TESTS FOR DETECTION OF KETONES IN URINE

Published in Clinical Pathology
Monday, 07 August 2017 18:11
The proportion of ketone bodies in urine in ketosis is variable: β-hydroxybutyric acid 78%, acetoacetic acid 20%, and acetone 2%.
 
No method for detection of ketonuria reacts with all the three ketone bodies. Rothera’s nitroprusside method and methods based on it detect acetoacetic acid and acetone (the test is 10-20 times more sensitive to acetoacetic acid than acetone). Ferric chloride test detects acetoacetic acid only. β-hydroxybutyric acid is not detected by any of the screening tests.
 
Methods for detection of ketone bodies in urine are Rothera’s test, Acetest tablet method, ferric chloride test, and reagent strip test.
 
1. ROTHERA’S’ TEST (Classic Nitroprusside Reaction)
 
Acetoacetic acid or acetone reacts with nitroprusside in alkaline solution to form a purple-colored complex (Figure 822.1). Rothera’s test is sensitive to 1-5 mg/dl of acetoacetate and to 10-25 mg/dl of acetone.
 
Figure 822.1 Principles of Rothera Test in Urine
Figure 822.1 Principles of Rothera’s test and reagent strip test for ketone bodies in urine. Ketones are detected as acetoacetic acid and acetone but not β-hydroxybutyric acid
 
Method
 
  1. Take 5 ml of urine in a test tube and saturate it with ammonium sulphate.
  2. Add a small crystal of sodium nitroprusside. Mix well.
  3. Slowly run along the side of the test tube liquor ammonia to form a layer.
  4. Immediate formation of a purple permanganate colored ring at the junction of the two fluids indicates a positive test (Figure 822.2).
 
False-positive test can occur in the presence of L-dopa in urine and in phenylketonuria.
 
Figure 822.2 Rotheras tube test and reagent strip test for ketone bodies in urine
Figure 822.2 Rothera’s tube test and reagent strip test for ketone bodies in urine
 
2. ACETEST TABLET TEST
 
This is Rothera’s test in the form of a tablet. The Acetest tablet consists of sodium nitroprusside, glycine, and an alkaline buffer. A purplelavender discoloration of the tablet indicates the presence of acetoacetate or acetone (≥ 5 mg/dl). A rough estimate of the amount of ketone bodies can be obtained by comparison with the color chart provided by the manufacturer.
 
The test is more sensitive than reagent strip test for ketones.
 
3. FERRIC CHLORIDE TEST (Gerhardt’s)
 
Addition of 10% ferric chloride solution to urine causes solution to become reddish or purplish if acetoacetic acid is present. The test is not specific since certain drugs (salicylate and L-dopa) give similar reaction. Sensitivity of the test is 25-50 mg/dl.
 
4. REAGENT STRIP TEST
 
Reagent strips tests are modifications of nitroprusside test (Figures 822.1 and 822.2). Their sensitivity is 5-10 mg/dl of acetoacetate. If exposed to moisture, reagent strips often give false-negative result. Ketone pad on the strip test is especially vulnerable to improper storage and easily gets damaged. Also read: URINE STRIP TEST — UNDERSTANDING ITS LIMITATIONS.

TESTS FOR DETECTION OF PROTEINURIA

Published in Clinical Pathology
Monday, 07 August 2017 13:36
1. HEAT AND ACETIC ACID TEST (BOILING TEST)
 
This test is based on the principle that proteins get precipitated when boiled in an acidic solution.
 
Method
 
Urine should be clear; if not, filter or use supernatant from a centrifuged sample.
 
Urine should be just acidic (check with litmus paper); if not, add 10% acetic acid drop by drop until blue litmus paper turns red.
 
A test tube is filled 2/3rds with urine. The tube is inclined at an angle and the upper portion is boiled over the flame. (Only the upper portion is heated so that convection currents generated by heat do not disturb the precipitate and the upper portion can be compared with the lower clear portion). Compare the heated part with the lower part. Cloudiness or turbidity indicates presence of either phosphates or proteins (Figure 821.1). A few drops of 10% acetic acid are added and the upper portion is boiled again. Turbidity due to phosphates disappears while that due to proteins does not.
 
Figure 821.1 Principle of heat test for proteins
Figure 821.1 Principle of heat test for proteins
 
False-positive test occurs with tolbutamide and large doses of penicillins.
 
2. REAGENT STRIP TEST
 
The reagent area of the strip is coated with an indicator and buffered to an acid pH which changes color in the presence of proteins (Figures 821.2 and 821.3). The principle is known as “protein error of indicators”.
 
Figure 821.2 Principle of reagent strip test for proteins
Figure 821.2 Principle of reagent strip test for proteins. The principle is called as ‘protein error of indicators’ meaning that one color appears if protein is present and another color if protein is absent. Sensitivity is 5-10 mg/dl. The test does not detect Bence Jones proteins, hemoglobin, and myoglobin
 
The reagent area is impregnated with bromophenol blue indicator buffered to pH 3.0 with citrate. When the dye gets adsorbed to protein, there is change in ionization (and hence pH) of the indicator that leads to change in color of the indicator. The intensity of the color produced is proportional to the concentration of protein. The test is semi-quantitative.
 
