphosphatidylserine unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{MultOfMean}</td>\n \n <td>MultOfMean</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{NonspecificOunce}</td>\n \n <td>NonspecificOunce</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Number}</td>\n \n <td>Number</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{OD_unit}</td>\n \n <td>optical density unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Once}/d</td>\n \n <td>Once / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{OpticalDensity}</td>\n \n <td>OpticalDensity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{OpticalDensityIndex}</td>\n \n <td>OpticalDensityIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{OpticalDensityRatio}</td>\n \n <td>OpticalDensityRatio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{P2Y12 Reaction Units}</td>\n \n <td>P2Y12 Reaction Units</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Package}</td>\n \n <td>Package</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Packs}/d</td>\n \n <td>Packs / day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{PackYears}</td>\n \n <td>PackYears</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Patch}</td>\n \n <td>Patch</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Percentile}</td>\n \n <td>Percentile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Pill}</td>\n \n <td>Pill</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Pouches}/wk</td>\n \n <td>Pouches / week</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{RadioactiveT3UptakeRatio}</td>\n \n <td>RadioactiveT3UptakeRatio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ratio}</td>\n \n <td>ratio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{RBC}/uL</td>\n \n <td>red blood cell per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{RecTiter}</td>\n \n <td>RecTiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Relative'U}</td>\n \n <td>Relative'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{RelativeViscosity}</td>\n \n <td>RelativeViscosity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{RPI'U}</td>\n \n <td>RPI'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{RubellaVirus}</td>\n \n <td>RubellaVirus</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{SatIndex}</td>\n \n <td>SatIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Scoop}</td>\n \n <td>Scoop</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ScoreOf}</td>\n \n <td>ScoreOf</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{shift}</td>\n \n <td>shift</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{spermatozoa}/mL</td>\n \n <td>spermatozoa per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{spray}</td>\n \n <td>spray</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{StandardDeviation}</td>\n \n <td>StandardDeviation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{StandardIgA'U}</td>\n \n <td>StandardIgA'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{StandardIgG'U}</td>\n \n <td>StandardIgG'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{StandardIgM'U}</td>\n \n <td>StandardIgM'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{StdDeviation'U}</td>\n \n <td>StdDeviation'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{StimulatingIndex}</td>\n \n <td>StimulatingIndex</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Streptozyme'U}</td>\n \n <td>Streptozyme'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ThyroxinUptake'U}</td>\n \n <td>ThyroxinUptake'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{TIBC'U}</td>\n \n <td>TIBC'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Times}/wk</td>\n \n <td>Times / week</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Tine'U}</td>\n \n <td>Tine'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{titer}</td>\n \n <td>titer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ToxoplasmaIndexValue}</td>\n \n <td>ToxoplasmaIndexValue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Vial}</td>\n \n <td>Vial</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Volume}/{Vvolume}</td>\n \n <td>Volume / Vvolume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{WeeksDays}</td>\n \n <td>WeeksDays</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{WhiteBloodCell}</td>\n \n <td>WhiteBloodCell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>1/d</td>\n \n <td>one per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>1/min</td>\n \n <td>one per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*12/L</td>\n \n <td>trillion per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3</td>\n \n <td>Thousand</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3.{RBC}</td>\n \n <td>Thousand Red Blood Cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3.U</td>\n \n <td>Thousand Per * Unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3/L</td>\n \n <td>Thousand Per Liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3/mL</td>\n \n <td>Thousand Per MilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3/uL</td>\n \n <td>Thousands Per MicroLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3{Copies}/mL</td>\n \n <td>Thousand Copies Per MilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*-3{Polarization'U}</td>\n \n <td>(the number ten for arbitrary powers ^ -3) Polarization'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*5</td>\n \n <td>OneHundredThousand</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6</td>\n \n <td>Million</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6.[iU]</td>\n \n <td>MillionInternationalUnit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6.eq/mL</td>\n \n <td>MillionEquivalentsPerMilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6.U</td>\n \n <td>(the number ten for arbitrary powers ^ 6) * Unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/{Specimen}</td>\n \n <td>MillionPerSpecimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/kg</td>\n \n <td>million per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/L</td>\n \n <td>million per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/mL</td>\n \n <td>million per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/mm3</td>\n \n <td>(the number ten for arbitrary powers ^ 6) / (millimeter ^ 3)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/uL</td>\n \n <td>million per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*-6{Immunofluorescence'U}</td>\n \n <td>(the number ten for arbitrary powers ^ -6) Immunofluorescence'U</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*8</td>\n \n <td>TenToEighth</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*9/L</td>\n \n <td>billion per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*9/mL</td>\n \n <td>billion per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*9/uL</td>\n \n <td>billion per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10.L/(min.m2)</td>\n \n <td>10 liter per minute per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10.L/min</td>\n \n <td>10 liter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10.uN.s/(cm.m2)</td>\n \n <td>10 * microNewton * second / centimeter * (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10.uN.s/cm</td>\n \n <td>10 * microNewton * second / centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10.uN.s/cm2</td>\n \n <td>10 * microNewton * second / (centimeter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>a</td>\n \n <td>year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>A/m</td>\n \n <td>Ampère / meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>att</td>\n \n <td>technical atmosphere</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>bar</td>\n \n <td>bar</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Cel</td>\n \n <td>degree Celsius</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cg</td>\n \n <td>centigram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cL</td>\n \n <td>centiliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm</td>\n \n <td>centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm[H2O]</td>\n \n <td>centimeter of water</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm[H2O]/(s.m)</td>\n \n <td>centimeter of water column / second * meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm[H2O]/L/s</td>\n \n <td>centimeter of water per liter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm[Hg]</td>\n \n <td>centimeter of mercury</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm2</td>\n \n <td>square centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm2/s</td>\n \n <td>square centimeter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm3</td>\n \n <td>cubic centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cP</td>\n \n <td>centiPoise</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cSt</td>\n \n <td>centiStokes</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>d</td>\n \n <td>day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dB</td>\n \n <td>decibel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>deg</td>\n \n <td>degree</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>deg/s</td>\n \n <td>degree per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dg</td>\n \n <td>decigram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dL</td>\n \n <td>deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dm</td>\n \n <td>decimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dm2/s2</td>\n \n <td>square decimeter per square second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>eq</td>\n \n <td>equivalents</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>eq/L</td>\n \n <td>equivalents / liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>eq/mL</td>\n \n <td>equivalents / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>eq/mmol</td>\n \n <td>equivalents / millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>eq/umol</td>\n \n <td>equivalents / micromole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>erg</td>\n \n <td>erg</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>eV</td>\n \n <td>electronvolt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fg</td>\n \n <td>femtogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fL</td>\n \n <td>femtoliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fL/nL</td>\n \n <td>femtoliter / nanoliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fm</td>\n \n <td>femtometer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol</td>\n \n <td>femtomole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol/g</td>\n \n <td>femtomole per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol/L</td>\n \n <td>femtomole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol/mg</td>\n \n <td>femtomole / milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol/mL</td>\n \n <td>femtomole / milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g</td>\n \n <td>gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g.m</td>\n \n <td>gram * meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g.m/({hb}.m2)</td>\n \n <td>gram * meter / hb * (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g.m/{hb}</td>\n \n <td>gram * meter / hb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(100.g)</td>\n \n <td>gram per 100 gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(12.h)</td>\n \n <td>gram per 12 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(24.h)</td>\n \n <td>gram per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(3.d)</td>\n \n <td>gram per 3 days</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(4.h)</td>\n \n <td>gram per 4 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(48.h)</td>\n \n <td>gram per 48 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(5.h)</td>\n \n <td>gram per 5 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(6.h)</td>\n \n <td>gram per 6 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(72.h)</td>\n \n <td>gram per 72 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(8.h)</td>\n \n <td>gram / 8 * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(8.kg.h)</td>\n \n <td>gram / 8 * kilogram * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(kg.h)</td>\n \n <td>gram / kilogram * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(kg.min)</td>\n \n <td>gram / kilogram * minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/{TotalWeight}</td>\n \n <td>gram / TotalWeight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/d</td>\n \n <td>gram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/dL</td>\n \n <td>gram per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/g</td>\n \n <td>gram per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/g{Cre}</td>\n \n <td>gram / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/g{creat}</td>\n \n <td>gram / gram creat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/g{tissue}</td>\n \n <td>gram per gram of tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/h</td>\n \n <td>gram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/h/m2</td>\n \n <td>gram per hour per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/kg</td>\n \n <td>gram per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/kg/d</td>\n \n <td>gram per kilogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/L</td>\n \n <td>gram per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/m2</td>\n \n <td>grams Per Square Meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/mg</td>\n \n <td>gram per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/min</td>\n \n <td>gram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/mL</td>\n \n <td>gram per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/mmol</td>\n \n <td>gram per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/mmol{creat}</td>\n \n <td>gram / millimole creat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/mol</td>\n \n <td>gram per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>GBq</td>\n \n <td>gigaBecquerel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>h</td>\n \n <td>hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>hL</td>\n \n <td>hectoliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Hz</td>\n \n <td>Hertz</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]</td>\n \n <td>international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>J</td>\n \n <td>joule</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>J/L</td>\n \n <td>joule per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>K</td>\n \n <td>Kelvin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>K/W</td>\n \n <td>Kelvin / Watt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>k[IU]/L</td>\n \n <td>kilo international unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>k[IU]/mL</td>\n \n <td>kilo international unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kat/kg</td>\n \n <td>katal / kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kat/L</td>\n \n <td>katal / liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kBq</td>\n \n <td>kiloBecquerel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kcal</td>\n \n <td>kilocalorie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kcal/(8.h)</td>\n \n <td>kilocalorie / 8 * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kcal/h</td>\n \n <td>kilocalorie per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg</td>\n \n <td>kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg.m/s</td>\n \n <td>kilogram meter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/(s.m2)</td>\n \n <td>kilogram per second per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/h</td>\n \n <td>kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/L</td>\n \n <td>kilogram per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/m2</td>\n \n <td>kilogram / (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/m3</td>\n \n <td>kilogram / (meter ^ 3)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/min</td>\n \n <td>kilogram / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/mol</td>\n \n <td>kilogram per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg/s</td>\n \n <td>kilogram / second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kL</td>\n \n <td>kiloliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>km</td>\n \n <td>kilometer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kPa</td>\n \n <td>kiloPascal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ks</td>\n \n <td>kilosecond</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kU/g</td>\n \n <td>kiloenzyme Unit per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kU/h</td>\n \n <td>kiloUnit / hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kU/L</td>\n \n <td>kiloenzyme Unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kU/mL</td>\n \n <td>kilo enzyme unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L</td>\n \n <td>liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L.s2/s</td>\n \n <td>liter * (second ^ 2) / second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/(8.h)</td>\n \n <td>liter per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/(min.m2)</td>\n \n <td>liter per minute per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/d</td>\n \n <td>liter per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/h</td>\n \n <td>liter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/kg</td>\n \n <td>liter per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/L</td>\n \n <td>liter per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/min</td>\n \n <td>liter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/s</td>\n \n <td>liter / second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>lm/m2</td>\n \n <td>lumen / (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m</td>\n \n <td>meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m/s</td>\n \n <td>meter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m/s2</td>\n \n <td>meter per square second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m[iU]</td>\n \n <td>milliinternational unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m[IU]/L</td>\n \n <td>milli international unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m[IU]/mL</td>\n \n <td>milli international unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m2</td>\n \n <td>square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m2/s</td>\n \n <td>square meter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m3/s</td>\n \n <td>cubic meter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mA</td>\n \n <td>milliAmpère</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mbar</td>\n \n <td>millibar</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mbar.s/L</td>\n \n <td>millibar second per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>MBq</td>\n \n <td>megaBecquerel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mCi</td>\n \n <td>milliCurie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq</td>\n \n <td>milliequivalent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/(12.h)</td>\n \n <td>milliequivalent per 12 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/(2.h)</td>\n \n <td>milliequivalent per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/(24.h)</td>\n \n <td>milliequivalent per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/(8.h)</td>\n \n <td>milliequivalent per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/(8.h.kg)</td>\n \n <td>milliequivalents / 8 * hour * kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/(kg.d)</td>\n \n <td>milliequivalents / kilogram * day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/{Specimen}</td>\n \n <td>milliequivalents / Specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/d</td>\n \n <td>milliequivalent per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/dL</td>\n \n <td>milliequivalent per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/g</td>\n \n <td>milliequivalent per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/g{Cre}</td>\n \n <td>milliequivalents / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/h</td>\n \n <td>milliequivalent per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/kg</td>\n \n <td>milliequivalent per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/kg/h</td>\n \n <td>milliequivalent per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/kg/min</td>\n \n <td>milliequivalents / kilogram / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/L</td>\n \n <td>milliequivalent per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/m2</td>\n \n <td>milliequivalent per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/min</td>\n \n <td>milliequivalent per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/mL</td>\n \n <td>milliequivalent per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg</td>\n \n <td>milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(10.h)</td>\n \n <td>milligram per 10 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(12.h)</td>\n \n <td>milligram per 12 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(18.h)</td>\n \n <td>milligram per 18 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(2.h)</td>\n \n <td>milligram per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(24.h)</td>\n \n <td>milligram per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(72.h)</td>\n \n <td>milligram per 72 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(8.h)</td>\n \n <td>milligram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(8.h.kg)</td>\n \n <td>milligram / 8 * hour * kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(kg.h)</td>\n \n <td>milligram / kilogram * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{Hgb}/g</td>\n \n <td>milligram / Hgb / gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{Specimen}</td>\n \n <td>milligram / Specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{Tot'Volume}</td>\n \n <td>milligram / Tot'Volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{Volume}</td>\n \n <td>milligram / Volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/d</td>\n \n <td>milligram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/d/(173.10*-2.m2)</td>\n \n <td>milligram / day / 173 * (the number ten for arbitrary powers ^ -2) * (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/dL</td>\n \n <td>milligram per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g</td>\n \n <td>milligram per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g{Cre}</td>\n \n <td>milligram / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g{creat}</td>\n \n <td>milligram per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/h</td>\n \n <td>milligram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/kg</td>\n \n <td>milligram per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/kg/(24.h)</td>\n \n <td>milligram / kilogram / 24 * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/kg/d</td>\n \n <td>milligram per kilogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/kg/min</td>\n \n <td>milligram per kilogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/L</td>\n \n <td>milligram per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/m2</td>\n \n <td>milligram per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/m3</td>\n \n <td>milligram per cubic meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mg</td>\n \n <td>milligram per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mg{cre}</td>\n \n <td>milligram / milligram cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/min</td>\n \n <td>milligram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mL</td>\n \n <td>milligram per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mmol</td>\n \n <td>milligram per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mmol{Cre}</td>\n \n <td>milligram / millimole Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mmol{creat}</td>\n \n <td>milligram per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/wk</td>\n \n <td>milligram per week</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg{Phenylketones}/dL</td>\n \n <td>milligram Phenylketones / deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>min</td>\n \n <td>minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL</td>\n \n <td>milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/({h'b}.m2)</td>\n \n <td>milliliter / h'b * (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(10.h)</td>\n \n <td>milliliter per 10 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(12.h)</td>\n \n <td>milliliter per 12 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(2.h)</td>\n \n <td>milliliter per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(24.h)</td>\n \n <td>milliliter per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(4.h)</td>\n \n <td>milliliter per 4 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(72.h)</td>\n \n <td>milliliter per 72 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(8.h)</td>\n \n <td>milliliter per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(kg.min)</td>\n \n <td>milliliter / kilogram * minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/[sin_i]</td>\n \n <td>milliliter per square inch (international)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/{h'b}</td>\n \n <td>MilliLitersPerHeartbeat [SI Volume Units]</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/cm[H2O]</td>\n \n <td>milliliter / centimeter of water column</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/d</td>\n \n <td>milliliter per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/dL</td>\n \n <td>milliliter per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/h</td>\n \n <td>milliliter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/kg</td>\n \n <td>milliliter per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/kg/(8.h)</td>\n \n <td>milliliter per kilogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/kg/d</td>\n \n <td>milliliter per kilogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/kg/h</td>\n \n <td>milliliter per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/kg/min</td>\n \n <td>milliliter per kilogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/L</td>\n \n <td>milliliter per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/m2</td>\n \n <td>milliliter per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/mbar</td>\n \n <td>milliliter per millibar</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/min</td>\n \n <td>milliliter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/min/(173.10*-2.m2)</td>\n \n <td>milliliter / minute / 173 * (the number ten for arbitrary powers ^ -2) * (meter ^ 2)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/min/{1.73_m2}</td>\n \n <td>milliliter per minute per 1.73 square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/min/m2</td>\n \n <td>milliliter per minute per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/mm</td>\n \n <td>milliliter per millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/s</td>\n \n <td>milliliter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm</td>\n \n <td>millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm/h</td>\n \n <td>millimeter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm/min</td>\n \n <td>millimeter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm[H2O]</td>\n \n <td>millimeter of water</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm[Hg]</td>\n \n <td>millimeter of mercury</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm2</td>\n \n <td>square millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mm3</td>\n \n <td>cubic millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol</td>\n \n <td>millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(12.h)</td>\n \n <td>millimole per 12 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(18.h)</td>\n \n <td>millimole per 18 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(2.h)</td>\n \n <td>millimole per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(24.h)</td>\n \n <td>millimole per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(6.h)</td>\n \n <td>millimole per 6 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(8.h)</td>\n \n <td>millimole per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(8.h.kg)</td>\n \n <td>millimole / 8 * hour * kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/{Tot'Volume}</td>\n \n <td>millimole / Tot'Volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/d</td>\n \n <td>millimole per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/dL</td>\n \n <td>millimole per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/g</td>\n \n <td>millimole per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/g{creat}</td>\n \n <td>millimole per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/g{hemoglobin}</td>\n \n <td>millimole per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/h</td>\n \n <td>millimole per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/h/mg{Hb}</td>\n \n <td>millimole per hour per milligram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/h/mg{protein}</td>\n \n <td>millimole per hour per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/kg</td>\n \n <td>millimole per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/kg/d</td>\n \n <td>millimole per kilogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/kg/h</td>\n \n <td>millimole per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/kg/min</td>\n \n <td>millimole per kilogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/kg{H2O}</td>\n \n <td>millimole per kilogram of water</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/L</td>\n \n <td>millimole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/L/s</td>\n \n <td>millimole per liter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/m</td>\n \n <td>millimole / meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/m2</td>\n \n <td>millimole per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/min</td>\n \n <td>millimole per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/mmol</td>\n \n <td>millimole per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/mol</td>\n \n <td>millimole per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/mol{creat}</td>\n \n <td>millimole per mole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/s/L</td>\n \n <td>millimole per second per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mo</td>\n \n <td>month</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol</td>\n \n <td>mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/d</td>\n \n <td>mole per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/kg</td>\n \n <td>mole per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/kg/s</td>\n \n <td>mole per kilogram per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/L</td>\n \n <td>mole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/m3</td>\n \n <td>mole per cubic meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/mL</td>\n \n <td>mole per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/mol</td>\n \n <td>mole per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/mol{creat}</td>\n \n <td>mole / mole creat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mol/s</td>\n \n <td>mole per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mosm</td>\n \n <td>milliosmole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mosm/kg</td>\n \n <td>milliosmole per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mosm/L</td>\n \n <td>milliosmole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mPa</td>\n \n <td>millipascal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ms</td>\n \n <td>millisecond</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU</td>\n \n <td>millienzyme Unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/g</td>\n \n <td>millienzyme Unit per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/g{Hgb}</td>\n \n <td>milliUnit / gram Hgb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/L</td>\n \n <td>millienzyme Unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mg</td>\n \n <td>milliUnit / milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mg{Cre}</td>\n \n <td>milliUnit / milligram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/min</td>\n \n <td>milliUnit / minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mL</td>\n \n <td>millienzyme Unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mL/min</td>\n \n <td>millienzyme Unit per milliliter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mmol{creatinine}</td>\n \n <td>millienzyme Unit per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mmol{RBCs}</td>\n \n <td>millienzyme Unit per millimole of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mV</td>\n \n <td>milliVolt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>N</td>\n \n <td>Newton</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>N.cm</td>\n \n <td>Newton centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>N.s</td>\n \n <td>Newton second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nCi</td>\n \n <td>nanoCurie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng</td>\n \n <td>nanogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/(24.h)</td>\n \n <td>nanogram per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/(8.h)</td>\n \n <td>nanogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/(8.h.kg)</td>\n \n <td>nanogram / 8 * hour * kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/(kg.d)</td>\n \n <td>nanogram / kilogram * day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/(kg.h)</td>\n \n <td>nanogram / kilogram * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/(kg.min)</td>\n \n <td>nanogram / kilogram * minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/10*6</td>\n \n <td>nanogram per million</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/d</td>\n \n <td>nanogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/dL</td>\n \n <td>nanogram per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/dL/h</td>\n \n <td>nanogram / deciliter / hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/g</td>\n \n <td>nanogram per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/g{Cre}</td>\n \n <td>nanogram / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/g{creat}</td>\n \n <td>nanogram per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/h</td>\n \n <td>nanogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/kg</td>\n \n <td>nanogram per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/kg/(8.h)</td>\n \n <td>nanogram per kilogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/kg/h</td>\n \n <td>nanogram per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/kg/min</td>\n \n <td>nanogram per kilogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/L</td>\n \n <td>nanogram per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/m2</td>\n \n <td>nanogram per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mg</td>\n \n <td>nanogram per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mg/h</td>\n \n <td>nanogram per milligram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mg{Protein}</td>\n \n <td>nanogram / milligram Protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/min</td>\n \n <td>nanogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mL</td>\n \n <td>nanogram per millliiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mL/h</td>\n \n <td>nanogram per milliliter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mL{rbc}</td>\n \n <td>nanogram / milliliter rbc</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/s</td>\n \n <td>nanogram per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nkat</td>\n \n <td>nanokatal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nL</td>\n \n <td>nanoliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nm</td>\n \n <td>nanometer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nm/s/L</td>\n \n <td>nanometer per second per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol</td>\n \n <td>nanomole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/(24.h)</td>\n \n <td>nanomole per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/d</td>\n \n <td>nanomole per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/dL</td>\n \n <td>nanomole per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/g</td>\n \n <td>nanomole per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/g{Cre}</td>\n \n <td>nanomole / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/g{creat}</td>\n \n <td>nanomole per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/g{dry_wt}</td>\n \n <td>nanomole per gram of dry weight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/h/L</td>\n \n <td>nanomole per hour per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/h/mg{protein}</td>\n \n <td>nanomole