Chemical Examination of Urine PDF

Summary

This document provides an overview of chemical analysis of urine, including various tests like glucose determination using Benedict's and Fehling's methods. It also discusses different types of urinary sugar tests and their significance in clinical diagnosis. The document details the principles, procedures, and results interpretation of the tests.

Full Transcript

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CHAPTER FOUR

Chemical Analysis of Urine
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Chapter Outline
Objectives
Determination of Urinary sugar
Determination of Urinary ketone bodies
Determination of Urinary protein
Determination of Urinary hemoglobin
Determination of Urinary Bilirubin
Determination of Urinary urobilinogen
Determination of Urinary urobilin
Determination of Urinary Porphybilinogen
Determination of Urinary lecuocyte estrase
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Chapter Outline…
Determination of Urinary Nitrite
Determination of Urinary Calcium
Determination of Urinary indicant
Determination of Urinary Melanin
Determination of Urinary Ascorbic Acid
Determination of Urinary phenyl pyruvic Acid
Determination of Urinary Mucopolysacchride
Determination of Urinary Hemosiderine
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Learning objectives
❖At the end of this chapter the students will able to:-
to carry out how to perform chemical tests and show the
various types of methods used to determine the chemical
constituent:-
– Know the interfering factors during their work
– Expected to differentiate the principles of each test
– Explain the test procedures
– Know the clinical significance of the tests
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Introduction
Chemical analysis of urine deals with those procedures or
examinations which are accomplished by means of chemical
reactions.
Chemical test are done for a quick screening of urine for certain
substances which have a diagnostic significance.
Abnormal or pathological dissolved constituents of urine
(chemicals) performed in routine urinalysis.
Chemical analysis of urine is important in the detection of
many diseases.
In abnormal (pathological) conditions its composition varies in
kind and quantities.
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Introduction…
So the chemical changes of urine can indicate disease at the
early stage.
Urine composition depends greatly on how much and what
specific waste material is to be excreted.
Urea, creatinine, uric acid, ammonium salts, chlorides, sulphates and
phosphates of sodium, potassium, calcium and magnesium are the
normal composition of urine.
Glucose, protein, ketone bodies, bilirubin, bile salts etc. are
the abnormal constituents of urine.
Normally these substances do not appear in the urine in
detectable amount.
So their appearance in the urine shows the pathological
condition.
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Chemical analysis
Chemical analysis of urine can be classified as:-
✓Screening test
✓Qualitative test
✓Quantitative test
Screening test:- tells the presence or absence of the abnormal
components of urine. e.g., dipstick tests
Qualitative test:- tells semi-quantitatively the amount of
solutes that exist at the detectable level in pathological or
physiological conditions. e.g., bilirubin, protein
Quantitative test:- tells the exact amount of abnormal
constituents if they are detectable. e.g., 24-hour urine protein
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Chemical Reaction Chart
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General Precaution for reagent strips
Store strips in a cool, dry place to prevent deterioration.
Do not use strips if they are discolored.
Do not touch the test areas.
Keep the test areas away from detergents or other
contaminating substances.
Dip the test areas into the urine specimen completely, but
briefly to avoid dissolving the reagents out of the test
area.
Remove only the number of reagent strips required at a
particular time, and keep the container tightly covered at
all times to prevent deterioration.
Read the test results carefully, at the time specified by the
manufacturer, in a good light and with the test area held
near the appropriate color chart on the bottle label.
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Determination of Glucose
Glucose is the sugar most commonly found in the urine,
although other sugars, such as lactose, fructose, galactose, and
pentose, may be found under certain condition.
The presence of detectable amount of glucose in the urine is
known as glycosuria.
Normally almost all the glucose, which passes from the blood
into the glomerular filtrate, is reabsorbed back into the
circulation by the kidney tubules (proximal convoluted
tubules).
Usually less than 15 - 20 mg/dl (0.8 mmol) is excreted in the
urine.
But this amount cannot be detected by the routine laboratory
tests.
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Glucose cont’d…
The blood glucose concentration normally lies between 70 and
120 mg/dl.
After a meal it may increase to 120 - 160 mg/dl.
If the blood glucose concentration becomes too high (usually
greater than 170 - 180 mg/dl), the excess glucose will not be
reabsorbed into the blood and glucose start appearing in urine.
The lowest blood glucose concentration that will result in
glycosuria is termed as the renal threshold.
The renal threshold refers to the concentration of a substance in
the blood at which the kidneys begin to excrete that substance
into the urine.
The most common condition in which the renal threshold for
glucose exceeds is diabetes mellitus.
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Causes of Glycosuria
Physiological
Pathological

