Non-Protein Nitrogen (Laboratory) PDF

Summary

This document details various laboratory methodologies for analyzing non-protein nitrogen compounds like urea, creatinine, uric acid, and ammonia. It covers different analytical techniques, precautions, and reference ranges for these essential kidney function markers. The topics discussed include direct and indirect methods, enzymatic approaches, and precautions.

Full Transcript

Non-Protein Nitrogen
(Laboratory)
COURSE LEARNING OUTCOMES:
✓ Determine the requirements regarding patient preparation,
specimen collection, transport, processing and handling
✓ Demonstrate and compare methods of analysis used for Non-
Protein Nitrogen
✓ Interpret laboratory test results and correlate with normal and
pathologic conditions
✓ Determine the significance of Non-Protein Nitrogen as a marker
for Kidney Function Test
✓ Determine other laboratory Methodology in the assessment of
kidney function
CONTENT
I. Urea
a. Lab Methodologies & Analytical Techniques
b. Precautions & Specimen Considerations
c. Reference Interval
II. Creatinine
a. Lab Methodologies & Analytical Techniques
b. Precautions & Specimen Considerations
c. Reference Interval
III. Uric Acid
a. Lab Methodologies & Analytical Techniques
b. Precautions & Specimen Considerations
c. Reference Interval
IV. Ammonia
a. Lab Methodologies & Analytical Techniques
b. Precautions & Specimen Considerations
c. Reference Interval
I. UREA
LABORATORY METHODOLOGIES & ANALYTICAL
TECHNIQUES

A. Direct Methods- measure urea levels directly

B. Indirect Methods (Blood Urea Nitrogen) -
assess the nitrogen content in urea

BUN x 2.14 = UREA
LABORATORY METHODOLOGIES & ANALYTICAL
TECHNIQUES
1. Micro - Kjeldahl (Indirect)
2. DAM: Diacetyl Monoxime (Direct)
3. Enzymatic Method (Indirect)
4. ISOTOPE DILUTION/ MASS SPECTROMETRY
1. MICRO - KJELDAHL (INDIRECT)

Classical reference method
Indirect method
Digests nitrogen to become ammonia
Principle: Nitrogen in PFF is converted to
ammonia using hot conc. sulfuric acid in
the presence of a catalyst
1. MICRO - KJELDAHL (INDIRECT)

Measurement of ammonia
1. Micro-Kjeldahl Nessler
Nessler’s Reaction (Nesslerization)
di mercuric potassium iodide (Nessler’s reagent)

gum ghatti
NH3 + K2Hg2I2 NH2Hg2I2 (yellow)

BUN x 2.14 = UREA
1. MICRO - KJELDAHL (INDIRECT)

2. Micro-Kjeldahl Berthelot
Berthelot Reaction

NH3 + phenol + Na nitroprusside indophenol
hypochlorite blue

BUN x 2.14 = UREA
2. DAM: DIACETYL MONOXIME (DIRECT)

EMPLOYED IN AUTOANALYZERS

strong acid yellow diazine
UREA + DAM
derivative
Reaction is intensified by:
✓ ferric ions and thiosemicarbazide
✓ intense red color formed is measured at 540 nm
Utilizes the FEARON Reaction
2. DAM: DIACETYL MONOXIME (DIRECT)

ADVANTAGES:
Simple
Direct measurement of UREA
Shows no interference by ammonia
LABORATORY METHODOLOGIES & ANALYTICAL
TECHNIQUES

Berthelot Reaction NH3 Color Reaction

Nessler’s Reaction N Color Reaction

Fearon Reaction UREA Color Reaction
3. ENZYMATIC METHOD (INDIRECT)

a. Urease-Nessler

Urea Urease CO2 + NH3 + K2Hg2I2 (yellow)

b. Urease-Berthelot
Urease CO2 + NH3
Urea + phenol hypochlorite (indophenol blue @ 630 nm)

BUN x 2.14 = UREA
3. ENZYMATIC METHOD (INDIRECT)

c. Coupled Urease/Glutamate Dehydrogenase (GLDH)
Method
CANDIDATE REFERENCE METHOD
4. ISOTOPE DILUTION/ MASS SPECTROMETRY

