Lecture Notes in Medical Technology: Lecture #6: Liver Function Test

LIVER FUNCTION TEST

The liver is a large and complex organ found in the upper quadrant of the body. It is beneath and attached to the diaphragm and protected by the lower rib cage. The liver accounts for approximately 2.5% of an adults body weight. Weighing between 1200–1600 g, it is unequally divided into lobes by the falciform ligament, the right lobe being about six times larger than the left lobe. The lobes have no functional significance, and there is free communication between all portions of the liver.

The liver is a very vascular organ with approximately 1500 ml of blood per minute passing through it. The liver is unusual in that it receives a dual blood supply. Blood rich in nutrients and other absorbed substances from the gastrointestinal tract is carried to the liver by the portal vein. Even though the portal vein contributes 80% of the total blood volume of the liver; it supplies only 40% of the oxygen. The hepatic artery, branching from the abdominal aorta, is the primary supplier of oxygenated blood to the liver. To complete the hepatic circulation, blood is drained form the liver by a collecting system of veins that empties into the hepatic veins and ultimately into the inferior vena cava.

The liver cells or the hepatocytes

The liver lobule is the basic microscopic unit of the liver and is responsible for all metabolic and excretory functions of the liver. Each lobule is roughly hexagonal in shape with four to six peripherally located portal triads, numerous columns of hepatic parenchymal cells, a continuous system of blood carrying sinusoids.

1. Kuppfer cells – a special endothelial cell which are phagocytic and are part of the reticuloendothelial system of the body.

Endothelial cells – are flattened cells that line the sinusoids and function as filters to prevent the passage of large molecules into the parenchymal cells.

2. Parenchymal cells – performs the metabolic, detoxification, excretory and synthetic functions associated with the liver and are responsible for the regenerative properties of the liver. It accounts for 60–80% of liver volume and has an average life span of 150 days in experimental animals.

Components of parenchymal cells and its functions:

a. Golgi apparatus

(1) Assembles and transports lipoproteins and

glycoproteins.

(2) Secretes albumin and bilirubin.

b. Lysosomes

(1) Contain hydrolytic enzymes

(2) Metabolism of metals

c. Microbodies

(1) Respiration

(2) Liquid and purine metabolism

(3) Gluconeogenesis

(4) Detoxification of alcohol

d. Mitochondria

(1) Energy source

(2) Oxidative phosphorylation

(3) Oxidation of fatty acids

e. Endoplasmic reticulum

(1) Synthesis of albumin, coagulation factors,

cholesterols and bile acids

(2) Metabolism of drugs and steroids

(3) Conjugation of bilirubin

(4) Deposition of glycogen

(5) Glycosylation of proteins

(6) Metabolism of fatty acids, phospholipids and

triglycerides

(7) Calcium homeostasis

Functions of the liver:

1. Metabolic function:

a. Carbohydrates

b. Lipids

c. Amino acid and proteins

d. Bilirubin

e. Hormones

f. Cholesterol

2. Excretory function:

a. Bile acids

b. Cholesterol

c. Bilirubin

3. Hematologic function:

a. Production of coagulation factors

b. Production of red blood cells in the fetus

4. Detoxifying function:

a. Bilirubin

b. Ammonia

c. Alcohol

d. Drugs

5. Storage function:

a. Glycogen

b. Lipids

c. Amino acids and proteins

d. Iron

e. Copper

f. Vitamins

6. Immunologic function:

a. Phagocytosis to clear bacteria and other foreign substances

b. Secretion of IgA

c. Humoral defenses

Liver secretions:

1. Bile – is a greenish–yellow liquid secreted by the liver which contains water, bile salts, bile pigments and cholesterol averaging 600 cc a day. The bile is transported to the common bile duct and then to the gall bladder where it is concentrated and emptied into the small intestines. It is essential for digestion of fats.