Figure 821.3 Grading of proteinuria with reagent strip test
Figure 821.3 Grading of proteinuria with reagent strip test (above) and sulphosalicylic acid test (below)
 
Reagent strip test is mainly reactive to albumin. It is false-negative in the presence of Bence Jones proteins, myoglobin, and hemoglobin. Overload (Bence Jones) proteinuria and tubular proteinuria may be missed entirely if only reagent strip method is used. This test should be followed by sulphosalicylic acid test, which is a confirmatory test. Highly alkaline urine, gross hematuria, and contamination with vaginal secretions can give false-positive reactions. Also read: URINE STRIP TEST — UNDERSTANDING ITS LIMITATIONS.
 
3. SULPHOSALICYLIC ACID TEST
 
Addition of sulphosalicylic acid to the urine causes formation of a white precipitate if proteins are present (Proteins are denatured by organic acids and precipitate out of solution).
 
Take 2 ml of clear urine in a test tube. If reaction of urine is neutral or alkaline, a drop of glacial acetic acid is added. Add 2-3 drops of sulphosalicylic acid (3 to 5%), and examine for turbidity against a dark background (Figure 821.3).
 
This test is more sensitive and reliable than boiling test.
 
False-positive test may occur due to gross hematuria, highly concentrated urine, radiographic contrast media, excess uric acid, tolbutamide, sulphonamides, salicylates, and penicillins.
 
False-negative test can occur with very dilute urine.
 
The test can detect albumin, hemoglobin, myoglobin, and Bence Jones proteins.
 
Comparison of reagent strip test and sulphosalicylic acid test is shown in Table 821.1.
 
Table 821.1 Comparison of two tests for proteinuria
Parameter Reagent strip test Sulphosalicylic acid test
1. Principle Colorimetric Acid precipitation
2. Proteins detected Albumin All (albumin, Bence Jones proteins, hemoglobin, myoglobin)
3. Sensitivity 5-10 mg/dl 20 mg/dl
4. Indicator Color change Turbidity
5. Type of test Screening Confirmatory
 
QUANTITATIVE ESTIMATION OF PROTEINS
 
Indications for quantitative estimation of proteins in urine are:
 
  • Diagnosis of nephrotic syndrome
  • Detection of microalbuminuria or early diabetic nephropathy
  • To follow response to therapy in renal disease
 
Proteinuria >1500 mg/ 24 hours indicates glomerular disease; proteinuria >3500 mg/24 hours is called as nephrotic range proteinuria; in tubular, hemodynamic and post renal diseases, proteinuria is usually < 1500 mg/24 hours.
 
Grading of albuminuria is shown in Table 821.2. There are two methods for quantitation of proteins:
 
  1. Estimation of proteins in a 24-hour urine sample, and
  2. Estimation of protein/creatinine ratio in a random urine sample.
 
Table 821.2 Grading of albuminuria
Condition mg/24 hr mg/L mg/g creatinine μg/min μg/mg creatinine g/mol creatinine
Normal < 30 < 20 < 20 < 20 < 30 < 2.5
Microalbuminuria 30-300 20-200 20-300 20-200 30-300 2.5-25
Overt albuminuria > 300 > 200 > 300 > 200 > 300 > 25
 
1. Quantitative estimation of proteins in a 24-hour urine sample: Collection of a 24-hour sample is given earlier. Adequacy of sample is confirmed by calculating expected 24-hour urine creatinine excretion. Daily urinary creatinine excretion depends on muscle mass and remains relatively constant in an individual patient. In adult males creatinine excretion is 14-26 mg/kg/24 hours, while in women it is 11-20 mg/kg/24 hours. Various methods are available for quantitative estimation of proteins: Esbach’s albuminometer method, turbidimetric methods, biuret reaction, and immunologic methods.
 
2. Estimation of protein/creatinine ratio in a random urine sample: Because of the problem of incomplete collection of a 24-hour urine sample, many laboratories measure protein/creatinine ratio in a random urine sample. Normal protein/creatinine ratio is < 0.2. In low-grade proteinuria it is 0.2-1.0; in moderate, it is 1.0-3.5; and in nephrotic- range proteinuria it is > 3.5.
 
MICROALBUMINURIA
 
This is defined as urinary excretion of 30 to 300 mg/24 hours (or 2-20 mg/dl) of albumin in urine.
 
Significance of Microalbuminuria
 
  1. Microalbuminuria is considered as the earliest sign of renal damage in diabetes mellitus (diabetic nephropathy). It indicates increase in capillary permeability to albumin and denotes microvascular disease. Microalbuminuria precedes the development of diabetic nephropathy by a few years. If blood glucose level and hypertension are tightly controlled at this stage by aggressive treatment then progression to irreversible renal disease and subsequent renal failure can be delayed or prevented.
  2. Microalbuminuria is an independent risk factor for cardiovascular disease in diabetes mellitus.
 
Detection of Microalbuminuria: Microalbuminuria cannot be detected by routine tests for proteinuria. Methods for detection include:
 
  • Measurement of albumin-creatinine ratio in a random urine sample
  • Measurement of albumin in an early morning or random urine sample
  • Measurement of albumin in a 24 hr sample
 
Test strips that screen for microalbuminuria are available commercially. Exact quantitation can be done by immunologic assays like radioimmunoassay or enzyme linked immunosorbent assay.
 
BENCE JONES PROTEINURIA
 
Bence Jones proteins are monoclonal immunoglobulin light chains (either κ or λ) that are synthesized by neoplastic plasma cells. Excess production of these light chains occurs in plasma cell dyscrasias like multiple myeloma and primary amyloidosis. Because of their low molecular weight and high concentration they are excreted in urine (overflow proteinuria).
 