per hour per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/h/mL</td>\n \n <td>nanomole per hour per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/L</td>\n \n <td>nanomole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/L/mmol{creat}</td>\n \n <td>nanomole per liter per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/L/s</td>\n \n <td>nanomole per liter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/L{RBCs}</td>\n \n <td>nanomole per liter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/m/mg{protein}</td>\n \n <td>nanomole per meter per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mg</td>\n \n <td>nanomole per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mg/h</td>\n \n <td>nanomole per milligram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/min/mg{hemoglobin}</td>\n \n <td>nanomole per minute per milligram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/min/mg{protein}</td>\n \n <td>nanomole per minute per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/min/mL</td>\n \n <td>nanomole per minute per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mL</td>\n \n <td>nanomole per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mL/h</td>\n \n <td>nanomole per milliliter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mL/min</td>\n \n <td>nanomole per milliliter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mmol</td>\n \n <td>nanomole per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mmol{Cre}</td>\n \n <td>nanomole / millimole Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mmol{creat}</td>\n \n <td>nanomole per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mol</td>\n \n <td>nanomole per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/nmol</td>\n \n <td>nanomole per nanomole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/s</td>\n \n <td>nanomole per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/s/L</td>\n \n <td>nanomole per second per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/umol{creat}</td>\n \n <td>nanomole per micromole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ns</td>\n \n <td>nanosecond</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Ohm</td>\n \n <td>Ohm</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>osm/kg</td>\n \n <td>osmole per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>osm/L</td>\n \n <td>osmole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Pa</td>\n \n <td>Pascal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg</td>\n \n <td>picogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/dL</td>\n \n <td>picogram per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/L</td>\n \n <td>picogram per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/mg</td>\n \n <td>picogram per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/mL</td>\n \n <td>picogram per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/mm</td>\n \n <td>picogram per millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pkat</td>\n \n <td>picokatal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pL</td>\n \n <td>picoliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pm</td>\n \n <td>picometer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol</td>\n \n <td>picomole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/d</td>\n \n <td>picomole per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/dL</td>\n \n <td>picomole per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/g</td>\n \n <td>picomole per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/h/mg{protein}</td>\n \n <td>picomole per hour per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/h/mL</td>\n \n <td>picomole per hour per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/L</td>\n \n <td>picomole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/mg{protein}</td>\n \n <td>picomole per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/min</td>\n \n <td>picomole per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/min/mg{protein}</td>\n \n <td>picomole per minute per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/mL</td>\n \n <td>picomole per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/mmol</td>\n \n <td>picomole per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/mmol{creat}</td>\n \n <td>picomole per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/mol</td>\n \n <td>picomole per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/umol</td>\n \n <td>picomole per micromole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/umol{creat}</td>\n \n <td>picomole per micromole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ps</td>\n \n <td>picosecond</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pT</td>\n \n <td>picotesla</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>s</td>\n \n <td>second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>St</td>\n \n <td>Stokes</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>t</td>\n \n <td>tonne</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U</td>\n \n <td>enzyme Unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/(1.h)</td>\n \n <td>enzyme Unit per 1 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/(12.h)</td>\n \n <td>enzyme unit per 12 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/(18.h)</td>\n \n <td>enzyme Unit per 18 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/(2.h)</td>\n \n <td>enzyme unit per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/(24.h)</td>\n \n <td>enzyme unit per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10*10{cells}</td>\n \n <td>enzyme unit per 10 billion cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10*12</td>\n \n <td>enzyme unit per trillion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10*6</td>\n \n <td>enzyme unit per million</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10*9</td>\n \n <td>enzyme unit per billion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/d</td>\n \n <td>enzyme unit per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/dL</td>\n \n <td>enzyme unit per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g</td>\n \n <td>enzyme unit per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g{Cre}</td>\n \n <td>Unit / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g{Hb}</td>\n \n <td>enzyme unit per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g{hemoglobin}</td>\n \n <td>enzyme Unit per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g{Hgb}</td>\n \n <td>UnitsPerGramHemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/h</td>\n \n <td>enzyme unit per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/kg/h</td>\n \n <td>Unit / kilogram / hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/kg{Hb}</td>\n \n <td>enzyme unit per kilogram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/kg{hemoglobin}</td>\n \n <td>enzyme Unit per kilogram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/L</td>\n \n <td>enzyme unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/min</td>\n \n <td>enzyme unit per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/mL</td>\n \n <td>enzyme unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/mL{RBC}</td>\n \n <td>Unit / milliliter RBC</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/mL{RBCs}</td>\n \n <td>enzyme unit per milliliter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/mmol{creat}</td>\n \n <td>enzyme unit per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/mol</td>\n \n <td>enzyme Unit per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/s</td>\n \n <td>enzyme unit per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/umol</td>\n \n <td>enzyme Unit per micromole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>u[IU]</td>\n \n <td>micro international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>u[IU]/L</td>\n \n <td>microinternational unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>u[IU]/mL</td>\n \n <td>micro international unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ueq</td>\n \n <td>microequivalents</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ueq/L</td>\n \n <td>microequivalent per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ueq/mL</td>\n \n <td>microequivalent per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug</td>\n \n <td>microgram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/(24.h)</td>\n \n <td>microgram per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/(8.h)</td>\n \n <td>microgram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/(kg.d)</td>\n \n <td>microgram / kilogram * day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/(kg.h)</td>\n \n <td>microgram / kilogram * hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/{Specimen}</td>\n \n <td>microgram / Specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/{TotalVolume}</td>\n \n <td>MicroGramsPerTotalVolume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/d</td>\n \n <td>microgram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/dL</td>\n \n <td>microgram per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/dL{rbc}</td>\n \n <td>microgram / deciliter rbc</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g</td>\n \n <td>microgram per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{Cre}</td>\n \n <td>microgram / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{creat}</td>\n \n <td>microgram per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{DryWeight}</td>\n \n <td>microgram / gram DryWeight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{Hgb}</td>\n \n <td>microgram / gram Hgb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{Tissue}</td>\n \n <td>microgram / gram Tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/h</td>\n \n <td>microgram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/kg</td>\n \n <td>microgram per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/kg/(8.h)</td>\n \n <td>microgram per kilogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/kg/d</td>\n \n <td>microgram per kilogram per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/kg/h</td>\n \n <td>microgram per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/kg/min</td>\n \n <td>microgram per kilogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/L</td>\n \n <td>microgram per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/L/(24.h)</td>\n \n <td>microgram per liter per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/L{DDU}</td>\n \n <td>microgram / liter DDU</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/m2</td>\n \n <td>microgram per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mg</td>\n \n <td>microgram per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mg{Cre}</td>\n \n <td>microgram / milligram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mg{creat}</td>\n \n <td>microgram per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/min</td>\n \n <td>microgram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mL</td>\n \n <td>microgram per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mL{FEU}</td>\n \n <td>microgram / milliliter FEU</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mmol</td>\n \n <td>microgram per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/ng</td>\n \n <td>microgram per nanogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug{T4}/dL</td>\n \n <td>microgram T4 / deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ukat</td>\n \n <td>microkatal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uL</td>\n \n <td>microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uL/(2.h)</td>\n \n <td>microliter per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uL/h</td>\n \n <td>microliter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>um</td>\n \n <td>micrometer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>um/s</td>\n \n <td>micrometer per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol</td>\n \n <td>micromole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/(24.h)</td>\n \n <td>micromole per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/d</td>\n \n <td>micromole per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/dL</td>\n \n <td>micromole per deciliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/g</td>\n \n <td>micromole per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/g{Cre}</td>\n \n <td>micromole / gram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/g{creat}</td>\n \n <td>micromole per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/g{Hb}</td>\n \n <td>micromole per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/g{hemoglobin}</td>\n \n <td>micromole per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/g{Hgb}</td>\n \n <td>micromole / gram Hgb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/h</td>\n \n <td>micromole per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/h/g</td>\n \n <td>micromole / hour / gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/h/L</td>\n \n <td>micromole per hour per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/h/mg{protein}</td>\n \n <td>micromole per hour per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/kg</td>\n \n <td>micromole per kilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/L</td>\n \n <td>micromole per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/L/h</td>\n \n <td>micromole per liter per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/L{rbc}</td>\n \n <td>micromole per liter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/m</td>\n \n <td>micromole / meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mg</td>\n \n <td>micromole per milligram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mg{Cre}</td>\n \n <td>micromole / milligram Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/min</td>\n \n <td>micromole per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/min/g</td>\n \n <td>micromole per minute per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/min/g{prot}</td>\n \n <td>micromole / minute / gram prot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/min/g{protein}</td>\n \n <td>micromole per minute per gram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/min/L</td>\n \n <td>micromole per minute per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mL</td>\n \n <td>micromole per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mL/min</td>\n \n <td>micromole per milliliter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mmol</td>\n \n <td>micromole per millimole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mol</td>\n \n <td>micromole per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mol{Cre}</td>\n \n <td>micromole / mole Cre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mol{creat}</td>\n \n <td>micromole per mole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mol{Hb}</td>\n \n <td>micromole per mole of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/umol</td>\n \n <td>micromole per micromole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uOhm</td>\n \n <td>microOhm</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>us</td>\n \n <td>microsecond</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uU</td>\n \n <td>microUnit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uU/g</td>\n \n <td>micro enzyme unit per gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uU/L</td>\n \n <td>micro enzyme unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uU/mL</td>\n \n <td>micro enzyme unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uV</td>\n \n <td>microvolt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>V</td>\n \n <td>volt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>wk</td>\n \n <td>week</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10.uN.s/(cm5.m2)</td>\n \n <td>10 micronewton second per centimeter to the fifth power per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*4/uL</td>\n \n <td>10 thousand per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>24.h</td>\n \n <td>24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>A</td>\n \n <td>Ampère</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ARU}</td>\n \n <td>aspirin response unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>atm</td>\n \n <td>standard atmosphere</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ag/{cell}</td>\n \n <td>attogram per cell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Bq</td>\n \n <td>Becquerel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{binding_index}</td>\n \n <td>binding index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[bdsk'U]</td>\n \n <td>Bodansky unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CAG_repeats}</td>\n \n <td>CAG trinucleotide repeats</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cal</td>\n \n <td>calorie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cm[H2O]/s/m</td>\n \n <td>centimeter of water per second per meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{delta_OD}</td>\n \n <td>change in (delta) optical density</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{copies}</td>\n \n <td>copies</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{count}</td>\n \n <td>count</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CPM}</td>\n \n <td>counts per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{CPM}/10*3{cell}</td>\n \n <td>counts per minute per thousand cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>daL/min</td>\n \n <td>dekaliter per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>daL/min/m2</td>\n \n <td>dekaliter per minute per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{dilution}</td>\n \n <td>dilution</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dyn.s/cm</td>\n \n <td>dyne second per centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dyn.s/(cm.m2)</td>\n \n <td>dyne second per centimeter per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich'U}/100.g</td>\n \n <td>Ehrlich unit per 100 gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EIA_index}</td>\n \n <td>EIA index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EIA_titer}</td>\n \n <td>EIA titer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EV}</td>\n \n <td>EIA value</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10</td>\n \n <td>enzyme unit per 10</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10*10</td>\n \n <td>enzyme unit per 10 billion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/(10.g){feces}</td>\n \n <td>enzyme unit per 10 gram of feces</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g{creat}</td>\n \n <td>enzyme unit per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/g{protein}</td>\n \n <td>enzyme unit per gram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U{25Cel}/L</td>\n \n <td>enzyme unit per liter at 25 deg Celsius</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U{37Cel}/L</td>\n \n <td>enzyme unit per liter at 37 deg Celsius</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>U/10*12{RBCs}</td>\n \n <td>enzyme unit per trillion red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>F</td>\n \n <td>Farad</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol/mg{cytosol_protein}</td>\n \n <td>femtomole per milligram of cytosol protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>fmol/mg{protein}</td>\n \n <td>femtomole per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{FIU}</td>\n \n <td>fluorescent intensity unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{fraction}</td>\n \n <td>fraction</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{GAA_repeats}</td>\n \n <td>GAA trinucleotide repeats</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{genomes}/mL</td>\n \n <td>genomes per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Globules}/[HPF]</td>\n \n <td>globules (drops) per high power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g.m/{beat}</td>\n \n <td>gram meter per heart beat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g{creat}</td>\n \n <td>gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g{Hb}</td>\n \n <td>gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g{total_nit}</td>\n \n <td>gram of total nitrogen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g{total_prot}</td>\n \n <td>gram of total protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g{wet_tissue}</td>\n \n <td>gram of wet tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/kg/(8.h)</td>\n \n <td>gram per kilogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/(8.h){shift}</td>\n \n <td>gram per 8 hour shift</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/cm3</td>\n \n <td>gram per cubic centimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/g{globulin}</td>\n \n <td>gram per gram of globulin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/kg/(8.h){shift}</td>\n \n <td>gram per kilogram per 8 hour shift</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/kg/h</td>\n \n <td>gram per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/kg/min</td>\n \n <td>gram per kilogram per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/mol{creat}</td>\n \n <td>gram per mole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/{specimen}</td>\n \n <td>gram per specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/{total_output}</td>\n \n <td>gram per total output</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g/{total_weight}</td>\n \n <td>gram per total weight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Gy</td>\n \n <td>Gray</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{beats}/min</td>\n \n <td>heart beats per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>H</td>\n \n <td>Henry</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[HPF]</td>\n \n <td>high power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[GPL'U]/mL</td>\n \n <td>IgG anticardiolipin unit per milliliter**</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{GPS'U}</td>\n \n <td>IgG antiphosphatidylserine unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[MPL'U]/mL</td>\n \n <td>IgM anticardiolipin unit per milliliter**</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ISR}</td>\n \n <td>immune status ratio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IFA_index}</td>\n \n <td>immunofluorescence assay index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{IFA_titer}</td>\n \n <td>Immunofluorescence assay titer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[in_i'H2O]</td>\n \n <td>inch (international) of water</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{index_val}</td>\n \n <td>index value</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{HA_titer}</td>\n \n <td>influenza hemagglutination titer</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]</td>\n \n <td>international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/L{37Cel}</td>\n \n <td>international unit per liter at 37 degrees Celsius</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[IU]/mg{creat}</td>\n \n <td>international unit per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kat</td>\n \n <td>katal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kU</td>\n \n <td>kilo enzyme unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kU/L{class}</td>\n \n <td>kilo enzyme unit per liter class</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kcal/d</td>\n \n <td>kilocalorie per day</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kcal/kg/(24.h)</td>\n \n <td>kilocalorie per kilogram per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kcal/[oz_av]</td>\n \n <td>kilocalorie per ounce (US & British)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ka'U]</td>\n \n <td>King Armstrong unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/(24.h)</td>\n \n <td>liter per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>L/s/s2</td>\n \n <td>liter per second per square second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Log_copies}/mL</td>\n \n <td>log (base 10) copies per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Log_IU}</td>\n \n <td>log (base 10) international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Log_IU}/mL</td>\n \n <td>log (base 10) international unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Log}</td>\n \n <td>log base 10</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[LPF]</td>\n \n <td>low power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>lm</td>\n \n <td>lumen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>lm.m2</td>\n \n <td>lumen square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Lyme_index_value}</td>\n \n <td>Lyme index value</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mclg'U]</td>\n \n <td>Mac Lagan unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Ms</td>\n \n <td>megasecond</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{feces}</td>\n \n <td>microgram per gram of feces</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug{FEU}/mL</td>\n \n <td>microgram fibrinogen equivalent unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/(100.g)</td>\n \n <td>microgram per 100 gram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/m3</td>\n \n <td>microgram per cubic meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/dL{RBCs}</td>\n \n <td>microgram per deciliter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{dry_tissue}</td>\n \n <td>microgram per gram of dry tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{dry_wt}</td>\n \n <td>microgram per gram of dry weight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{hair}</td>\n \n <td>microgram per gram of hair</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{Hb}</td>\n \n <td>microgram per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/g{tissue}</td>\n \n <td>microgram per gram of tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/L{RBCs}</td>\n \n <td>microgram per liter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mL{class}</td>\n \n <td>microgram per milliliter class</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mL{eqv}</td>\n \n <td>microgram per milliliter equivalent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/mmol{creat}</td>\n \n <td>microgram per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/{specimen}</td>\n \n <td>microgram per specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ug/[sft_i]</td>\n \n <td>microgram per square foot (international)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol{BCE}/mol</td>\n \n <td>micromole bone collagen equivalent per mole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/(2.h)</td>\n \n <td>micromole per 2 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/(8.h)</td>\n \n <td>micromole per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/dL{GF}</td>\n \n <td>micromole per deciliter of glomerular filtrate</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/kg{feces}</td>\n \n <td>micromole per kilogram of feces</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/L{RBCs}</td>\n \n <td>micromole per liter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/umol{creat}</td>\n \n <td>micromole per micromole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mg{creat}</td>\n \n <td>micromole per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/mmol{creat}</td>\n \n <td>micromole per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>umol/min/g{mucosa}</td>\n \n <td>micromole per minute per gram of mucosa</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mmol{creat}</td>\n \n <td>milli enzyme unit per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/g{Hb}</td>\n \n <td>milli enzyme unit per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/g{protein}</td>\n \n <td>milli enzyme unit per gram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mU/mg{creat}</td>\n \n <td>milli enzyme unit per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mbar/L/s</td>\n \n <td>millibar per liter per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/g{creat}</td>\n \n <td>milliequivalent per gram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/{specimen}</td>\n \n <td>milliequivalent per specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>meq/{total_volume}</td>\n \n <td>milliequivalent per total volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg{FEU}/L</td>\n \n <td>milligram fibrinogen equivalent unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/(6.h)</td>\n \n <td>milligram per 6 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{collection}</td>\n \n <td>milligram per collection</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/d/{1.73_m2}</td>\n \n <td>milligram per day per 1.73 square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/dL{RBCs}</td>\n \n <td>milligram per deciliter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g{dry_tissue}</td>\n \n <td>milligram per gram of dry tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g{feces}</td>\n \n <td>milligram per gram of feces</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g{tissue}</td>\n \n <td>milligram per gram of tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/g{wet_tissue}</td>\n \n <td>milligram per gram of wet tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/kg/(8.h)</td>\n \n <td>milligram per kilogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/kg/h</td>\n \n <td>milligram per kilogram per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/L{RBCs}</td>\n \n <td>milligram per liter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mg{creat}</td>\n \n <td>milligram per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{specimen}</td>\n \n <td>milligram per specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{total_output}</td>\n \n <td>milligram per total output</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{total_volume}</td>\n \n <td>milligram per total volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL{fetal_RBCs}</td>\n \n <td>milliliter of fetal red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(5.h)</td>\n \n <td>milliliter per 5 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/(6.h)</td>\n \n <td>milliliter per 6 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/{beat}</td>\n \n <td>milliliter per heart beat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mL/{beat}/m2</td>\n \n <td>milliliter per heart beat per square meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/(5.h)</td>\n \n <td>millimole per 5 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/{ejaculate}</td>\n \n <td>millimole per ejaculate</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/kg/(8.h)</td>\n \n <td>millimole per kilogram per 8 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/L{RBCs}</td>\n \n <td>millimole per liter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/mmol{urea}</td>\n \n <td>millimole per millimole of urea</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/mmol{creat}</td>\n \n <td>millimole per millmole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/{specimen}</td>\n \n <td>millimole per specimen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/{total_vol}</td>\n \n <td>millimole per total volume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6.[CFU]/L</td>\n \n <td>million colony forming unit per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6.[IU]</td>\n \n <td>million international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*6/(24.h)</td>\n \n <td>million per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mPa.s</td>\n \n <td>millipascal second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{minidrop}/min</td>\n \n <td>minidrop per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{minidrop}/s</td>\n \n <td>minidrop per second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{molecule}/{platelet}</td>\n \n <td>molecule per platelet</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{mm/dd/yyyy}</td>\n \n <td>month-day-year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{mutation}</td>\n \n <td>mutation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nU/mL</td>\n \n <td>nanoenzyme unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nU/{RBC}</td>\n \n <td>nanoenzyme unit per red blood cell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng{FEU}/mL</td>\n \n <td>nanogram fibrinogen equivalent unit per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/U</td>\n \n <td>nanogram per enzyme unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mg{creat}</td>\n \n <td>nanogram per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mg{protein}</td>\n \n <td>nanogram per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/mL{RBCs}</td>\n \n <td>nanogram per milliliter of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ng/10*6{RBCs}</td>\n \n <td>nanogram per million red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol{BCE}</td>\n \n <td>nanomole bone collagen equivalent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol{BCE}/L</td>\n \n <td>nanomole bone collagen equivalent per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol{BCE}/mmol{creat}</td>\n \n <td>nanomole bone collagen equivalent per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol{1/2cys}/mg{protein}</td>\n \n <td>nanomole of 1/2 cystine per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol{ATP}</td>\n \n <td>nanomole of ATP</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/dL{GF}</td>\n \n <td>nanomole per deciliter of glomerular filtrate</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mg{creat}</td>\n \n <td>nanomole per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mg{protein}</td>\n \n <td>nanomole per milligram of protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/mg{protein}/h</td>\n \n <td>nanomole per milligram of protein per hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/min</td>\n \n <td>nanomole per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/min/mg{Hb}</td>\n \n <td>nanomole per minute per milligram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>nmol/min/10*6{cells}</td>\n \n <td>nanomole per minute per million cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}/[HPF]</td>\n \n <td>number per high power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}/L</td>\n \n <td>number per liter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}/[LPF]</td>\n \n <td>number per low power field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}/uL</td>\n \n <td>number per microliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}/mL</td>\n \n <td>number per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{#}/min</td>\n \n <td>number per minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Ohm.m</td>\n \n <td>Ohm meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>osm</td>\n \n <td>osmole</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Pan_Bio'U}</td>\n \n <td>panbio unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*4{RBCs}</td>\n \n <td>per 10 thousand red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/m3</td>\n \n <td>per cubic meter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/{entity}</td>\n \n <td>per entity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{Hb}</td>\n \n <td>per gram of hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{tot_nit}</td>\n \n <td>per gram of total nitrogen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{tot_prot}</td>\n \n <td>per gram of total protein</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{wet_tis}</td>\n \n <td>per gram of wet tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/[IU]</td>\n \n <td>per international unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/kg{body_wt}</td>\n \n <td>per kilogram of body weight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mm</td>\n \n <td>per millimeter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/mmol{creat}</td>\n \n <td>per millimole of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/{OIF}</td>\n \n <td>per oil immersion field</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*3</td>\n \n <td>per thousand</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*3.