2. Bile pigments – manufactures from the products formed by the breaking down of hemoglobin.

3. Bile salts – most useful constituent of bile not excreted from the body but are reabsorbed almost completely and recirculate back to the liver through an enterohepatic pathway. Bile salts normally function in the emulsification of dietary fats, the activation of the lipases and in the absorption of lipid through the intestinal mucosa.

4. Bile acids – are catabolic products of cholesterol formed in the liver. These are either conjugated with glycine or the sulfur containing compound, taurine to form bile salts.

METABOLIC FUNCTION OF THE LIVER

It is presumed that patients with hepatic diseases may have hypoglycemia, decreased carbohydrate tolerance and decreased hepatic glycogen stores.

I. Carbohydrate metabolism

A. Galactose Tolerance Test

This is based on the ability of the normal liver to convert galactose to glycogen. The galactose that is carried to the liver cells from the intestinal tract is normally converted into glucose, which is then further converted to glycogen. If galactose is subjected into the blood, the speed of removal of this sugar is related to the integrity of the liver and the normal functioning of its cells. In liver diseases, little or not conversion of galactose to glycogen takes place.

Preparation of the patient for:

a. Oral Galactose Tolerance Test

The patient is given 40 g of galactose in about 200 ml of water, which may be flavored with lemon juice. Blood samples are drawn at 30 and 60 minutes after giving the galactose. All urine specimens voided within the 5–hour period after ingestion are collected and combined.

Normal values:

40–60 mg/100 ml in 30–60 minutes

b. Intravenous Galactose Tolerance Test

One ml of the 50% galactose solution per kilogram body weight (0.5 g/kg if less concentrated solutions are used) is injected by a physician under proper clinical condition. A blood sample is drawn 60 minutes after the completion of the test.

Procedure for galactose determination:

A method for determination of galactose in blood or urine ordinarily involves removal of glucose by fermentation with yeast or by treatment with glucose oxidase.

The concentration of the remaining sugar is determined by the galactose oxidase method and is expressed as galactose.

Normal values:

Should not exceed 42mg/100 ml after 60 minutes

II. Protein metabolism

Deamination and transamination of amino acids, urea formation and synthesis of prothrombin and many of the plasma proteins is dependent on normal liver function. In protein metabolism, an extensive impairment or destruction of liver cells is required before abnormal function can be clearly demonstrated.

Test for protein metabolism:

A. Total protein, A/G ratio (see discussion on Lecture #10: Proteins)

B. Flocculation and Turbidity Tests

C. Electrophoresis

Flocculation and Turbidity Tests:

Generally, the response to these test depend on the state of balance between the stabilizing and precipitating factors in the serum. The precipitating factors include gamma globulins and lipoproteins such as betaglobulins. The stabilizing factors are albumin and alpha–1–globulin. In normal serum, the distribution of the protein components is such that the stabilizing factors prevent turbidity or flocculation when any flocculation or turbidity tests are carried out.

a. Cephalin Cholesterol Flocculation Test (CCFT) – Hanger’s method

Serum from patients with liver cells impairment will react with the cephalin–cholesterol suspension to produce a flocculant precipitate, which is probably an alpha or beta–globulin–cholesterol complex.

Normal blood serum does not produce flocculation due to the inhibitory action of the albumin or globulin. A blood serum will flocculate a colloidal suspension of cephalin–cholesterol due to increased gamma–globulin and decreased albumin.

Reagents:

1. NSS

2. Ether, anesthetic grade

3. Cephalin–cholesterol stock solution (prepared from the brain of the sheep)

To the cephalin–cholesterol mixture, add 5 ml of ether. Allow the solution to stand for several hours to obtain complete solution of the material and keep tightly stored in a refrigerator.

4. Cephalin–cholesterol suspension (working standard)

Heat 35 ml of freshly prepared distilled water to 65–70^oC, add slowly with constant stirring 1 ml of the clear stock solution. Heat gently and allow to simmer until the volume is reduced to 30 ml. A stable milky solution should result and it should be cooled to room temperature before use. When stored in a refrigerator, the emulsion is stable for two weeks.