Bence Jones proteins have a characteristic thermal behaviour. When heated, Bence Jones proteins precipitate at temperatures between 40°C to 60°C (other proteins precipitate between 60-70°C), and precipitate disappears on further heating at 85-100°C (while precipitate of other proteins does not). When cooled (60-85°C), there is reappearance of precipitate of Bence Jones proteins. This test, however, is not specific for Bence Jones proteins and both false-positive and -negative results can occur. This test has been replaced by protein electrophoresis of concentrated urine sample (Figure 821.4).
 
Figure 821.4 Urine protein electrophoresis showing heavy Bence Jones proteinuria
Figure 821.4 Urine protein electrophoresis showing heavy Bence Jones proteinuria (red arrow) along with loss of albumin and other low molecular weight proteins in urine
 
Further evaluation of persistent overt proteinuria is shown in Figure 821.5.
 
Figure 821.5 Evaluation of proteinuria
Figure 821.5 Evaluation of proteinuria.
Note: Quantitation of proteins and creatinine clearance are done in all patients with persistent proteinuria

TESTS FOR DETECTION OF GLUCOSE IN URINE

Published in Clinical Pathology
Saturday, 05 August 2017 23:28
1. COPPER REDUCTION METHODS
 
A. Benedict’s qualitative test: When urine is boiled in Benedict’s qualitative solution, blue alkaline copper sulphate is reduced to red-brown cuprous oxide if a reducing agent is present (Figure 820.1). The extent of reduction depends on the concentration of the reducing substance. This test, however, is not specific for glucose.
 
Figure 820.1 Principle of Benedict’s qualitative test for sugar in urine
Figure 820.1 Principle of Benedict’s qualitative test for sugar in urine. Sensitivity is 200 mg of glucose/dl
 
Other carbohydrates (like lactose, fructose, galactose, pentoses), certain metabolites (glucuronic acid, homogentisic acid, uric acid, creatinine), and drugs (ascorbic acid, salicylates, cephalosporins, penicillins, streptomycin, isoniazid, para-aminosalicylic acid, nalidixic acid, etc.) also reduce alkaline copper sulphate solution.
 
Method
 
  1. Take 5 ml of Benedict’s qualitative reagent in a test tube (composition of Benedict’s qualitative reagent: copper sulphate 17.3 gram, sodium carbonate 100 gram, sodium citrate 173 gram, distilled water 1000 ml).
  2. Add 0.5 ml (or 8 drops) of urine. Mix well.
  3. Boil over a flame for 2 minutes.
  4. Allow to cool at room temperature.
  5. Note the color change, if any.
 
Sensitivity of the test is about 200 mg reducing substance per dl of urine. Since Benedict’s test gives positive reaction with carbohydrates other than glucose, it is also used as a screening test (for detection of galactose, lactose, fructose, maltose, and pentoses in urine) for inborn errors of carbohydrate metabolism in infants and children. For testing urine only for glucose, reagent strips are preferred (see below).
 
The result is reported in grades as follows (Figure 820.2):
 
  • Nil: no change from blue color
  • Trace: Green without precipitate
  • 1+ (approx. 0.5 grams/dl): Green with precipitate
  • 2+ (approx. 1.0 grams/dl): Brown precipitate
  • 3+ (approx. 1.5 grams/dl: Yellow-orange precipitate
  • 4+ (> 2.0 grams/dl): Brick- red precipitate.
 
Figure 820.2 Grading of Benedicts test
Figure 820.2 Grading of Benedict’s test (above) and reagent strip test (below) for glucose
 
B. Clinitest tablet method (Copper reduction tablet test): This is a modified form of Benedict’s test in which the reagents are present in a tablet form (copper sulphate, citric acid, sodium carbonate, and anhydrous sodium hydroxide). Sensitivity is 200 mgs/dl of glucose.
 
2. REAGENT STRIP METHOD
 
This test is specific for glucose and is therefore preferred over Benedict’s and Clinitest methods. It is based on glucose oxidase-peroxidase reaction. Reagent area of the strips is impregnated with two enzymes (glucose oxidase and peroxidase) and a chromogen. Glucose is oxidized by glucose oxidase with the resultant formation of hydrogen peroxide and gluconic acid. Oxidation of chromogen occurs in the presence of hydrogen peroxide and the enzyme peroxidase with resultant color change (Figure 820.3). Nature of chromogen and buffer system differ in different strips. Also read: URINE STRIP TEST — UNDERSTANDING ITS LIMITATIONS.
 
The strip is dipped into the urine sample and color is observed after a specified time and compared with the color chart provided (Figure 820.2).
 
Figure 820.3 Principle of reagent strip test for glucose in urine
Figure 820.3 Principle of reagent strip test for glucose in urine. Each mole of glucose produces one mole of peroxide, and each mole of peroxide reduces one mole of oxygen. Sensitivity is 100 mg glucose/100 ml
 
This test is more sensitive than Benedict’s qualitative test and specific only for glucose. Other reducing agents give negative reaction.
 
Sensitivity of the test is about 100 mg glucose/dl of urine.
 
False-positive test occurs in the presence of oxidizing agent (bleach or hypochlorite used to clean urine containers), which oxidizes the chromogen directly.
 
False-negative test occurs in the presence of large amounts of ketones, salicylates, ascorbic acid, and severe Escherichia coli infection (catalase produced by organisms in urine inactivates hydrogen peroxide).

PHYSICAL EXAMINATION OF URINE

Published in Clinical Pathology
Saturday, 05 August 2017 17:22
The parameters to be examined on physical examination of urine are listed below.
 