GOLD STANDARD
used only by REFERENCE LABORATORIES due to its high
cost
PRECAUTIONS & SPECIMEN CONSIDERATIONS

✓Specimens:
Plasma, serum, or urine.
✓Non-hemolyzed samples are recommended.
✓Highly influenced by protein intake, but the impact of a
recent protein meal is minimal.
Fasting is generally not required
✓Gray and blue-top tubes are unsuitable for BUN
determination
Fluoride and citrate inhibit the urease enzyme.
PRECAUTIONS & SPECIMEN CONSIDERATIONS

✓Avoid contamination with ammonium salts
✓Prevent prolonged standing, as urea can convert
to ammonia.
✓Urea is prone to bacterial breakdown.
Specimens, especially urine and timed urine samples,
should be refrigerated if not analyzed within a few
hours.
UREA: REFERENCE INTERVAL / RANGE

CONVERSION FACTOR: (Conventional to SI unit)

0.357
Conventional unit: 8 – 23 mg/dL
SI unit: 2.9 – 8.2 mmol/L
ATTENDANCE CHECK
II. CREATININE
LABORATORY METHODOLOGIES & ANALYTICAL
TECHNIQUES
1. Direct JAFFE Reaction Method
2. Kinetic Jaffe Method
3. Enzymatic Methods
4. Isotope Dilution/ Mass Spectrometry
1. DIRECT JAFFE REACTION METHOD
Sample must first undergo deproteinization

Creatinine in a protein Alkaline picrate
free filtrate

Red-orange tautomer of creatinine
picrate
1. DIRECT JAFFE REACTION METHOD

Reagent: ALKALINE PICRATE
Picric acid (trinitrophenol) mixed with 10%
NaOH should be freshly made, as it can
turn into picramic acid if left standing for
too long.
1. DIRECT JAFFE REACTION METHOD

DISADVANTAGES:
Not specific for creatinine
FALSE INCREASE FALSE DECREASE
Ketones Bilirubin
Glucose Hemoglobin
Fructose
Protein
Urea
Ascorbic acid
Cephalosporins
1. DIRECT JAFFE REACTION METHOD

To eliminate interferences, use:

Lloyd’s Reagent (Method of Hare): Sodium
aluminum silicate
Fuller’s Earth Reagent: Aluminum magnesium
silicate

These reagents remove interferences, enhancing the
method’s specificity and sensitivity.
2. KINETIC JAFFE METHOD

Measures the varying rates at which color develops from
non-creatinine chromogens, helping to eliminate
interferences.
It is widely used, cost-effective, quick, and
straightforward.
Requires automated equipment.
No need for protein-free filtrate; serum can be used
directly.
Product: Red-orange tautomer of creatinine picrate
3. ENZYMATIC METHODS

Free from interference by glucose and other Jaffe
chromogens.

a. Creatinine Iminohydrolase Method

A reduction in absorbance at 340 nm reveals the level of creatinine.
3. ENZYMATIC METHODS

b. Creatinine Amidohydrolase Method
3. ENZYMATIC METHODS

Different coupled enzymatic approaches, designed
for use with a dry slide analyzer, include:
Creatininase (creatinine amidohydrolase)
Creatinase (creatine amidinohydrolase)
Sarcosine oxidase
Peroxidase
4. ISOTOPE DILUTION/ MASS SPECTROMETRY

ULTIMATE REFERENCE STANDARD for creatinine
measurement
PRECAUTIONS & SPECIMEN CONSIDERATIONS

✓Specimens:
Plasma, serum, or urine.
✓Avoid hemolyzed samples, as red blood cells contain
significant non-creatinine chromogens.
✓Lipemic and icteric samples can cause incorrect results.
✓Ensure that specimens are stored correctly and maintain
a pH of 7.0.
PRECAUTIONS & SPECIMEN CONSIDERATIONS

✓Fasting is not required, but a high-protein diet can
temporarily boost serum creatinine levels.
✓Urine: Refrigerate it right after collection.
✓If you need to store urine for more than 4 days,
freeze it.
✓Effects of Specific Medications:
✓Dopamine can affect the accuracy of Jaffe and
enzymatic assays.
✓Lidocaine may introduce a false increase in results for
some enzymatic assays
 CREATININE: REFERENCE INTERVAL / RANGE