Procedure:

Serum NSS Emulsion

Unknown 0.2 ml 4 ml 1 ml

Reagent control 4 ml 1ml

Positive or negative 0.2 ml 4 ml 1 ml

control

Mix gently by inversion and let stand in the dark at room temperature for 24–48 hours.

To shorten the time required for the test, some laboratories read the tubes after 4 hour incubation at 37^oC.

Examine the tubes and judge the reaction as follows:

Negative – no flocculation or precipitation

1+ reaction – slight flocculation or precipitation

2+ reactions – definite flocculation or precipitation

3+ reaction – almost complete precipitation with a somewhat cloudy supernatant fluid

4+ reactions – complete precipitation with a clear supernatant fluid

Normal values:

Serum from normal individuals give negative or 1+ reaction

Clinical Significance:

CCFT responds readily to serum specimens containing increased gamma–globulin and decreased albumin. This condition is common in a high percentage of cases of viral hepatitis, cirrhosis and hepatic necrosis and occurs less frequently in post–hepatic obstruction. The test is very sensitive to qualitative changes in serum albumin, which may explain its rapid response to acute hepatitis.

The important application of this test is the differentiation of parenchymal liver disease from early obstructive or hemolytic jaundice because CCFT is elevated in liver disease, usually unaffected in the two latter cases.

Notes:

1. Only milky smooth emulsions should be used in the test.

2. Use carefully cleaned glassware rinsed with distilled water.

3. Use fresh serum and protect the reaction from heat and light.

4. Use fresh distilled water to prepare reagents.

b. Zinc Sulfate Turbidity Test

Serum from patients with high gamma–globulin (liver disease) will produce varying degree of turbidity when mixed with a dilute solution of zinc sulfate in a barbiturate buffer of pH 7.5.

Procedure:

0.2 ml serum

6ml zinc sulfate reagent

Stopper, mix thoroughly and read the absorbance against a reagent blank

Use a standard curve or compute

ZnSO₄ turbidity units = A or O.D. x K

Normal values: 2–12 units

c. Thymol Turbidity Test

Serum from patients with liver disease will produce definite turbidity when mixed with a thymol solution in barbiturate buffer. The turbidity is caused by the precipitation of a globulin thymol–phospholipid complex. It is also observed in serum with increased betaglobulin and with lipemic sera.

Procedures:

1. Shank–Hoagland

0.1 ml serum

1.0 ml thymol buffer

Mix thoroughly and let stand for 30 minutes at 25–28^oC

Mix again and read absorbance against a reagent blank.

Use a standard curve or compute.

Thymol turbidity units = A or O.D. x K

Normal values: 0.5 Shank–Hoagland units

2. Maclogan

Serum is mixed with thymol buffer in the proportion of 1:10 and compared with standard solutions with concentrations in Maclogan units.

For comparison, 1 Maclogan unit = 2 Shank–Hoagland units

Clinical significance:

TTT is affected in increased gamma–globulin, lipids and beta–globulins and decreased albumin. The test does not respond as rapidly to viral hepatitis as CCFT but the increase in thymol turbidity persists at times longer than an abnormal CCFT.

Increased in: infectious hepatitis, nephrosis, cirrhosis and diabetes

Decreased in: obstructive jaundice without liver involvement

Notes:

1. Thymol reagent should be clear and colorless and must be adequately mixed with serum during the test.

2. pH should be 7.55 as this is more sensitive than pH 7.8.

3. Reaction should be in a water bath at 25^oC or above. Turbidity decreases as temperatures rises.

4. Test should not be done on lipemic sera as it will give false positive elevations.

5. Blood should be withdrawn in the fasting state.

The advantages of TTT over the CCFT are:

1. TTT is the last to return to normal in liver disease.

2. The turbidity in TTT can be accurately measured with a photoelectric colorimeter whereas the CCFT is graded only.

Other flocculation tests:

1. Colloidal Gold Test

2. Takata–Ara test (HgCl₂ as precipitating agent)

3. Cadmium Sulfate Test

III. Bilirubin metabolism

A. The bilirubin of aged or damaged red blood cells is converted by a complex series of reactions to the bile pigments, bilirubin.