{RBCs}</td>\n \n <td>per thousand red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/10*12{RBCs}</td>\n \n <td>per trillion red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{loss_AChR}</td>\n \n <td>percent loss of acetylcholine receptor</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{penetration}</td>\n \n <td>percent penetration</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{abnormal}</td>\n \n <td>percent abnormal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{activity}</td>\n \n <td>percent activity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{aggregation}</td>\n \n <td>percent aggregation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{at_60_min}</td>\n \n <td>percent at 60 minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{basal_activity}</td>\n \n <td>percent basal activity</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{binding}</td>\n \n <td>percent binding</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{blockade}</td>\n \n <td>percent blockade</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{blocked}</td>\n \n <td>percent blocked</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{bound}</td>\n \n <td>percent bound</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{breakdown}</td>\n \n <td>percent breakdown</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{deficient}</td>\n \n <td>percent deficient</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{dose}</td>\n \n <td>percent dose</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{excretion}</td>\n \n <td>percent excretion</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Hb}</td>\n \n <td>percent hemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{hemolysis}</td>\n \n <td>percent hemolysis</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{index}</td>\n \n <td>percent index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{inhibition}</td>\n \n <td>percent inhibition</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{loss}</td>\n \n <td>percent loss</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{lysis}</td>\n \n <td>percent lysis</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{normal}</td>\n \n <td>percent normal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{normal_pooled_plasma}</td>\n \n <td>percent normal pooled plasma</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{bacteria}</td>\n \n <td>percent of bacteria</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{baseline}</td>\n \n <td>percent of baseline</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{cells}</td>\n \n <td>percent of cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{RBCs}</td>\n \n <td>percent of red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{WBCs}</td>\n \n <td>percent of white blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{positive}</td>\n \n <td>percent positive</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{reactive}</td>\n \n <td>percent reactive</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{recovery}</td>\n \n <td>percent recovery</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{reference}</td>\n \n <td>percent reference</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{residual}</td>\n \n <td>percent residual</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{saturation}</td>\n \n <td>percent saturation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{total}</td>\n \n <td>percent total</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{uptake}</td>\n \n <td>percent uptake</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{viable}</td>\n \n <td>percent viable</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{percentile}</td>\n \n <td>percentile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{phenotype}</td>\n \n <td>phenotype</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pA</td>\n \n <td>picoampere</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/{cell}</td>\n \n <td>picogram per cell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/mg{creat}</td>\n \n <td>picogram per milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pg/{RBC}</td>\n \n <td>picogram per red blood cell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/(24.h)</td>\n \n <td>picomole per 24 hour</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pmol/{RBC}</td>\n \n <td>picomole per red blood cell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pt_us]</td>\n \n <td>pint</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{relative}</td>\n \n <td>relative percent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{relative_saturation}</td>\n \n <td>relative saturation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Rubella_virus}</td>\n \n <td>rubella virus</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{saturation}</td>\n \n <td>saturation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>s/{control}</td>\n \n <td>second per control</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>S</td>\n \n <td>Siemens</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Sv</td>\n \n <td>Sievert</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{s_co_ratio}</td>\n \n <td>signal to cutoff ratio</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{STDV}</td>\n \n <td>standard deviation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>T</td>\n \n <td>Tesla</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3{copies}/mL</td>\n \n <td>thousand copies per milliliter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*3{RBCs}</td>\n \n <td>thousand red blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{TSI_index}</td>\n \n <td>thyroid-stimulating immunoglobulin index</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Wb</td>\n \n <td>Weber</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{WBCs}</td>\n \n <td>white blood cells</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>1</td>\n \n <td>1*</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>'</td>\n \n <td>minute</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>''</td>\n \n <td>second</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%[slope]</td>\n \n <td>percent of slope</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>%{Bound}</td>\n \n <td>PercentBound</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/100{Spermatozoa}</td>\n \n <td>Per100Spermatozoa</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>/g{HGB}</td>\n \n <td>PerGramHemoglobin</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[acr_br]</td>\n \n <td>acre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[acr_us]</td>\n \n <td>acre</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Amb'a'1'U]</td>\n \n <td>Amb a 1 units</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[bbl_us]</td>\n \n <td>barrel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[bf_i]</td>\n \n <td>board foot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu]</td>\n \n <td>British thermal unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu_39]</td>\n \n <td>British thermal unit at 39 °F</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu_59]</td>\n \n <td>British thermal unit at 59 °F</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu_60]</td>\n \n <td>British thermal unit at 60 °F</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu_IT]</td>\n \n <td>international table British thermal unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu_m]</td>\n \n <td>mean British thermal unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Btu_th]</td>\n \n <td>thermochemical British thermal unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[bu_br]</td>\n \n <td>bushel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[bu_us]</td>\n \n <td>bushel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[c]</td>\n \n <td>velocity of light</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Cal]</td>\n \n <td>nutrition label Calories</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[car_Au]</td>\n \n <td>carat of gold alloys</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[car_m]</td>\n \n <td>metric carat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[CCID_50]</td>\n \n <td>CELL CULTURE INFECTIOUS DOSE 50%</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cft_i]</td>\n \n <td>cubic foot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ch_br]</td>\n \n <td>Gunter's chain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ch_us]</td>\n \n <td>Gunter's chain Surveyor's chain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cicero]</td>\n \n <td>cicero Didot's pica</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cml_i]</td>\n \n <td>circular mil</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cr_i]</td>\n \n <td>cord</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[crd_us]</td>\n \n <td>cord</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[cyd_i]</td>\n \n <td>cubic yard</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[D'ag'U]</td>\n \n <td>D-ANTIGEN UNITS</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[didot]</td>\n \n <td>didot Didot's point</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[diop]</td>\n \n <td>diopter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[dpt_us]</td>\n \n <td>dry pint</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[dqt_us]</td>\n \n <td>dry quart</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[dr_ap]</td>\n \n <td>dram drachm</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[dye'U]</td>\n \n <td>Dye unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[e]</td>\n \n <td>elementary charge</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[eps_0]</td>\n \n <td>permittivity of vacuum</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[fdr_br]</td>\n \n <td>fluid dram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[FFU]</td>\n \n <td>FOCUS-FORMING UNITS</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ft_br]</td>\n \n <td>foot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ft_us]</td>\n \n <td>foot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[fth_br]</td>\n \n <td>fathom</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[fth_us]</td>\n \n <td>fathom</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[fur_us]</td>\n \n <td>furlong</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[G]</td>\n \n <td>Newtonian constant of gravitation</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[gal_wi]</td>\n \n <td>historical winchester gallon</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[gil_br]</td>\n \n <td>gill</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[gil_us]</td>\n \n <td>gill</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[h]</td>\n \n <td>Planck constant</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[hd_i]</td>\n \n <td>hand</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[hnsf'U]</td>\n \n <td>Hounsfield unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[HP]</td>\n \n <td>horsepower</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[hp_C]</td>\n \n <td>HOMEOPATHIC POTENCY OF CENTESIMAL SERIES</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[hp_M]</td>\n \n <td>HOMEOPATHIC POTENCY OF MILLESIMAL SERIES</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[hp_Q]</td>\n \n <td>HOMEOPATHIC POTENCY OF QUINTAMILLESIMAL SERIES</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[hp_X]</td>\n \n <td>HOMEOPATHIC POTENCY OF DECIMAL SERIES</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[in_br]</td>\n \n <td>inch</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[in_i'Hg]</td>\n \n <td>inch of mercury column</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[in_us]</td>\n \n <td>inch</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]/dL</td>\n \n <td>InternationalUnitsPerDeciLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]/g</td>\n \n <td>InternationalUnitsPerGram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]/kg</td>\n \n <td>InternationalUnitsPerKilogram</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]/L</td>\n \n <td>InternationalUnitsPerLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[iU]/mL</td>\n \n <td>InternationalUnitsPerMilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[k]</td>\n \n <td>Boltzmann constant</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[kn_br]</td>\n \n <td>knot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[kn_i]</td>\n \n <td>knot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[knk'U]</td>\n \n <td>Kunkel unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lb_ap]</td>\n \n <td>pound</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lb_tr]</td>\n \n <td>pound</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lbf_av]</td>\n \n <td>pound