CONVERSION FACTOR: (Conventional to SI unit)

88.40
ADULT CHILDREN ( Plasma
Fasting is NOT required for the specimen.
Lipemia can impact the accuracy of results.
Hemolysis can cause a false increase in total protein levels.
Total protein levels are generally higher in ambulatory patients
compared to those in a recumbent position due to fluid
redistribution into extracellular compartments.
At birth, total protein levels are lower and typically reach adult
levels by age 3.
With aging, there is a gradual decline in albumin levels.
Pregnancy can also result in lower total protein levels.
LAB METHODOLOGIES

1. Kjeldahl Method
2. Biuret Method
3. Folin-Ciocalteau (Lowry) Method
4. Ultraviolet Absorption Method
5. Salt Fractionation
6. Refractometry
7. Turbidimetric and Nephelometric Methods
8. Serum Protein Electrophoresis
KJELDAHL METHOD (INDIRECT METHOD)

widely accepted standard for protein measurement.
Determines protein concentration based on the nitrogen
content of proteins
Proteins contain an average of 16% nitrogen, and protein
content is calculated by multiplying the nitrogen amount
by 6.25
The process includes converting nitrogen into ammonia
through digestion with an acid mixture
KJELDAHL METHOD (INDIRECT METHOD)
Process: Serum is treated with tungstic acid, which separates
proteins from the solution, leaving a protein-free filtrate.

Reagents:
Sulfuric Acid (H₂SO₄): Used to digest the sample and
convert nitrogen into a measurable form.

End Product:
Ammonia: The amount of ammonia produced during the
digestion process is quantified to estimate protein content.
BIURET METHOD (DIRECT METHOD)
Most used method for protein quantification.
Also referred to as Piotrowski's Test
Endorsed by the International Federation of Clinical
Chemistry and Laboratory Medicine (IFCC)
BIURET METHOD (DIRECT METHOD)
Principle:
Cupric ions react with peptide bonds in an alkaline
environment to form a violet-colored complex.
The intensity of the violet color is proportional to the
number of peptide bonds and indicates the total protein
concentration.
The measurement is taken at a wavelength of 545 nm.
This method requires a minimum of two peptide bonds
and an alkaline medium to produce a detectable reaction.
BIURET METHOD (DIRECT METHOD)
Reagents:
1. Copper Sulfate:
Primary Reagent: Cupric ions from copper sulfate form complexes with peptide bonds.
2. Potassium Sodium Tartrate (Rochelle's Salt):
Stabilizes Copper: Helps keep copper in solution.
3. Potassium Iodide:
Prevents Auto reduction: Stops copper from reducing itself during the reaction.
4. Sodium Hydroxide:
Alkalinizes the Solution: Creates the alkaline environment necessary for the reaction.
Note:
Avoid Hemolysis: Hemoglobin absorbs light at the same wavelength as the biuret reagent, which
can interfere with accurate measurement.
FOLIN-CIOCALTEAU (LOWRY) METHOD
Highest Analytical Sensitivity among protein
determination methods.
Principle:
Oxidation of phenolic compounds, including
tyrosine, tryptophan, and histidine, results in a
deep blue color.
Reagents:
Phenol Reagent or Phosphotungstic-Molybdic
Acid: Used to induce the color reaction.
Color Enhancer:
Biuret Reagent: Enhances the color intensity of
the reaction, aiding in the measurement.
ULTRAVIOLET ABSORPTION METHOD
Principle: Proteins absorb ultraviolet light due to specific
components:

210 nm: Absorption is attributed to peptide bonds in the
protein.

280 nm: Absorption is due to aromatic amino acids,
specifically tryptophan, tyrosine, and phenylalanine.
SALT FRACTIONATION
Purpose: Separates globulins from albumin
using salting-out techniques with sodium
salts.

Salt Used: Sodium sulfate is employed for the
salting-out process.