B. Bilirubin is then transported from the extrahepatic sources as a bilirubin–albumin complex into the liver (hepatic sinusoids).

C. In the liver, the protein is separated from the complex and bilirubin is converted into bilirubin digluoronide by the reaction with uridine diphosphate gluconate catalyzed by the enzyme system, UDP–gluconyl transferase.

D. The glucoronide, along with some free bilirubin, is excreted into the bile, passes into the small intestines and is exposed to the reducing action of the enzyme of anaerobic bacteria.

E. The reduction products: mesobilirubinogen, stercobilinogen and urobilinogen collectively known as urobilin, are first formed in the colon, then a portion of the urobilinogen is absorbed into the portal circulation and returned to the liver.

F. The normal liver removes all but a small amount of urobilinogen from the blood, probably oxidizes some of it to bilirubin and excretes both into the bile for a return trip to the colon.

G. The urobilinogen remaining in the colon are excreted in the stool after being oxidized to form urobilin (stercobilin), an orange brown colored pigment.

The reaction is summarized as follows:

Hemoglobin heme (iron porphyrin) + globin

heme oxygenase

biliverdin

biliverdin reductase

bilirubin (B1)

attaches to albumin

liver

UDP – glucuronyl transferase

(uridine diphosphate)

bilirubin diglucoronide (B2)

bile

intestine (bacterial flora)

urobilinogen oxidation stercobilinogen

reabsorbed by the stercobilin

enterohepatic circulation (stool)

(enterohepatic cycle)

urobilin (urine)

The Van den Bergh Reaction

Ehrlich described the coupling reaction of bilirubin with diazotized sulfanilic acid to form a blue pigment in strongly acid or alkaline solutions. Van den Bergh applied this color reaction to the quantitative determination of bilirubin and reported the effect of alcohol on the rate of coupling reaction. According to the reaction of bilirubin with Ehrlich’s reagent (diazotized sulfanilic acid).

Van den Bergh classified bilirubin present in the serum into:

1. Direct–reacting bilirubin or conjugated bilirubin or bilirubin diglucuronide or B2 – water soluble.

2. Indirect–reacting or unconjugated bilirubin or B1 – alcohol soluble.

Comparison of properties of Direct and Indirect bilirubin:

Direct bilirubin Indirect bilirubin

1. Structure bilirubin diglucuronide bilirubin (loosely attached

attached to albumin)

2. Solubility in:

a. water soluble insoluble

b. alcohol soluble soluble

3. Diffusibility into tissues good poor

4. Reaction to Van den Bergh direct indirect

5. Presence in urine present absent

6. Toxicity non–toxic toxic

Synonyms of Bilirubin 1: Synonyms of Bilirubin 2:

1. Unconjugated bilirubin 1. Conjugated bilirubin

2. Water insoluble/Non–polar bilirubin 2. Water soluble/Polar bilirubin

3. Indirect reacting bilirubin 3. Direct reacting bilirubin

4. Hemobilirubin 4. Cholebilirubin/Cholestatic bilirubin

5. Free bilirubin 5. Prompt bilirubin

6. Prehepatic bilirubin 6. Post–hepatic bilirubin

7. One–minute bilirubin

Methods of bilirubin determination:

General principles:

The chemical methods for quantitation estimation of

bilirubin in serum are based on diazotization of the

bilirubin and measurement of the azo dye.

1. Malloy and Evelyn (based on Van den Bergh reaction)

Bilirubin in serum is coupled with diazotized sulfanilic acid to form a pink or purple compound, azobilirubin, the intensity of color which is proportional to the bilirubin concentration in the serum.

Direct bilirubin reacts with diazo reagent in aqueous solution to form a color within one minute, after which the mixture is read against a reagent blank. The subsequent addition of alcohol accelerates the reaction of all forms of bilirubin in the serum and a value for total bilirubin is obtained after allowing the specimen to stand for 15–30 minutes. This represents the total bilirubin which is the sum of the bilirubin diglucoronide (direct) and the unconjugated bilirubin. Indirect–reacting bilirubin is determined by difference.