force</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lcwt_av]</td>\n \n <td>long hunderdweight British hundredweight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[Lf]</td>\n \n <td>LIMIT OF FLOCCULATION</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ligne]</td>\n \n <td>ligne French line</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lk_br]</td>\n \n <td>link for Gunter's chain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lk_us]</td>\n \n <td>link for Gunter's chain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lne]</td>\n \n <td>line</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[lton_av]</td>\n \n <td>long ton British ton</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[ly]</td>\n \n <td>light-year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[m_e]</td>\n \n <td>electron mass</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[m_p]</td>\n \n <td>proton mass</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mesh_i]</td>\n \n <td>mesh</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[MET]</td>\n \n <td>metabolic equivalent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mi_br]</td>\n \n <td>mile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mil_i]</td>\n \n <td>mil</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mil_us]</td>\n \n <td>mil</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[min_br]</td>\n \n <td>minim</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[mu_0]</td>\n \n <td>permeability of vacuum</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[nmi_br]</td>\n \n <td>nautical mile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[oz_ap]</td>\n \n <td>ounce (US and British)</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pc_br]</td>\n \n <td>pace</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pca]</td>\n \n <td>pica</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pca_pr]</td>\n \n <td>Printer's pica</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[p'diop]</td>\n \n <td>prism diopter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[PFU]</td>\n \n <td>PLAQUE-FORMING UNITS</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pi]</td>\n \n <td>the number pi</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pied]</td>\n \n <td>pied French foot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pk_br]</td>\n \n <td>peck</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pk_us]</td>\n \n <td>peck</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pnt]</td>\n \n <td>point</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pnt_pr]</td>\n \n <td>Printer's point</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[PNU]</td>\n \n <td>PROTEIN NITROGEN UNITS</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pouce]</td>\n \n <td>pouce French inch</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[PRU]</td>\n \n <td>peripheral vascular resistance unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[pwt_tr]</td>\n \n <td>pennyweight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[rch_us]</td>\n \n <td>Ramden's chain Engineer's chain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[rd_br]</td>\n \n <td>rod</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[rd_us]</td>\n \n <td>rod</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[rlk_us]</td>\n \n <td>link for Ramden's chain</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[S]</td>\n \n <td>Svedberg unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[sc_ap]</td>\n \n <td>scruple</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[sct]</td>\n \n <td>section</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[scwt_av]</td>\n \n <td>short hundredweight U.S. hundredweight</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[smgy'U]</td>\n \n <td>Somogyi unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[smi_us]</td>\n \n <td>square mile</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[smoot]</td>\n \n <td>Smoot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[srd_us]</td>\n \n <td>square rod</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[stone_av]</td>\n \n <td>stone British stone</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[TCID_50]</td>\n \n <td>TISSUE CULTURE INFECTIOUS DOSE 50%</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[twp]</td>\n \n <td>township</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[USP'U]</td>\n \n <td>UNITED STATES PHARMACOPEIA UNIT</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[yd_br]</td>\n \n <td>yard</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>[yd_us]</td>\n \n <td>yard</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Cells}/uL</td>\n \n <td>CellsPerMicroLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Copies}/mL</td>\n \n <td>CopiesPerMilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ct}</td>\n \n <td>crossing threshold</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Ehrlich_U}/dL</td>\n \n <td>EhrlichUnitsPerDeciLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{EhrlichU}/dL</td>\n \n <td>EhrlichUnitsPerDeciLiter [Arbitrary Concentration Units]</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Elisa_U}/mL</td>\n \n <td>ElisaUnitsPerMilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{ElisaU}/mL</td>\n \n <td>ElisaUnitsPerMilliLiter [Arbitrary Concentration Units]</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{kp_C}</td>\n \n <td>HOMEOPATHIC POTENCY OF CENTESIMAL KORSAKOVIAN SERIES</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{rbc}</td>\n \n <td>red blood cell count</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{Spermatozoa}/mL</td>\n \n <td>SpermatozoaPerMilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{tbl}</td>\n \n <td>tablets</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>{tot}</td>\n \n <td>particles total count</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10*</td>\n \n <td>the number ten for arbitrary powers</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>10^</td>\n \n <td>the number ten for arbitrary powers</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>a_g</td>\n \n <td>mean Gregorian year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>a_j</td>\n \n <td>mean Julian year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>a_t</td>\n \n <td>tropical year</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Ao</td>\n \n <td>Ångström</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ar</td>\n \n <td>are</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>AU</td>\n \n <td>astronomic unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>b</td>\n \n <td>barn</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B</td>\n \n <td>bel</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B[kW]</td>\n \n <td>bel kilowatt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B[mV]</td>\n \n <td>bel millivolt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B[SPL]</td>\n \n <td>bel sound pressure</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B[uV]</td>\n \n <td>bel microvolt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B[V]</td>\n \n <td>bel volt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>B[W]</td>\n \n <td>bel watt</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Bd</td>\n \n <td>baud</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Bi</td>\n \n <td>Biot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>bit</td>\n \n <td>bit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>bit_s</td>\n \n <td>bit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>By</td>\n \n <td>byte</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>C</td>\n \n <td>Coulomb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cal_[15]</td>\n \n <td>calorie at 15 °C</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cal_[20]</td>\n \n <td>calorie at 20 °C</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cal_IT</td>\n \n <td>international table calorie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cal_m</td>\n \n <td>mean calorie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cal_th</td>\n \n <td>thermochemical calorie</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>cd</td>\n \n <td>candela</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Ci</td>\n \n <td>CURIE</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>circ</td>\n \n <td>circle</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>dyn</td>\n \n <td>dyne</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>G</td>\n \n <td>Gauss</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g%</td>\n \n <td>gram percent</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>g.m/{H.B.}</td>\n \n <td>gram meter per heartbeat</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Gal</td>\n \n <td>Gal</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Gb</td>\n \n <td>Gilbert</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>gf</td>\n \n <td>gram-force</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>gon</td>\n \n <td>gon grade</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>k[iU]/mL</td>\n \n <td>KiloInternationalUnitsPerMilliLiter</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>kg{wet'tis}</td>\n \n <td>kilogram of wet tissue</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Ky</td>\n \n <td>Kayser</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Lmb</td>\n \n <td>Lambert</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>lx</td>\n \n <td>lux</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m[H2O]</td>\n \n <td>meter of water column</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>m[Hg]</td>\n \n <td>meter of mercury column</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/{TotalVolume}</td>\n \n <td>MilliGramPerTotalVolume</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg/mg{Cre}</td>\n \n <td>MilligramsPerMilligramCreatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mg{creat}</td>\n \n <td>milligram of creatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mho</td>\n \n <td>mho</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/{TotalVolume}</td>\n \n <td>MilliMolesPerTotalVolume [Substance Units]</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mmol/mol{Cre}</td>\n \n <td>MilliMolesPerMoleCreatinine</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mo_g</td>\n \n <td>mean Gregorian month</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mo_j</td>\n \n <td>mean Julian month</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>mo_s</td>\n \n <td>synodal month</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Mx</td>\n \n <td>Maxwell</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Np</td>\n \n <td>neper</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>Oe</td>\n \n <td>Oersted</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>P</td>\n \n <td>Poise</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>pc</td>\n \n <td>parsec</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>ph</td>\n \n <td>phot</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>R</td>\n \n <td>Roentgen</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>rad</td>\n \n <td>radian</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>RAD</td>\n \n <td>radiation absorbed dose</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>REM</td>\n \n <td>radiation equivalent man</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>sb</td>\n \n <td>stilb</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>sph</td>\n \n <td>spere</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>sr</td>\n \n <td>steradian</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>st</td>\n \n <td>stere</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>u</td>\n \n <td>unified atomic mass unit</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>uCi</td>\n \n <td>MICROCURIE</td>\n \n <td/>\n \n </tr>\n \n <tr>\n \n <td>W</td>\n \n <td>Watt</td>\n \n <td/>\n \n </tr>\n \n </table>\n \n </li>\n \n </ul>\n \n </div>",
"status" : "generated"
}
}| Title | Version | Status | Publisher | Date |
|---|---|---|---|---|
| 4.0.1 | draft | FHIR Project | - | |
| 4.3.0 | draft | FHIR Project | - | |
| Common UCUM units | 5.0.0 | draft | FHIR Project | - |