Process: Albumin that remains in the
supernatant after salting-out can be
quantified using any of the total protein
measurement methods.
SALT FRACTIONATION
REFRACTOMETRY
Relies on measuring the refractive index caused by solutes in the
serum.
TURBIDIMETRIC AND NEPHELOMETRICMETHODS
Reagents:
Sulfosalicylic acid (SSA)
Trichloroacetic acid (TCA)
Principle:
Nephelometry: Measures the scattering of
light by a fine, uniform precipitate in
suspension.
Turbidimetry: Measures the reduction of
light transmission caused by precipitates
that block light.
TURBIDIMETRIC AND NEPHELOMETRICMETHODS
Factors that affects the
nephelometry and turbidity:
Size and number of particles
Depth of the tube
Cross sectional areas of each
particle
SERUM PROTEIN ELECTROPHORESIS (SPE)
Introduced By: Tiselius
Principle:
Charged particles migrate in an electric
field.
Proteins are separated based on their
electrical charge.
Applications:
Identifies monoclonal spikes of
immunoglobulins
Differentiates monoclonal gammopathies
from polyclonal hypergammaglobulinemia
SERUM PROTEIN ELECTROPHORESIS (SPE)
Cations: Positively charged ions
Anions: Negatively charged ions
At pH 8.6: Proteins acquire a negative charge

Positive Electrode: Anode
Negative Electrode: Cathode

Migration of Serum Proteins: From the cathode to the
anode
SERUM PROTEIN ELECTROPHORESIS (SPE)
Fastest to slowest:
SERUM PROTEIN ELECTROPHORESIS (SPE)
ALBUMIN ALPHA 1 ALPHA 2 BETA GAMMA
alpha1-antitrypsin (90%) haptoglobin transferrin (90%) Immunoglobulins
(Igs)
alpha1-fetoprotein ceruloplasmin hemopexin C-reactive protein
(CRP)
alpha1-acidglycoprotein alpha2- IgA
(orosomucoid) macroglobulin

alpha1-antichymotrypsin beta2-
microglobulin
thyroxine-binding complements(C3,
globulin(TBG) C4, C5)
antithrombin III
SERUM PROTEIN ELECTROPHORESIS (SPE)
Staining Agents:
Bromphenol blue
Ponceau S
Amido Black 10B
Lissamine green
Coomassie Brilliant Blue

Quantification:
After staining, the bands are scanned with a DENSITOMETER to
measure the amount of protein in each band.
SERUM PROTEIN ELECTROPHORESIS (SPE)
SERUM PROTEIN ELECTROPHORESIS (SPE)
OTHER METHODS
Coomassie Brilliant Blue Dye:
Sensitive enough to detect as little as 1 µg of protein.
Used as a stain for cerebrospinal fluid (CSF)
electrophoresis.

Ninhydrin:
Produces a violet color when reacting with primary
amines.
Commonly used for detecting peptides and amino acids
after paper chromatography.
REMEMBER!
Protein Profile – evaluates the synthetic function of the
liver.

Total Serum Protein (TSP) = albumin + globulin
Globulin = TSP – albumin
Total Plasma Protein (TPP) = albumin + globulin +
fibrinogen
TPP - TSP = fibrinogen
B. Albumin
Determination
ALBUMIN DETERMINATION

Albumin

Synthesis: Produced in the liver.
Normal Synthesis Rate: Approximately 120
mg/kg/day.
Major Serum Protein.
ALBUMIN DETERMINATION

Relationship with Liver Disease:
Albumin concentration decreases as liver disease
severity increases.
Measurement Methods:
Direct methods utilize the dye-binding property of
albumin.
Binding Characteristics:
Albumin binds many small molecules, including specific
dyes that do not interact with other serum proteins
 ALBUMIN DETERMINATION
Isolation and Measurement:

Isolation Process:
Mix serum with Na2SO4 or (NH4)2SO4 and centrifuge.
Residue: Precipitated globulins.
Filtrate: Contains albumin.

