Chemistry Calculations: Difference between revisions
Created page with "== Statistics & Quality Control == === Mean/Average (unit) === The mean is the average of a series of numbers. Report to the same units and decimal places as the data. <math display="block">\bar{x}=\frac{x_1+x_2+...+x_n}{n}</math> === Sample Standard Deviation === Use standard deviation when the '''mean of two methods is the same.''' Report as +1 decimal place more than the data. <math display="block">s=\sqrt{\frac{\Sigma(x-\bar{x})^2}{n-1}}</math>where x = data and..." |
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<math display="block">s=\sqrt{\frac{\Sigma(x-\bar{x})^2}{n-1}}</math>where x = data and <math>\bar{x} = \text{Mean}</math> | <math display="block">s=\sqrt{\frac{\Sigma(x-\bar{x})^2}{n-1}}</math>where x = data and <math>\bar{x} = \text{Mean}</math> | ||
=== Coefficient of Variation === | === Coefficient of Variation (%) === | ||
Use coefficient of variation when the '''mean of two methods is different.''' Report to 1 decimal place. | |||
<math display="block">CV=\frac{SD}{Mean}*100</math> | <math display="block">CV=\frac{SD}{Mean}*100</math> | ||
=== Percent Error (%) === | |||
Report to 1 decimal place. | |||
<math display="block">\mathrm{% Error}=\frac{Actual-Theoretical}{Theoretical}*100\mathrm{%}</math> | |||
=== Westgard Rules === | === Westgard Rules === | ||
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* 1-2s (one control value exceeds the mean ±2 SD) | * 1-2s (one control value exceeds the mean ±2 SD) | ||
* R10x (ten consecutive values fall on one side of the mean) | * R10x (ten consecutive values fall on one side of the mean) | ||
== Blood pH & Respiration == | |||
=== Blood pH Calculations === | |||
<math display="block">pH=6.1+log\frac{[HCO^-]}{0.03*P_{CO2}}</math> | |||
dCO2 = dissolved CO2 | |||
PCO2 = partial pressure CO2 | |||
[HCO-] = concentration of bicarbonate | |||
== Kidney Function Testing == | |||
=== Creatinine Clearance (mL/s) === | |||
Creatinine clearance is (U*V)/S and the corrected creatinine clearance uses BSA to correct for size/muscle mass. | |||
<math display="block">CC=\frac{U*V}{S}*\frac{1.73}{BSA}</math> | |||
<math display="block">CC=\frac{\mbox{[Urine Creatinine]}*\mbox{Urine flow}]}{\mbox{[Serum creatinine]}}*\frac{1.73}{\mbox{Body surface area}}</math> | |||
Convert mmol/L to mmol/day: | |||
<math display="block">\mbox{24h excretion}=\frac{\mbox{24h urine volume }*\mbox{ [Analyte]}}{1000}</math> | |||
U = urine creatinine (μmol/L) | |||
S = serum creatinine (μmol/L) | |||
V = urine flow rate (mL/s) - this is the 24h volume (mL) divided by 86 400 seconds per 24h | |||
BSA = body surface area (m<sup>2</sup>) - calculate using height and weight on nomogram | |||
=== Creatinine (mmol/d) === | |||
Used as measure of creatinine levels from 24h urine. | |||
<math display="block">Creatinine=\frac{V*c}{1000}</math> | |||
<math display="block">=\frac{\mbox{Urine volume }*[Creatinine]}{1000}</math> | |||
=== eGFR Estimated Glomerular Filtration Rate === | |||
Complicated calculation using standardized serum creatinine and many correction factors for age and gender. | |||
== Electrolytes & Osmolality == | |||
=== Osmolar Gap === | |||
Calculates difference between expected osmolality vs actual osmolality. High osmolar gap may be due to presence of volatile or osmotically active compounds like ethanol, methanol, etc. | |||
<math display="block">\mbox{Calculated Osmolality}=2*[Na^{2+}]+[Urea]+[Glucose]</math> | |||
From this, the osmolar gap can be calculated: | |||
<math display="block">\mbox{Osmolar Gap}=\mbox{Measured Osmolality}-\mbox{Calculated Osmolality}</math> | |||
== Dilutions & Concentrations == | == Dilutions & Concentrations == | ||
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You can then determine the amount of diluent/solvent needed from the calculated volume of solute required. | You can then determine the amount of diluent/solvent needed from the calculated volume of solute required. | ||
<math>V_{diluent}=V_{total}-V_{solute}</math> | <math display="block">V_{diluent}=V_{total}-V_{solute}</math> | ||
Revision as of 19:08, 10 February 2025
Statistics & Quality Control
Mean/Average (unit)
The mean is the average of a series of numbers. Report to the same units and decimal places as the data.
Sample Standard Deviation
Use standard deviation when the mean of two methods is the same. Report as +1 decimal place more than the data.
where x = data and
Coefficient of Variation (%)
Use coefficient of variation when the mean of two methods is different. Report to 1 decimal place.
Percent Error (%)
Report to 1 decimal place.
Westgard Rules
There are 4 reject rules and 2 warning rules:
- 1-3s (one control value exceeds the mean ±3 SD)
- 2-2s (two consecutive control values exceed the mean ±2 SD)
- R-4s (when one value exceeds the mean +2 SD and another value exceeds -2 SD within the same run so that the values are 4 SD different from each other)
- 4-1s (four consecutive control values exceed the mean ±1 SD)
Warning Rules:
- 1-2s (one control value exceeds the mean ±2 SD)
- R10x (ten consecutive values fall on one side of the mean)
Blood pH & Respiration
Blood pH Calculations
dCO2 = dissolved CO2
PCO2 = partial pressure CO2
[HCO-] = concentration of bicarbonate
Kidney Function Testing
Creatinine Clearance (mL/s)
Creatinine clearance is (U*V)/S and the corrected creatinine clearance uses BSA to correct for size/muscle mass.
Convert mmol/L to mmol/day:
U = urine creatinine (μmol/L)
S = serum creatinine (μmol/L)
V = urine flow rate (mL/s) - this is the 24h volume (mL) divided by 86 400 seconds per 24h
BSA = body surface area (m2) - calculate using height and weight on nomogram
Creatinine (mmol/d)
Used as measure of creatinine levels from 24h urine.
eGFR Estimated Glomerular Filtration Rate
Complicated calculation using standardized serum creatinine and many correction factors for age and gender.
Electrolytes & Osmolality
Osmolar Gap
Calculates difference between expected osmolality vs actual osmolality. High osmolar gap may be due to presence of volatile or osmotically active compounds like ethanol, methanol, etc.
From this, the osmolar gap can be calculated:
Dilutions & Concentrations
Calculating Dilutions Using Dilution Factors and Total Volume
You can determine the amount of solute required for a dilution with a given dilution factor and final (total) volume.
DF = dilution factor (e.g., in a 1:250 dilution, the DF is 250)
You can then determine the amount of diluent/solvent needed from the calculated volume of solute required.