Physiological
a. After large ingestion of carbohydrates

b. Anything that stimulates sympathetic nervous system

c. 15 to 20% cases of pregnancy

d. Renal Glycosuria: in some persons, glycosuria is found
when blood glucose is in normal range.
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Causes of Glycosuria
Pathological Glycosuria
A. Diabetes Mellitus:- a chronic metabolic disorder characterized
by high blood sugar levels due to either:-
insufficient insulin production or
the body's cells not responding effectively to insulin.
✓ Glucose is not properly metabolized and blood glucose
concentration rises, and
✓ When it is in range of 170 - 180 mg/dl, glucose starts appearing
in urine.
B. Glycosuria due to other endocrine disorders:-
A number of endocrine disorders can cause hyperglycemia, and
this may result in glycosuria,
- Hyperthyroidism
- Hyperadrenalism
- Hyperpitutarism
- Some diseases of pancreas
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Types of Urinary Sugar (Glucose) Test

1. Non-specific reduction tests based on the reduction of
certain metal ion by glucose.
2. Specific (Enzymatic) tests based on the action of
glucose oxidase on glucose.
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Non-Specific Test for Glucose
Glucose is acting as a reducing agent and any compound with a
free aldehyde or ketone group will give the same reaction.
Hence glucose is not the only reducing substance that may
be found in urine.
Urine contains non-glucose reducing substances (NGRS) such
as: uric acid, creatinine, galactose, fructose, lactose, pentose,
homogenestic acid, ascorbic acid chloroform, and
formaldehyde.
❖ Commonly used non-specific tests for urinary sugar are:-
✓ Benedict’s Qualitative test
✓ Fehling test
✓ Clinitest tablet test
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Benedict’s Qualitative Test
Principle
When urine is boiled in an alkaline copper sulphate solution,
glucose and other reducing substances reduce (convert) the
blue copper (II) in Benedict's qualitative reagent to copper (I)
oxide (Cu2O), which is orange to red in color.
A positive reaction is graded as a change in color ranging
from blue to green, yellow, orange and finally red.
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The overall reaction is

The copper (II) ions are supplied in Benedict's qualitative
reagent in the form of copper sulphate (CuS04).
In the presence of a strong alkali this is converted to copper ( I)
oxide (Cu2O ).
The heat is supplied by means of a boiling water (1000C) bath.
The tubes are brought back to room temperature, and the
results are read when convenient.
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Procedure
1. Arrange test tubes (12ml) in a row rack.
2. Take two extra tubes for control runs:-
✓ negative with water and
✓ positive with 1.0 g/dl of glucose solution.
3. Add eight drops of well-mixed urine.
4. Add 5ml of Benedict’s reagent.
5. Mix well and place in a boiling water bath for 5 min.
6. Remove and cool to room temperature.
7. A positive: presence of a fine yellow to brick red
8. Graded on the basis of the color of solution.
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Grade results according to the following criteria:
1. Negative: No change in the blue color of the reagent or the
occurrence of a white or green precipitate from phosphates.
2. Trace: Slight amount of yellow precipitate with a greenish blue to
bluish green mixed solution less than 500mg/dl of sugar).
3. +: Moderate amount of yellow precipitate with green, often
referred to as apple green, mixed solution. (Approximately
500mg/dl of sugar).
4. ++: Large amount of yellow precipitate with a yellowish green,
often called muddy green mixed solution. (Appr.750mg/dl of
sugar).
5. +++: Large amount of yellow precipitate with green yellow, or
muddy orange, mixed solution. Some blue color remains in
supernatant. (Appr.1000mg/dl of sugar).
6. ++++: Large amount of yellow to red precipitate with reddish
yellow to red mixed solution. No blue remains in the supernatant
(Appr.2000mg/dl).
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Fehling’s Test