  • Volume
  • Color
  • Appearance
  • Odor
  • Specific Gravity
  • pH
 
VOLUME
 
Volume of only the 24-hr specimen of urine needs to be measured and reported. The average 24-hr urinary output in adults is 600-2000 ml. The volume varies according to fluid intake, diet, and climate. Abnormalities of urinary volume are as follows:
 
  • Polyuria means urinary volume > 2000 ml/24 hours. This is seen in diabetes mellitus (osmotic diuresis), diabetes insipidus (failure of secretion of antidiuretic hormone), chronic renal failure (loss of concentrating ability of kidneys) or diuretic therapy.
  • Oliguria means urinary volume < 400 ml/24 hours. Causes include febrile states, acute glomerulonephritis (decreased glomerular filtration), congestive cardiac failure or dehydration (decreased renal blood flow).
  • Anuria means urinary output < 100 ml/24 hours or complete cessation of urine output. It occurs in acute tubular necrosis (e.g. in shock, hemolytic transfusion reaction), acute glomerulonephritis, and complete urinary tract obstruction.
 
COLOR
 
Normal urine color in a fresh state is pale yellow or amber and is due to the presence of various pigments collectively called urochrome. Depending on the state of hydration urine may normally be colorless (over hydration) or dark yellow (dehydration). Some of the abnormal colors with associated conditions are listed in Table 819.1.
 
Table 819.1 Different colors of urine
Colors Conditions
Colorless Dilute urine (diabetes mellitus, diabetes insipidus, overhydration)
Red Hematuria, Hemoglobinuria, Porphyria, Myoglobinuria
Dark brown or black Alkaptonuria, Melanoma
Brown Hemoglobinuria
Yellow Concentrated urine
Yellow-green or green Biliverdin
Deep yellow with yellow foam Bilirubin
Orange or orange-brown Urobilinogen/Porphobilinogen
Milky-white Chyluria
Red or orange fluorescence with UV light Porphyria
Note: Many drugs cause changes in urine color; drug history should be obtained if there is abnormal coloration of urine
 
APPEARANCE
 
Normal, freshly voided urine is clear in appearance. Causes of cloudy or turbid urine are listed in Table 819.2. Foamy urine occurs in the presence of excess proteins or bilirubin.
 
Table 819.2 Causes of cloudy or turbid urine
Cause Appearance Diagnosis
1. Amorphous phosphates White and cloudy on standing in alkaline urine Disappear on addition of a drop of dilute acetic acid
2. Amorphous urates Pink and cloudy in acid urine Dissolve on warming
3. Pus cells Varying grades of turbidity Microscopy
4. Bacteria Uniformly cloudy; do not settle at the bottom following centrifugation Microscopy, Nitrite test
 
ODOR
 
Freshly voided urine has a typical aromatic odor due to volatile organic acids. After standing, urine develops ammoniacal odor (formation of ammonia occurs when urea is decomposed by bacteria). Some abnormal odors with associated conditions are:
 
  • Fruity: Ketoacidosis, starvation
  • Mousy or musty: Phenylketonuria
  • Fishy: Urinary tract infection with Proteus, tyrosinaemia.
  • Ammoniacal: Urinary tract infection with Escherichia coli, old standing urine.
  • Foul: Urinary tract infection
  • Sulfurous: Cystinuria.
 
SPECIFIC GRAVITY (SG)
 
This is also called as relative mass density. It depends on amount of solutes in solution. It is basically a comparison of density of urine against the density of distilled water at a particular temperature. Specific gravity of distilled water is 1.000. Normal SG of urine is 1.003 to 1.030 and depends on the state of hydration. SG of normal urine is mainly related to urea and sodium. SG increases as solute concentration increases and decreases when temperature rises (since volume expands with rise in temperature).
 
SG of urine is a measure of concentrating ability of kidneys and is determined to get information about this tubular function. SG, however, is affected by proteinuria and glycosuria.
 
Causes of increase in SG of urine are diabetes mellitus (glycosuria), nephrotic syndrome (proteinuria), fever, and dehydration.
 
Causes of decrease in SG of urine are diabetes insipidus (SG consistently between 1.002-1.003), chronic renal failure (low and fixed SG at 1.010 due to loss of concentrating ability of tubules) and compulsive water drinking.
 
Methods for measuring SG are urinometer method, refractometer method, and reagent strip method.

1. Urinometer method: This method is based on the principle of buoyancy (i.e. the ability of a fluid to exert an upward thrust on a body placed in it). Urinometer (a hydrometer) is placed in a container filled with urine (Figure 819.1A). When solute concentration is high, upthrust of solution increases and urinometer is pushed up (high SG). If solute concentration is low, urinometer sinks further into the urine (low SG).
 
Figure 819.1 A. Urinometer method and B. Reagent strip method for measuring specific gravity of urine
Figure 819.1 (A) Urinometer method and (B) Reagent strip method for measuring specific gravity of urine
 
Accuracy of a urinometer needs to be checked with distilled water. In distilled water, urinometer should show SG of 1.000 at the temperature of calibration. If not, then the difference needs to be adjusted in test readings taken subsequently.
 
The method is as follows:
 
  1. Fill a measuring cylinder with 50 ml of urine.
  2. Lower urinometer gently into the urine and let it float freely.
  3. Let urinometer settle; it should not touch the sides or bottom of the cylinder.
  4. Take the reading of SG on the scale (lowest point of meniscus) at the surface of the urine.
  5. Take out the urinometer and immediately note the temperature of urine with a thermometer.
 