Measurement Methods:
Micro-Kjeldahl Method: Multiply the result by 6.25.
Biuret Method: Identifies albumin by producing a violet color.
Dye-Binding Methods: Measures albumin based on dye binding.
ALBUMIN DETERMINATION

DYE-BINDING METHODS

Dyes Used for Measurement:
Bromcresol Purple: The most specific dye (603 nm)
Bromcresol Green: The most commonly used dye
(628 nm)
Methyl Orange
Hydroxyaminobenzoic Acid (HABA)
ALBUMIN DETERMINATION
INCREASED IN DECREASED IN
severe dehydration liver disease
prolonged tourniquet application nephrotic syndrome
malabsorption syndrome
muscle wasting disease
thyrotoxicosis
malnutrition
burns

Low total protein + Low albumin
= Hepatic cirrhosis & Nephrotic syndrome
C. Albumin/Globulin
Ratio
ALBUMIN/GLOBULIN RATIO
Purpose: Determines if globulin levels are higher than albumin in
the serum.
Globulin:
Analysis: Not directly measured; computed as TSP - albumin.
Reference Range: 1.3-3:1 (Typically, albumin > globulin).
Increased Globulin Indications: (Inverted A/G Ratio)
Chronic inflammation
Multiple myeloma
Waldenstrom macroglobulinemia
Inverted Ratio: Occurs when globulin > albumin, known as an
inverted A/G ratio.
REFERENCE INTERVAL / RANGE

ALBUMIN
CONVERSION FACTOR: (Conventional to SI unit)

10
Conventional unit: 3.5-5 g/dL (gm %)
SI unit: 35-50 g/L
REFERENCE VALUESFOR OTHER PROTEIN FRACTIONS

Alpha1-globulin 0.1-0.3 g/dL
Alpha2-globulin 0.6-1.0 g/dL
Beta-globulin 0.7-1.1 g/dL
Gamma globulin 0.8-1.6 g/dL
MUST KNOW!
Analbuminemia
hereditary absence of
albumin
Bisalbuminemia
associated with the
presence of therapeutic
drugs in serum
(↑penicillin =
bisalbuminemia)
D. Prothrombin Time/
Vitamin K Response
Test
PROTHROMBIN TIMETEST/ VITAMIN K RESPONSE
TEST
Liver Function
Responsible for synthesizing Vitamin K-dependent clotting
factors

Intrahepatic vs. Extrahepatic Obstructive Liver Disease
Intrahepatic Disorder: PT (Prothrombin Time) is prolonged
Extrahepatic Disorder: PT (Prothrombin Time) is normal

Vitamin K Administration
Route: Intramuscular (IM)
Dosage: 10 mg daily for 1-3 days
PROTHROMBIN TIMETEST/ VITAMIN K RESPONSE
TEST
Assessment of Liver Disease Severity
Serum Albumin
Vitamin K-Dependent Clotting Factors
These are the most useful indicators for
evaluating the severity of liver disease
PART 2
III. Tests that evaluate
hepatic conjugation
and excretion function
 B1 B2
Unconjugated bilirubin Conjugated bilirubin
Water Insoluble Water Soluble
Non-polar bilirubin Polar Bilirubin
Indirect reacting Direct reacting
Hemobilirubin Cholebilirubin
Slow reacting One-minute/promt bilirubin
Prehepatic bilirubin Post hepatic/obstructive and
regurgitative bilirubin
 I. BILIRUBIN ASSAYS
✓end product of hemoglobin metabolism
✓Function:
Principal pigment in bile
✓Formation:
Results from the breakdown of heme-
containing substances, including:
Myoglobin
Cytochrome oxidase
Catalase
I. BILIRUBIN ASSAYS
Specimen Considerations for Bilirubin Assay
✓Avoid:
Hemolysis
Lipemia
✓Sample Requirements:
Fasting sample preferred to prevent increased
bilirubin concentration from lipemia
Hemolyzed samples can reduce bilirubin reaction with
diazo reagent
I. BILIRUBIN ASSAYS
Specimen Considerations for Bilirubin Assay
✓Processing:
Protect specimen from light
Process as soon as possible (preferably within 2-3
hours)
✓Note:
Photoisomerization converts B1 to B2, potentially
leading to falsely elevated B2 levels
Visible icterus occurs at bilirubin levels >25 mg/L
I. BILIRUBIN ASSAYS
Notes to Remember
✓Unconjugated bilirubin reacts SLOWLY
Therefore, accelerants such as CAFFEINE or METHANOL
are used to measure both direct and indirect bili (total
bilirubin)
Without accelerants, only direct-acting bilirubin will be
measured
✓Conjugated bilirubin:
the fraction that produced a color in aqueous solution
✓Unconjugated bilirubin:
the fraction that produce a color only after addition of
alcohol.
I. BILIRUBIN ASSAYS
Notes to Remember
✓Total bilirubin is measured 15 minutes after
adding the accelerant/coupling accelerator.
✓Caffeine benzoate is preferred over
methanol
Because methanol causes protein ppt’n and
turbidity
I. BILIRUBIN ASSAYS
MUST KNOW!!!