Principle: The same as benedict test

Fehling’s reagent

Solution A Solution B
Copper sulphate 34.65 g Sodium hydroxide 125 gm
Distilled water 500 ml Sodium potassium
tartarate173 gm
Distilled water 500 ml
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Procedure of reagent preparation
1. Take equal volume of Fehling’s solution A and solution B.
2. Mix and boil.
3. Add a few drops of urine and boil again.
4. If sugar is present, the same type of change occur as in the
Benedict’s test and are reported similarly.
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Advantage of Bendict’s Test over Fehling’s test
It uses a single solution already prepared
It uses a more stable reagent
It is about ten times more sensitive and traces of glucose will
not be caramelized.
If the test is carried out using the proper proportions of the
reagent and urine, it is more specific, as uric acid and creatinine
will not ordinarily reduce Benedict’s solution, under these
conditions.
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Clinitest Tablet Tests

Principle:
The same as that of Benedict's Qualitative Test.
Contains anhydrous sodium hydroxide, which results in
moderate boiling when added to dilute urine gives heat in its
reaction with citric acid.
Results are graded as negative, trace, 1+, 2+, 3+, or 4+ by
comparison on color chart.
Sensitivity
✓ Clinitest reagent tablets will detect as little as 250mg of
sugar in 100ml of urine.
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Procedure
Five drop method
Follow the direction supplied with the clintest tablets
1. Place 5 drops of urine in a test tube and add 10 drops of
distilled water.
2. Add one clintest tablet by easing it in to the tube with out
touching it. It contains strong alkali.
3. Watch while boiling takes place, but don’t shake or touch the
bottom of tube.
4. Wait 15 seconds after boiling stops, then shake the tube gently
and compare the color of the solution with the color scale.
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Cont…

Grade the results as negative, trace, 1+, 2+, 3+, 4+
The results correspond to the following concentrations
(mg/dl): trace = 250mg/dl;1+ = 500mg/dl; 2+ = 750mg/dl:
3+ = 1000mg/dl: 4+ = 2000mg/dl.
Watch the solution carefully while it is boiling.
If it passes through orange to dark shade of greenish brown, the
sugar concentration is more than 2000mg/dl and the results
should be recorded as 4+ without reference to the color scale.
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Specific (enzymatic) test for glucose

These tests are based on the use of glucose oxidase
The glucose oxidase in the presence of atmospheric oxygen
oxidize glucose to gluconic acid and hydrogen peroxide.
The principle of all enzymatic test is the same
They differ only on the uses of different type of chromogen (a
color indicative).
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Cont…
Specific test for urinary glucose that will be discussed here are:
✓Clinistix reagent strip
✓Test tape
✓Diastistix
Which are available in the reagent strip
– Separately or in combination with other urine test
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Principle Clinstix
It is a double sequential enzyme reactions:-
Glucose oxidase will oxidize glucose to gluconic acid and
at the same time reduce atmospheric oxygen to hydrogen
peroxide.
The hydrogen peroxide formed will, in the presence of the
enzyme peroxidase, oxidize the reduced form a dye to the
oxidized form, which is indicated by the color change of
an oxidation - reduction indicator.
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Clinistix Reagent Strip Test
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Chemical Exam
When the test strip is dipped in
urine the reagents are activated
and a chemical reaction occurs.
The chemical reaction results in a
specific color change.
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Positive Glucose

(Normal for comparison)
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Procedure

Follow the directions supplied with the strips.
1. Rapidly dip the test end of the strip in the urine.
2. Read the results after exactly 10 seconds
3. Record the results as positive or negative.
If the test area remains green, the result is negative.
A positive result is indicated by the appearance of a purple
color in the test area.
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Test-Tape for Glucose
Principle
Test-Tape is a screening test
Specific for glucose
The principle is the same to clinistix
Differ in the oxidation - reduction indicator employed, and the
material the reagents are impregnated on.
In Test-Tape the reagents are impregnated on a tear strip of
special paper, and the indicator is yellow in its reduced form
and green to blue in its oxidized form.
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Procedure
Follow the manufacture direction:
1. Tear off approximately 1 and 1/2 inch.
2. Dip part of the tape into the urine specimen; remove it
immediately.
3. Wait for 30 seconds; then observe the appearance of any
green color.
4. Record the result as positive or negative.
– If the test area remains yellow after 30 seconds, the result is
negative.
– If any green color is present at this time, the result is
positive.
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Diastix Reagent Strip for Glucose