Correction for temperature: Density of urine increases at low temperature and decreases at higher temperature. This causes false reading of SG. Therefore, SG is corrected for difference between urine temperature and calibration temperature. Check the temperature of calibration of the urinometer To get the corrected SG, add 0.001 to the reading for every 3°C that the urine temperature is above the temperature of calibration. Similarly subtract 0.001 from the reading for every 3°C below the calibration temperature.
 
Correction for dilution: If quantity of urine is not sufficient for measurement of SG, urine can be appropriately diluted and the last two figures of SG are multiplied by the dilution factor.
 
Correction for abnormal solute concentration: High SG in the presence of glycosuria or proteinuria will not reflect true kidney function (concentrating ability). Therefore it is necessary to nullify the effect of glucose or proteins. For this, 0.003 is subtracted from temperature-corrected SG for each 1 gm of protein/dl urine and 0.004 for every 1 gm of glucose/dl urine.
 
2. Refractometer method: SG can be precisely determined by a refractometer, which measures the refractive index of the total soluble solids. Higher the concentration of total dissolved solids, higher the refractive index. Extent of refraction of a beam of light passed through urine is a measure of solute concentration, and thus of SG. The method is simple and requires only 1-2 drops of urine. Result is read from a scale or from digital display.
 
3. Reagent strip method: Reagent strip (Figure 819.1B) measures the concentration of ions in urine, which correlates with SG. Depending on the ionic strength of urine, a polyelectrolyte will ionize in proportion. This causes a change in color of pH indicator (bromothymol blue). Also read: URINE STRIP TEST — UNDERSTANDING ITS LIMITATIONS.
 
REACTION AND pH
 
The pH is the scale for measuring acidity or alkalinity (acid if pH is < 7.0; alkaline if pH is > 7.0; neutral if pH is 7.0). On standing, urine becomes alkaline because of loss of carbon dioxide and production of ammonia from urea. Therefore, for correct estimation of pH, fresh urine should be examined.
 
There are various methods for determination of reaction of urine: litmus paper, pH indicator paper, pH meter, and reagent strip tests.
 
  1. Litmus paper test: A small strip of litmus paper is dipped in urine and any color change is noted. If blue litmus paper turns red, it indicates acid urine. If red paper turns blue, it indicates alkaline urine (Figure 819.2A).
  2. pH indicator paper: Reagent area (which is impregnated with bromothymol blue and methyl red) of indicator paper strip is dipped in urine sample and the color change is compared with the color guide provided. Approximate pH is obtained.
  3. pH meter: An electrode of pH meter is dipped in urine sample and pH is read off directly from the digital display. It is used if exact pH is required.
  4. Reagent strip test: The test area (Figure 819.2B) contains polyionic polymer bound to H+; on reaction with cations in urine, H+ is released causing change in color of the pH-sensitive dye. Also read: URINE STRIP TEST — UNDERSTANDING ITS LIMITATIONS.
 
Figure 819.2 A. Testing pH of urine with litmus paper and B. with reagent strip test
Figure 819.2 Testing pH of urine with litmus paper (A) and with reagent strip test (B)
 
Normal pH range is 4.6 to 8.0 (average 6.0 or slightly acidic). Urine pH depends on diet, acid base balance, water balance, and renal tubular function.
 
Acidic urine is found in ketosis (diabetes mellitus, starvation, fever), urinary tract infection by Escherichia coli, and high protein diet. Alkaline urine may result from urinary tract infection by bacteria that split urea to ammonia (Proteus or Pseudomonas), severe vomiting, vegetarian diet, old ammoniacal urine sample and chronic renal failure.
 
Determining pH of urine helps in identifying various crystals in urine. Altering pH of urine may be useful in treatment of renal calculi (i.e. some stones form only in acid urine e.g. uric acid calculi; in such cases urine is kept alkaline); urinary tract infection (urine should be kept acid); and treatment with certain drugs (e.g. streptomycin is effective in urinary tract infection if urine is kept alkaline). In unexplained metabolic acidosis, measurement of urine pH is helpful in diagnosing renal tubular acidosis; in renal tubular acidosis, urine pH is consistently alkaline despite metabolic acidosis.

TEST FOR DETECTION OF UROBILINOGEN IN URINE

Published in Clinical Pathology
Saturday, 05 August 2017 15:23
Fresh urine sample should be used because on standing urobilinogen is converted to urobilin, which cannot be detected by routine tests. A timed (2-hour postprandial) sample can also be used for testing urobilinogen.
 
Methods for detection of increased amounts of urobilinogen in urine are Ehrlich’s aldehyde test and reagent strip test.
 
1. EHRLICH’S ALDEHYDE TEST
 
Ehrlich’s reagent (pdimethylaminobenzaldehyde) reacts with urobilinogen in urine to produce a pink color. Intensity of color developed depends on the amount of urobilinogen present. Presence of bilirubin interferes with the reaction, and therefore if present, should be removed. For this, equal volumes of urine and 10% barium chloride are mixed and then filtered. Test for urobilinogen is carried out on the filtrate. However, similar reaction is produced by porphobilinogen (a substance excreted in urine in patients of porphyria).
 
Fig. 818.1 Ehrlichs aldehyde test for urobilinogen
Figure 818.1 Ehrlich’s aldehyde test for urobilinogen
 
Method: Take 5 ml of fresh urine in a test tube. Add 0.5 ml of Ehrlich’s aldehyde reagent (which consists of hydrochloric acid 20 ml, distilled water 80 ml, and paradimethylaminobenzaldehyde 2 gm). Allow to stand at room temperature for 5 minutes. Development of pink color indicates normal amount of urobilinogen. Darkred color means increased amount of urobilinogen (Figure 818.1).
 