Composition of Ehrlich’s diazo reagent:

a. Diazo A – 0.1% sulfanilic acid

b. Diazo B – 0.5% sodium nitrite (NaNO₂)

c. Diazo blank – 1.5% hydrochloric acid (HCl)

Modification of Evelyn Malloy method:

a. Thamhauser–Andersen modification

The direct reaction is made on the serum and the indirect on the alcoholic extract separated from serum after it has been precipitated by ethyl alcohol and ammonium sulfate.

b. Anino, Watson and Ducci

2. Jendrassik and Grof

The diazotization is accelerated by caffeine and sodium benzoate at a strongly alkaline pH for the determination of total bilirubin. Alkaline copper tartrate is added producing a green color instead of a blue color which should be the color of diazotized bilirubin in alkali; but due to the yellow color of the reaction of the diazo reagent and caffeine mixture, a green color develops. Direct bilirubin is determined 2 minutes after the addition of diazo reagent. The diazotization is terminated by the addition of ascorbic acid.

Modification of Jendrassik and Grof method:

a. Stoner and Wiseberg method

Principle:

Proteins in serum are eliminated with saturated

ammonium sulfate (NH₄)₂SO₄ and then

bilirubin is reacted with diazotized sulfanilic

acid forming a blue azobilirubin using

alcoholic HCl as coupling promoter.

Reagents and results:

1. Saturated Ammonium Sulfate – protein

precipitant

2. Alcoholic HCl – coupling promoter

3. Ehrlich’s diazo reagent – color reagent

4. Blue azobilirubin at acid pH – end product

and color

b. Alkaline Methanolysis Method

The most accurate method for measuring bilirubin which involves the formation methyl esters and determination of the products by High Performance Liquid Chromatography (HPLC). This method is used in researches only.

Advantages of this method over Evelyn Malloy:

a. Less sensitive to variation in pH, protein and hemoglobin concentrations in the patient’s sample.

b. Forms minimal turbidity during the reaction.

c. Sensitive enough to produce sufficient, reliable color even with very low concentrations of bilirubin.

Precautions in bilirubin determination:

a. Hemolysis decreases the reaction of bilirubin with diazo reagent, producing falsely low concentrations and lipemia causes error in the spectrophotometric measurements.

b. Bilirubin is both light and temperature sensitive. Allowing serum or plasma to be exposed to fluorescent or natural light reduces bilirubin values by 10% within 30 minutes.

c. Samples are stable for one week in a dark refrigerator and for three months in a freezer.

d. The patient must fast 8–14 hours to prevent lipemia.

3. Thin Film EKTACHEM analyzer compose of:

a. Spreading Layer/Reaction Layer – contains Triton x–100 surfactant, diazonium salt and dyphylline as accelerator. This layer separates the unconjugated bilirubin from albumin and contains all of the necessary components for the quantitation of bilirubin.

b. Control Layer – buffered mordant layer that stabilizes the azo derivatives produced in the reaction layer and increases the sensitivity of the assay.

c. Non–reactive transparent support

When the bilirubin in the sample come into contact with the reagent on the slide, a spectral change occurs. The reflectance densities of the azo derivatives of all bilirubin fractions are then measured at 540 nm reflects bilirubin concentrations and measurement at 460 nm is used to correct for spectral interferences. To differentiate conjugated from unconjugated bilirubin, another type of dry chemistry slide is used with four layers:

a. Spreading layer – allows uniform dispersal of sample but also contains caffeine, surfactants and sodium benzoate to disassociate the unconjugated bilirubin from albumin.

b. First masking layer – where bilirubin removed from albumin migrate.

c. Second masking layer – uses selective filtration to trap many large molecules. This layer removes hemoglobin, albumin bound delta bilirubin, lipids and lipochromes.

d. Registration layer – where the conjugated and unconjugated bilirubin bind to mordant. Two separate reflection density measurements are made, one at 400 nm for unconjugated bilirubin and another at 460 nm for conjugated bilirubin.