Diastix is a specific test for glucose based on the use of glucose
oxidase.
The chemical reaction is the same as clinistix
The difference being the chromogen system used to indicate the
presence of glucose.
The reagent area contains glucose oxidase, peroxidase, a blue
background dye, and potassium iodide as the chromogen.
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Procedure
❖ Follow the directions supplied with the reagent strip.
1. Dip the reagent area of the strip briefly into the specimen.
2. Compare the test area with the color chart after 10 seconds to
see whether the reaction is positive or negative for glucose.
3. Compare the test area with the color chart at 30 seconds, for a
semi-quantitative result, and report the results as indicated on
the chart.
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Rubner’s Test
To 10 ml of undiluted urine add 3 gms (excess) lead acetate,
Shake well, Filter
Boil the filtrate and add 1 ml concentrated ammonium
hydroxide and boil.
The precipitate formed is the criterion of the test.
Lactose: Red solution + Red precipitate
Glucose: Red solution + Yellow precipitate
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Fructose

Fructose may be found in the urine mostly after fruits,
honey, syrup and jams food.
It may be found in liver disease and along with glucose, in
the urine of diabetics.
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Seliwanoff’s Test for Fructose

Hydrochloric acid acts on fructose to form a derivative of
furfuraldehyde, which gives a red-colored compound when
linked with resorcinol.

Procedure
1.Add a few drops of urine (about 0.5 ml) to about 5 ml of the
reagent in a test tube
2. Boil.

Interpretation: Fructose gives a red color within half a minute
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Clinical Significance
Normally, urine doesn't contain a sufficient amount of sugar
to react with any of the popular enzyme or reducing tests.
When sugar appears in the urine, it shows the abnormality
caused by disease diabetes mellitus.
Test for urine sugar is used in screening to detect diabetic
mellitus, confirming diagnosis of diabetes mellitus, and
monitoring the effectiveness of diabetic therapy.
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Ketones
Ketones are also called Ketone bodies.
are a group of three related substances:-
1. Acetone
2. Acetoacetate (acetoacetic acid) and
3. -hydroxybutyrate (-hydroxybutyric acid).
Formed in liver from acetoacetate (oxidation product of amino
acid, fatty acid)
Used as energy source for extrahepatic tissue like brain and
muscle cells.
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Ketone bodies an alternative fuel for cells
Ketone bodies are normal products of fat metabolism.
Normally they are not detectable in the blood or urine of health
individuals.
In normal metabolism, fat is broken down in the tissues to glycerol
and fatty acids.
The free fatty acids are transported by the plasma albumin to the liver
where they are broken down to acetyl coenzyme A (acetyl Co-A)
molecules.
Liver mitochondria have the capacity to divert any excess acetyl CoA
derived from fatty acid or pyruvate oxidation into ketone bodies.
The compounds categorized as ketone bodies are acetoacetate, 3-
hydroxybutyrate and acetone (a volatile non-metabolizable side
product).
They are transported in the blood to peripheral tissues, where they
can be reconverted to acetyl CoA and oxidized by the TCA cycle.
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Cont…
The liver actively produces ketone bodies, but it cannot itself use
them as fuels.
Ketone bodies are used in extrahepatic tissues such as the skeletal
and cardiac muscle and the renal cortex, in proportion to their
concentration in blood.
Even the brain can utilize ketone bodies for fuel if the level rises
sufficiently, this is important during prolonged periods of fasting.
Extrahepatic tissues efficiently oxidize acetoacetate and 3-
hydroxybutyrate.
The liver lacks succinyl CoA: acetoacetate CoA transferase, and
therefore is unable to use acetoacetate as a fuel.!!
Red blood cells cannot efficiently oxidize acetoacetate and 3-
hydroxybutyrate because they lack mitochondria.
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Tests for ketone bodies in Urine:-