Since both urobilinogen and porphobilinogen produce similar reaction, further testing is required to distinguish between the two. For this, Watson-Schwartz test is used. Add 1-2 ml of chloroform, shake for 2 minutes and allow to stand. Pink color in the chloroform layer indicates presence of urobilinogen, while pink coloration of aqueous portion indicates presence of porphobilinogen. Pink layer is then decanted and shaken with butanol. A pink color in the aqueous layer indicates porphobilinogen (Figure 818.2).
 
Figure 818.2 Interpretation of Watson Schwartz test
Figure 818.2 Interpretation of Watson-Schwartz test
 
False-negative reaction can occur in the presence of (i) urinary tract infection (nitrites oxidize urobilinogen to urobilin), and (ii) antibiotic therapy (gut bacteria which produce urobilinogen are destroyed).
 
2. REAGENT STRIP METHOD
 
This method is specific for urobilinogen. Test area is impregnated with either p-dimethylaminobenzaldehyde or 4-methoxybenzene diazonium tetrafluoroborate. Also read: URINE STRIP TEST — UNDERSTANDING ITS LIMITATIONS.

LABORATORY TESTS IN PORPHYRIAS

Published in Clinical Pathology
Thursday, 03 August 2017 18:15
Porphyrias (from Greek porphura meaning purple pigment; the name is probably derived from purple discoloration of some body fluids during the attack) are a heterogeneous group of rare disorders resulting from disturbance in the heme biosynthetic pathway leading to the abnormal accumulations of red and purple pigments called as porphyrins in the body. Heme, a component of hemoglobin, is synthesized through various steps as shown in Figure 817.1. Each of the steps is catalyzed by a separate enzyme; if any of these steps fails (due to hereditary or acquired cause), precursors of heme (porphyrin intermediates) accumulate in blood, get deposited in skin and other organs, and excreted in urine and feces. Depending on the site of defect, different types of porphyrias are described with varying clinical features, severity, and the nature of accumulated porphyrin.
 
Porphyria has been offered as a possible explanation for the medieval tales of vampires and werewolves; this is because of the number of similarities between the behavior of persons suffering from porphyria and the folklore (avoiding sunlight, mutilation of skin on exposure to sunlight, red teeth, psychiatric disturbance, and drinking of blood to obtain heme).
 
Porphyrias are often missed or wrongly diagnosed as many of them are not associated with definite physical findings, screening tests may yield false-negative results, diagnostic criteria are poorly defined and mild disorders produce an enzyme assay result within ‘normal’ range.
 
Heme is mainly required in bone marrow (for hemoglobin synthesis) and in liver (for cytochromes). Therefore, porphyrias are divided into erythropoietic and hepatic types, depending on the site of expression of disease. Hepatic porphyrias mainly affect the nervous system, while erythropoietic porphyrias primarily affect the skin. Porphyrias are also classified into acute and nonacute (or cutaneous) types depending on clinical presentation (Table 817.1).
 
Table 817.1 Various classification schemes for porphyrias
Classification based on predominant clinical manifestations
Classification based on site of expression of disease
Classification based on mode of clinical presentation
Neuropsychiatric
Hepatic
Acute
1. Acute intermittent porphyria
1. ALA-dehydratase porphyria
1. ALA-dehydratase porphyria (Plumboporphyria)
2. ALA-dehydratase porphyria (Plumboporphyria)
2. Acute intermittent porphyria
2. Acute intermittent porphyria
Cutaneous (Photosensitivity)
3. Hereditary coproporphyria
3. Hereditary coproporphyria
1. Congenital erythropoietic porphyria
4. Variegate porphyria
4. Variegate porphyria
2. Porphyria cutanea tarda
Erythropoietic porphyria
Non-acute (cutaneous)
3. Erythropoietic protoporphyria
1. Congenital erythropoietic porphyria
1. Porphyria cutanea tarda
Mixed (Neuropsychiatric and cutaneous)
2. Erythropoietic protoporphyria
2. Congenital erythropoietic porphyria
1. Hereditary coproporphyria
Hepatic/Erythropoietic
3. Erythropoietic protoporphyria
2. Variegate porphyria
1. Porphyria cutanea tarda
 
 
Inheritance of porphyrias may be autosomal dominant or recessive. Most acute porphyrias are inherited in an autosomal dominant manner (i.e. inheritance of one abnormal copy of gene). Therefore, the activity of the deficient enzyme is 50%. When the level of heme falls in the liver due to some cause, activity of ALA synthase is stimulated leading to increase in the levels of heme precursors up to the point of enzyme defect. Increased levels of heme precursors cause symptoms of acute porphyria. When the heme level returns back to normal, symptoms subside.
 
Accumulation of porphyrin precursors can occur in lead poisoning due to inhibition of enzyme aminolevulinic acid dehydratase in heme biosynthetic pathway. This can mimick acute intermittent porphyria.
 
CLINICAL FEATURES
 
Clinical features of porphyrias are variable and depend on type. Acute porphyrias present with symptoms like acute and severe abdominal pain/vomiting/constipation, chest pain, emotional and mental disorders, seizures, hypertension, tachycardia, sensory loss, and muscle weakness. Cutaneous porphyrias present with photosensitivity (redness and blistering of skin on exposure to sunlight), itching, necrosis of skin and gums, and increased hair growth over the temples (Table 817.2).
 