Normal values:

Direct–reacting = 0 – 0.2 mg%

Indirect–reacting = 0.2 – 0.8 mg%

Total bilirubin = 0.2 – 1.0 mg%

Interpretation:

Direct Indirect

Obstructive increased –

Hemolytic – increased

Hepatic increased –

The Icterus Index

This is a measure of the degree of ictresia or yellowishness of serum or plasma in cases of jaundice. The degree of yellowishness is due to hemobilirubin and cholebilirubin.

Principle:

Serum or plasma is diluted with NSS or sodium

citrate solution until the color of the specimen

matches with that of a reference standard. The

standard used is a 1: 10,000 dilution or 0.01%

potassium dichromate.

Methods:

1. Muellengracht – 0.85% - 0.90% saline as diluent

2. Newberger – sodium citrate as diluent

a. Precautions:

(1) Specimen with visible lipemia or hemolysis are unsatisfactory hence, fasting is necessary.

(2) Lipochrome pigments such as carotene are detected with this method, therefore, foods such as carrots should be avoided the day before the test.

b. Normal values: 6 – 8 Icterus units

IV. Lipid metabolism

The lipid plays a major role in lipid metabolism. It is the organ that is involved in the complex transportation of lipid material between the blood and the bile. It is an important site of synthesis of fatty acids, ketone bodies and cholesterol esters, phosphatides and lipoproteins.

The typical profile seen is an increased level of triglycerides and fatty acids, decreased levels of cholesterol esters and the accompanying alterations in lipoprotein concentrations. Many of these abnormalities can be attributed to the deficiency of two enzymes of liver origin: lecithin–cholesterol acyltransferase (LCAT) and hepatic triglyceride lipase.

The appearance of lipoprotein X as an indicator of cholestasis provides a specific evaluation of liver dysfunction. Lipoprotein X contains free cholesterol and phospholipids and has albumin as its primary apoproteins.

(Methods of lipid quantitation is discussed on Lecture #5)

EXCRETORY FUNCTION OF THE LIVER

Exogenous dye tests have traditionally been used to test the liver’s detoxification and excretion ability. Dye tests evaluate first the liver’s ability to transport exogenous substances into the hepatocytes, then its ability to metabolize the substance, usually by conjugation to make it more soluble and finally its excretion into bile. These tests may provide a sensitive picture of the functioning of the liver as a whole.

A. Bromsulfonphthalein Dye Excretion Test

It is the most sensitive test for liver function. It is a valuable test in the detection of parenchymal liver dosage from any cause before the appearance of jaundice.

Principle:

A measured amount of dye is injected intravenously. Normally, this dye is removed from the blood by the parenchymal cells in the liver, excreting it in the bile. Only around 5% of the dye injected is retained in the blood and this is detected based on the fact that the dye is colorless in acid and reddish purple in alkaline solution.

The rate of removal of BSP and its excretion into the bile depends on several factors: the blood level of the dye, the hepatic blood flow, the condition of the liver cells and the potency of the bile ducts.

Procedure:

1. To avoid lipemia, the test is usually run in the morning on the patient in the fasting state.

2. Take the weight of the patient in pounds and compute for the amount of dye.

a. Rosenthal method

2 mg/kg body weight dose – 30 minutes = weight in lbs. = ml of 5% BSP solution

b. McDonald method

5 mg/kg body weight dose – 45 minutes = weight in lbs. = ml of 5% BSP solution

3. Inject into an arm vein the dye from 39 – 60 seconds and start timing as soon as the injection is completed.

4. Extract blood from the opposite arm vein at the end of the prescribed time.

5. Separate the serum. Icteric, lipemic or grossly hemolyzed serum should not be used. Treat the samples as follows:

Blank Unknown

Serum 0.5 ml 0.5 ml

Water 2.5 ml 2.5 ml

0.1 N HCl 3.0 ml –

0.1 N NaOH – 3.0 ml

· Sodium p–toluene sulfonate is added to the alkaline buffer to release the BSP dye bound to albumin, thus diminishing the effect of proteins on the color of the dye.