Rothera’s test
Lang’s test
Acetest tablet test
Acetone powder test
Reagent strip tests (eg. ketostix)
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Rothera’s test

Principle
Both acetone and acetoacetic acid give a purple color with
alkaline sodium nitroprusside.
This is the general principle for the tests mentioned above.
Results:- Report the test as positive or negative
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Procedure
1. To 5 ml of fresh urine, add ammonium sulphate crystals until
saturated (about 1 g.).
2. Add 2 drops of sodium nitroprusside reagent and mix
3. Overlay with ammonium hydroxide solution (28%).
4. If acetone or acetoacetate is present, a red to purple color will
develop at the line of contact.
✓ The color may not appear for 10-15 minutes.
5. Report the test as positive or negative.

Note: Urine collected after a big meal may give a purplish color
within 30 seconds but it fades within 3-4 minutes. This is not a
positive test.
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Ketostix Reagent Strip Test
Principle:- is based on Rothera’s test,
Acetoacetic acid will react with sodium nitroprusside in a
alkaline medium to form a purple color.
If glycine is added, the test is slightly sensitive to acetone.
N.B Multistix and ketostix have been formulated to react
only with acetoacetic acid. They don’t react with acetone.
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Ketostix Reagent Strip Test

Procedure
Dip test-end of the strip in urine
At 15 seconds compare the color of dipped-end with the
color chart.
Report as indicated by the color chart.
Content of Reagent Strip
Sodium Nitroprusside, Glycine, and a strongly Alkaline
buffer.
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Positive urine Ketones

(Normal for comparison)
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Gerhardt’s Test for acetoacetate
It is specific for acetoacetate;
However, it is capable of detecting only large amounts of
acetoacetate.
The test has been used as a means of determining the severity of
ketosis.
A positive result indicates severe ketosis, and treatment must be
started immediately.
Principle of the Test
When acetoacetate reacts with a ferric chloride (FeC13) solution,
Bordeaux red color is formed.
Reagent = 10% Ferric chloride reagent
Weigh 10 g of ferric chloride and transfer to a 100 ml volumetric
flask.
Dissolve and dilute to 100 ml volume with water and mix.
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Clinical Significance
When the rate of formation of ketone bodies is greater than the
rate of their use, their levels begin to rise in the blood, which is
called ketonemia, and eventually in the urine, which is known
as ketonuria.

Both ketonemia and ketonuria are seen most often in cases of:-
Starvation and diabetes mellitus
Also in the urine during prolonged vomiting, severe
diarrhea, anesthesia, high fat intake and low carbohydrate
diet.
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Clinical Significance…
The excessive production and accumulation of ketone bodies
may lead to ketosis.
Its physiological effect is serious because acetoacetic acid and
-hydroxybutyric acid contribute excess hydrogen ions to the
blood,
✓resulting in acidosis:- a condition that tends to lower the
blood pH.
✓If not corrected in time this may result in death.
Another physiological effect found to be toxic to brain tissue
when present in increased amounts in the blood. So this
condition can result in permanent brain damage.
For diagnosis of the severity of diabetes.
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Determination of Urinary Protein

Introduction
❖ Test for urinary protein is one of the most important and
valuable parts of the routine urinalysis.
✓ Albumin is one of the important proteins, which appears in
urine during a pathological condition.
✓ It often occurs as a symptom of renal disease.
✓ Globulins are excreted less frequently.
✓ Bence Jones protein is a specific type of globulin excreted in
multiple myeloma.
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Causes of Proteinuria
1. Increased permeability of the glomerulus:-
Normally, the glomerular membrane in the formation of
urine, is not permeable for protein molecules.
If the glomerular membrane is damaged these large
protein molecules can pass through it.
2. A decrease in normal reabsorption in the tubules:-
disease condition which affect reabsorption.
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Types of proteinurea

Classified according to the relationship of its etiology to the
kidney and also the mechanism involved:-
A. Functional Proteinuria
B. Systemic disease or renal pathology Proteinuria
A. Functional Proteinuria: not associated with renal damage.
1. Accidental or false proteinurea:-
Occurs when mixing of urine with a proteinous fluid
such as pus, blood or vaginal discharge.
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Functional Proteinuria cont’d…