✓BILIRUBIN absorbs light maximally at 450nm
✓It imparts yellow color to serum, urine and
amniotic fluid (body fluids)
I. BILIRUBIN ASSAYS
PRINCIPLE OF BILIRUBIN ASSAYS:

Van den Bergh Reaction
✓diazotization of bilirubin to produce
azobilirubin
I. BILIRUBIN ASSAYS
DIAZO REACTIONS

Principle: Reaction of bilirubin with diazotized sulfanilic
acid forms a colored product, azobilirubin
Reactions:
Bilirubin + diazotized sulfanilic acid → azobilirubin
(conjugated bilirubin)
Bilirubin + diazotized sulfanilic acid + accelerator → total
bilirubin
Calculating Unconjugated Bilirubin:
Total bilirubin - conjugated bilirubin = unconjugated
bilirubin
 I. BILIRUBIN ASSAYS
DIAZO REACTIONS
✓Historically first performed on urine samples only,
but Van den Bergh found that diazo reaction may
be applied on serum samples but only in the
presence of accelerators (solubilizers)
✓The third fraction, delta bilirubin will react as
conjugated bilirubin
Delta bilirubin is conjugated bilirubin tightly bound
to ALBUMIN.
It is elevated in obstructive jaundice
I. BILIRUBIN ASSAYS
1. Diazo Reaction
A. EVELYN MALLOY
B. JENDRASSIK AND GROF
C. MODIFIED JENDRASSIK AND GROF
I. BILIRUBIN ASSAYS
1. Diazo Reaction

A. EVELYN AND MALLOY METHOD
Coupling accelerator: 50% Methanol

Final reaction:
(+) pink to purple azobilirubin (560 nm)

Uses pH 1.2
I. BILIRUBIN ASSAYS
1. Diazo Reaction

B. JENDRASSIK AND GROF METHOD
MOST SENSITIVE AND MOST WIDELY USED
More sensitive than Evelyn Malloy
Popular technique for the discreet analyzers
Not falsely elevated by hemolysis
 I. BILIRUBIN ASSAYS
1. Diazo Reaction
B. JENDRASSIK AND GROF METHOD
✓Coupling accelerator:
CAFFEINE SODIUM BENZOATE
✓Buffer: Sodium Acetate
less sensitive to pH change
✓Ascorbic acid: terminates the initial reaction and
destroys the excess diazo reagent
✓Final reaction:
(+) pink to blue azobilirubin (600 nm)
 I. BILIRUBIN ASSAYS
1. Diazo Reaction

C. MODIFIED JENDRASSIK AND GROF METHOD
CANDIDATE REFERENCE METHOD FOR TOTAL
BILIRUBIN

Coupling accelerator:
caffeine-benzoate
 I. BILIRUBIN ASSAYS
MUST KNOW!

Obstruction in the biliary tract also causes
elevated total cholesterol due to block in the
normal excretion of cholesterol in the bile.
 I. BILIRUBIN ASSAYS
MUST KNOW!
If there is obstruction,
1. Conjugated bilirubin will re-enter the
circulation
2. It will accumulate
3. Then spontaneously form a covalent bond
with albumin forming delta bilirubin or
biliprotein with a half-life of 17 days thereby
prolonging its half-life in the circulation.

Note: (B1 = 55 or premature Low LDL-c
menopause for women
Family history of premature CHD
Current cigarrete smoking
High LDL-c
Low HDL-c (