Table 817.2 Clinical characteristics of porphyrias
Porphyria Deficient enzyme Clinical features Inheritance Initial test
1. Acute intermittent porphyria (AIP)* PBG deaminase Acute neurovisceral attacks; triggering factors+ (e.g. drugs, diet restriction) Autosomal dominant Urinary PBG; urine becomes brown, red, or black on standing
2. Variegate porphyria Protoporphyrinogen oxidase Acute neurovisceral attacks + skin fragility, bullae Autosomal dominant Urinary PBG
3. Hereditary coproporphyria Coproporphyrinogen oxidase Acute neurovisceral attacks + skin fragility, bullae Autosomal dominant Urinary PBG
4. Congenital erythropoietic porphyria Uroporphyrinogen cosynthase Onset in infancy; skin fragility, bullae; extreme photosensitivity with mutilation; red teeth and urine (pink red urinestaining of diapers) Autosomal recessive Urinary/fecal total porphyrins; ultraviolet fluorescence of urine, feces, and bones
5. Porphyria cutanea tarda* Uroporphyrinogen decarboxylase Skin fragility, bullae Autosomal dominant (some cases) Urinary/fecal total porphyrins
6. Erythropoietic protoporphyria* Ferrochelatase Acute photosensitivity Autosomal dominant Free erythrocyte protoporphyrin
Disorders marked with * are the three most common porphyrias. PBG: Porphobilinogen
  
Symptoms can be triggered by drugs (barbiturates, oral contraceptives, diazepam, phenytoin, carbamazepine, methyldopa, sulfonamides, chloramphenicol, and antihistamines), emotional or physical stress, infection, dieting, fasting, substance abuse, premenstrual period, smoking, and alcohol. Autosomal dominant porphyrias include acute intermittent porphyria, variegate porphyria, porphyria cutanea tarda, erythropoietic protoporphyria (most cases), and hereditary coproporphyria. Autosomal recessive porphyrias include: congenital erythropoietic porphyria, erythropoietic protoporphyria (few cases), and ALAdehydratase porphyria (plumboporphyria).
 
LABORATORY DIAGNOSIS
 
Porphyria can be diagnosed through tests done on blood, urine, and feces during symptomatic period. Timely and accurate diagnosis is required for effective management of porphyrias. Due to the variability and a broad range of clinical features, porphyrias are included under differential diagnosis of many conditions. All routine hospital laboratories usually have facilities for initial investigations in suspected cases of porphyrias; laboratory tests for identification of specific type of porphyrias are available in specialized laboratories.
 
INITIAL STUDIES
 
In suspected acute porphyrias (acute neurovisceral attack), a fresh randomly collected urine sample (10-20 ml) should be submitted for detection of excessive urinary excretion of porphobilinogen (PBG) (see Figure 817.2). In AIP, urine becomes red or brown on standing (see Figure 817.3). In suspected cases of cutaneous porphyrias (acute photosensitivity without skin fragility), free erythrocyte protporphyrin or FEP in EDTA blood (for diagnosis of erythrocytic protoporphyria) and for all other cutaneous porphyrias (skin fragility and bullae), examination of fresh, random urine (10-20 ml) and either feces (5-10 g) or plasma for excess porphyrins are necessary (see Figure 817.4 and Table 817.2).
 
Figure 817.2 Evaluation of acute neurovisceral porphyria
 Figure 817.2 Evaluation of acute neurovisceral porphyria
 
Figure 817.3 Red coloration of urine on standing in acute intermittent porphyria
Figure 817.3 Red coloration of urine on standing in acute intermittent porphyria
 
Figure 817.4 Evaluation of cutaneous porphyrias
Figure 817.4 Evaluation of cutaneous porphyrias
 
Apart from diagnosis, the detection of excretion of a particular heme intermediate in urine or feces can help in detecting site of defect in porphyria. Heme precursors up to coproporphyrinogen III are water-soluble and thus can be detected in urine. Protoporphyrinogen and Protoporphyrin are insoluble in water and are excreted in bile and can be detected in feces. All samples should be protected from light.
 
Samples required are
 
  1. 10-20 ml of fresh random urine sample without any preservative;
  2. 5-10 g wet weight of fecal sample, and
  3. blood anticoagulated with EDTA.
 
Test for Porphobilinogen in Urine
 
Ehrlich’s aldehyde test is done for detection of PBG. Ehrlich’s reagent (p-dimethylaminobenzaldehyde) reacts with PBG in urine to produce a red color. The red product has an absorption spectrum with a peak at 553 nm and a shoulder at 540 nm. Since both urobilinogen and porphobilinogen produce similar reaction, further testing is required to distinguish between the two. Urobilinogen can be removed by solvent extraction. (See Watson-Schwartz test). Levels of PBG may be normal or near normal in between attacks. Therefore, samples should be tested during an attack to avoid false-negative results.
 
Test for Total Porphyrins in Urine
 
Total porphyrins can be detected in acidified urine sample by spectrophotometry (Porphyrins have an intense absorbance peak around 400 nm). Semiquantitative estimation of porphyrins is possible.
 
Test for Total Porphyrins in Feces
 
Total porphyrins in feces can be determined in acidic extract of fecal sample by spectrophotometry; it is necessary to first remove dietary chlorophyll (that also absorbs light around 400 nm) by diethyl ether extraction.
 
Tests for Porphyrins in Erythrocytes and Plasma
 
Visual examination for porphyrin fluorescence, and solvent fractionation and spectrophotometry have now been replaced by fluorometric methods.
 
Further Testing
 
If the initial testing for porphyria is positive, then concentrations of porphyrins should be estimated in urine, feces, and blood to arrive at specific diagnosis (Tables 817.3 and 817.4).
 