2. Physiological proteinurea:-
It is usually less than 0.5 gm/24 hrs. which is associated
with fever, exposure to heat or cold, emotional stress, and
later stage of pregnancy.
3. Postural (orthostatic) proteinurea:-
✓ Associated only with the upright position or sitting for a
long time.
✓ The proteinurea is intermittent and disappears when the
individual lies down.
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B. Systemic disease or renal pathology Proteinurea

1. Pre-renal proteinuria:- not due to primary renal disease
Fever and a variety of toxic condition
Venous congestion
Renal hypoxia
Hypertension
Myxedema(hypothyroidism)
Bence Jones protein
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Cont…
2. Renal proteinuria:- primarily kidney disease
Gomerulonephritis
Nephrotic syndrome, primary and secondary
Destructive parenchymal lesions (tumour, infection)
3. Post renal proteinuria:-
protein added to the urine at some point farther down the
urinary tract from the renal parenchyma.
Infection of the renal pelvis or ureter
Cystitis
Urethritis or prostatitis
Contamination with vaginal secretion
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Test for urinary protein

1. Precipitation or turbidimetric test
Principle: Protein is either precipitated out of the urine
specimen by means of a chemical, or it is coagulated out of
solution with heat.
These tests include:-
a) Robert’s Test ring tests
b) Heller’s Test

c) Sulphosalicylic Acid Test non-ring tests
d) Heat and Acetic Acid Test
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Robert's Test

Principle:-
The principle of this test is based on the precipitation of
protein and formation of white compact ring using
concentrated Nitric acid (HNO3).
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Procedure of Robert's Test

Place 3-5 ml urine in a test tube.
Place the Robert's Reagent to the bottom of the tube and allow
3 ml of the reagent to lay beneath the urine.
A white ring at the zone of contact indicates a positive test.
The ring must be read within 3 minutes
Report the result according to the type of the ring formed
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Heller's Test
Principle:- The same as Robert`s Test

Heller's Reagent: It is concentrated nitric acid.

Procedure the same as roberts test
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Sulphosalicylic Acid Test

Principle
Sulphosalicylic acid solution (20%) precipitates any protein in
the urine specimen.
It is an anion precipitant that works by the neutralization of the
protein cation.
This method is more sensitive and reliable than the heat
method.
It can detect 5 to 10 mg/dl of protein in urine specimen
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Procedure of Sulphosalicylic Acid Test

Take 2 ml of a centrifuge (clear) urine specimen in a test
tube.
Add equal amount of Sulphosalicylic acid reagent.
Shake the test tube gently and let stand for 10 minutes
Note the degree of turbidity by looking at the illuminated
tube against a dark background
Grade and report the result as non ring test

Interpretation:- report the result based on the turbidity formed
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Heat and Acetic Acid Test

Principle:
The test is based on the precipitation of protein by heat.
Procedure
Fill a test tube three-fourth full of clear urine, and gently
heat the upper portion of urine for 2 minutes to boil,
being careful not to shake the tube more than necessary.
The lower portion of urine is not heated so that it can be
used as a control for comparing.
If turbidity (a white cloud) can arise due either of
phosphates, carbonates, or protein.
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Procedure Cont’d…

Add 3 drops of 10% acetic acid drop by drop, boiling
between each drop.
A white cloud that disappeared is due to phosphates or
carbonates. Persistence or development of turbidity
implies proteinuria.
Read the test and record results according to the chart for
non-ring precipition test.
Sensitivity
This method is the most sensitive for small amount of protein
and can reliably detect protein concentrations of 2 to 3 mg/dl
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Colorimetric Reagent Strip (Dipstick)

Principle
The Colorimetric reagent strip test is based on the ability
of protein to alter the color of some acid-base indicators
without altering the pH.
When an indicator, such as tetrabromophenol blue is
buffered at pH 3, it is yellow in solutions without protein.
Tests are more specific.
They require only a drop of urine enough to moisten the
reagent area.
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Procedure of Reagent Strip

Observe the precautions and follow the instructions supplied
by the manufacturer.
1. Dip the reagent area of the strip briefly into the specimen.
2. Remove excess urine by tapping or drawing the edge of the
strip along the rim of the urine container.
3. Compare the color that develops with the color chart
supplied by the manufacturer and report as indicated on
the chart.
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Chemical Exam

When the test strip is dipped
in urine the reagents are
activated and a chemical
reaction occurs.
The chemical reaction results
in a specific color change.
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Quantitative 24 hour protein Determinations

✓ Estimates the protein content of urine.
✓ Performed by quantitating the amount of precipitation formed
following the addition of a specific chemical to the urine.
✓ The precipitate is measured either by comparison with known
standards (sulphosalicylic acid turbidity test) or
✓ By recording the height of the column of precipitate in a
specially-designed tube (Esbach's test).
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Quantitative 24 hour protein Determinations

A. Sulphosalicylic Acid Turbidity Test
1. Pipette 2.5 ml of urine into a test tube.
2. Add 7.5 ml of 3% sulphosalicylic acid.
3. Invert to mix
4. Let stand 30 minutes.
Compare the turbidity with known standards prepared
from solutions containing 10, 20, 30, 40, 75 and 100mg
albumin/dl, and estimate the concentration of the unknown
(urine protein).
If the unknown urine contains more than 100mg/dl
protein, dilute the urine and repeat the test.
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Quantitative 24 hour protein Determinations

B. Esbach’s Test
1. measure the total volume; then filter some of the urine.
2. Do qualitative protein test, Robert’s or strip test.
if the urine is +3, made 1:5 dilution.
if the urine is +4 make 1:10 dilution.
if the urine is trace, +1 or +2 non dilution is needed.
if the urine is negative, a quantitative test is not done.
N.B: measure the pH of the urine. It should be acidic. If not,
add 10 % acetic acid
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Esbach’s Test Cont’d…

4. Add pumice powder to the 0.5 mark of the Esbach’s tube.
5. Add urine to the “U” mark.
6. Add Esbach’s reagent to the “R” mark.
7. Mix slowly by inversion, 10 times.
8. Wait for 30 minutes. Read the highest of the column. Do
not subtract the amount of the pumice.
9. The result is now in gram per liter of protein in the urine. If
the urine has been diluted, multiply by the dilution factor,
calculate, and record the g % and the g / 24 hrs.
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Clinical Significance

Proteinuria: >6-8gm/l.
renal damage cause proteinuria.
A positive protein test for urine may be correlated with
findings of casts.
In cases of renal disease, it is essential that the diagnosis
be made and treatment started as soon as possible to
prevent extensive and permanent renal damage.
Proteinuria with the presence of leukocytes and bacteria in the
urine will be suggestive of urinary tract infection.
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Bence - Jones Protein

It is an abnormal low molecular weight globulin consisting of
light chains of immunoglobulin, which contains the amino
acid found in other proteins except methionine.
It may be found in the urine of patients with multiple
myeloma, which is a malignant disease of the plasma cells,
mainly affecting bone.
The incidence of Bence-Jones proteinuria in multiple
myeloma has been estimated as 50% to 80%.
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Heat test to screen Bence -Jones Protein

Principle:
Bence Jones protein coagulates when heated to 40 to 600C and
re-dissolves partially or wholly on boiling.
Albumin coagulates above 600C and does not re-dissolve on
boiling.
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Heat test to screen Bence -Jones Protein

Procedure
1. Take 5ml of clear fresh urine into each of three test tubes.
2. Acidify the urine by adding 1 drop of glacial acetic acid to
the first tube, 2 drops to the second tube, and 3 drops to the
third tube.
3. Place the three tubes in a beaker of tap water and insert a 0-
100 OC thermometer in one of the tube.
4. Using a gentle flame slowly heat the beaker of water.
5. When the temperature reaches 40OC look for cloudiness and
precipitate in the tubes. Continue to observe until the
temperature reaches 60OC.
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Clinical significance

Suggests the diagnosis of multiple myeloma, leukemia or
waldenstorms macroglobulinemia.
Interfering factor:
False positive result may occur in connective tissue
disease, renal insufficiency, contamination of the specimen
with menstrual blood and prostatic secretion or semen.
coagulable protein denatures or decompose at room
temperature.
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