Table 817.3 Diagnostic patterns of concentrations of heme precursors in acute porphyrias
Porphyria Urine Feces
Acute intermittent porphyria PBG, Copro III
Variegate porphyria PBG, Copro III Proto IX
Hereditary coproporphyria PBG, Copro III Copro III
PBG: Porphobilinogen; Copro III: Coproporphyrinogen III; Proto IX: Protoporphyrin IX
 
Table 817.4 Diagnostic patterns of concentrations of heme precursors in cutaneous porphyrias
Porphyria Urine Feces Erythrocytes
Congenital erythropoietic porphyria Uro I, Copro I Copro I
Porphyria cutanea tarda Uroporphyrin Isocopro
Erythropoietic protoporphyria Protoporphyrin
Uro I: Uroporphyrinogen I; Copro I: Coproporphyrinogen I; Isocopro: Isocoproporphyrinogen
 
In latent porphyrias and in patients during remission, porphyrin levels may be normal; in such cases, enzymatic and DNA testing is necessary for diagnosis.
 
If porphyria is diagnosed, then it is necessary to investigate close family members for the disorder. Positive family members should be counseled regarding triggering factors.

PLATELET GLYCOPROTEIN ANALYSIS

Published in Hemotology
Thursday, 03 August 2017 16:55
This is done by flow cytometric analysis for detection of lack of GpIb/IX in Bernanrd Soulier syndrome (deficiency of CD42), and lack of GpIIb/IIIa in Glanzmann’s thrombasthenia (deficiency of CD41, CD61).
 
What is the best protocol for platelet glycoprotein (GPIIb/IIIa) analysis using flow cytometry?
 
Fresh platelets should always be used. Storing platelets dramatically changes the level of transmembrane proteins. The best way is to follow one of standardized protocols defined in: Immunophenotypic analysis of platelets. Krueger LA, Barnard MR, Frelinger AL 3rd, Furman MI, Michelson AD.Curr Protoc Cytom. 2002 Feb;Chapter 6:Unit 6.10

TEST FOR D-DIMER

Published in Hemotology
Thursday, 03 August 2017 16:33
D-dimer is derived from the breakdown of fibrin by plasmin and D-dimer test is used to evaluate fibrin degradation. Blood sample can be either serum or plasma. Latex or polystyrene microparticles coated with monoclonal antibody to D-dimer are mixed with patient’s sample and observed for microparticle agglutination. As the particle is small, turbidometric endpoint can be determined in automated instruments. D-dimer and FDPs are raised in disseminated intravascular coagulation, intravascular thrombosis (myocardial infarction, stroke, venous thrombosis, pulmonary embolism), and during postoperative period or following trauma. D-dimer test is commonly used for exclusion of thrombosis and thrombotic tendencies.
 
Further Reading:
 

TEST FOR FIBRINOGEN/FIBRIN DEGRADATION PRODUCTS (FDPs)

Published in Hemotology
Thursday, 03 August 2017 13:02
FDPs are fragments produced by proteolytic digestion of fibrinogen or fibrin by plasmin. For determination of FDPs, blood is collected in a tube containing thrombin (to remove all fibrinogen by converting it into a clot) and soybean trypsin inhibitor (to inhibit plasmin and thus prevent in vitro breakdown of fibrin). A suspension of latex particles linked to antifibrinogen antibodies (or fragments D and E) is mixed with dilutions of patient’s serum on a glass slide. If FDPs are present, agglutination of latex particles occurs (see Figure 814.1). The highest dilution of serum at which agglutination is detected is used to determine concentration of FDPs. Increased levels of FDPs occur in fibrinogenolysis or fibrinolysis. This occurs in disseminated intravascular coagulation, deep venous thrombosis, severe pneumonia, and recent myocardial infarction.

QUALITY CONTROL OF ALL LABORATORY EQUIPMENT

Published in Biomedical Engineering
Wednesday, 02 August 2017 09:18
Because diagnoses and treatment plans are made based on laboratory findings, it is imperative that the equipment utilized in the lab be in excellent working order, serviced at regular intervals, calibrated and cleaned as recommended by the manufacturer, and used properly. In addition to properly functioning equipment, there are things the technician can do to improve the accuracy of their test results:
 
  1. Follow manufacturer directions precisely.
  2. Become familiar with normal and abnormal findings.
  3. Log all activity of equipment, including daily, weekly, and monthly servicing.
  4. Save enough sample to perform tests more than once to verify accuracy of findings.

 

Remember, all laboratory equipment and its results are only as reliable as the human operating the equipment!
Advertisement

Useful Sites

  • NCBI

    National Center for Biotechnology Information
  • LTO

    Lab Tests Online® by AACC
  • ASCP

    American Society for Clinical Pathology
  • ASM

    American Society for Microbiology
  • The Medical Library®

    Project of BioScience.pk
Advertisement

Connect With Us

Contact Us

All comments and suggestions about this web site are very welcome and a valuable source of information for us. Thanks!

Tel: +(92) 302 970 8985-6

Email: This email address is being protected from spambots. You need JavaScript enabled to view it.

Website: https://www.bioscience.pk



This website is certified by Health On the Net Foundation. Click to verify. This site complies with the HONcode standard for trustworthy health information:
verify here.

Our Sponsors

InsightGadgets.comPathLabStudyTheMedicalLibrary.orgThe Physio ClubB2BPakistan.com

By using BioScience.pk you agree to our use of cookies to enhance your experience on this website.