6. Read against blank at 575 nm; read the value on a curve.

Normal values:

Less than 5% of the dye should be obtained after

45 minutes (McDonald method)

No dye in 30 minutes (Rosenthal method)

Sources of error:

1. Care must be taken so that all of the dye enters the vein since it is quite irritating to the tissue: Allergic reactions and anaphylactic shock.

2. In post prandial cases, the removal of the dye is speed up due to increased hepatic blood flow and bile excretion.

3. BSP excretion is increased (less retained) in hypoalbuminemia due to the reduced albumin binding capacity of the dye.

4. In proteinuria, the dye is lost thru the urine since it is albumin bound.

B. Indocyanin Green (ICG) Dye Excretion Test

The ICG is similar to BSP test except that tricarbocyanine dye is not conjugated in the liver as is BSP. Almost all of the dye injected is recovered in the bile. Dependence on hepatic blood flow results in a decreased clearance rate in patients with conditions characterized by decrease myocardial output. The dosage of dye injected is 0.5 mg per kilogram of body weight and a normally functioning liver clears 28% (+/– 3%) of the dye per minute from the circulation.

Dichromatic Ear Densitometry

The Dichromatic Ear Densitometry is attached to the outer ear, while one photocell detects the concentration of the dye and a second photocell compensates for changes in hematocrit, oxygen saturation and blood volume. This provides a noninvasive but accurate evaluation of arterial levels of the ICG dye.

CONJUGATION AND DETOXIFICATION FUNCTION OF THE LIVER

The liver by means of conjugation is able to convert many toxic substances into non–toxic compounds, change active drugs into inactive conjugates, and alter the solubility of metabolites by esterification or conjugation to assist in normal excretion. Glycine, glucuronic acid and sulfates are often used as conjugating agents.

A. Hippuric Acid Test

Quick (1933) introduced the hippuric acid test as a test for liver function. Benzoic acid in the form of sodium benzoate is conjugated with glycine to form hippuric acid for excretion by the kidney.

Preparation of the patient:

1. Oral Test

a. Patient must be in the postabsorptive state

b. After emptying the bladder, give 6 g sodium benzoate dissolved in about 200 ml of water.

c. Urine is collected for a 4–hour period.

2. Intravenous test

a. A sterile solution containing 1.77 g of sodium benzoate in 20 ml water is slowly injected by a physician after the patient has emptied his bladder and drank a glass of water.

b. The urine is collected for one hour after the injection with complete emptying of the bladder by the patient.

Advantages of Intravenous test:

a. Avoidance of nausea or vomiting that may result from the oral route.

b. Decrease time required for the test.

c. Elimination of absorption factor from GIT.

Procedure:

Sodium benzoate is conjugated with glycine to form hippuric acid, which is excreted in the urine. Sodium chloride is added to decrease the solubility of hippuric acid and enhance its precipitation from acidified urine. Hippuric acid is then isolated, dissolved and titrated with a standard solution of alkali using phenolphthalein as an indicator.

Normal values:

Normal excretion of hippuric acid expressed as benzoic acid

Oral = 3.0 – 3.5 g/4 hours

I.V. = 0.6 – 0.9 g/2 hours

Clinical significance:

Normal liver cells are important for the proper rate of conjugation and excretion of a foreign substance when kidney function is normal. Decreased rates are observed in liver cell impairment. In conditions involving renal impairment, the results of the tests are inconclusive.

MISCELLANEOUS LIVER FUNCTION TESTS

1. Cholesterol

The liver is concerned with the metabolism of lipid especially cholesterol. Cholesterol is elevated in obstructive jaundice and this increase parallels the increase bilirubin. Changes in ratio of free to esterified cholesterol are seen in liver diseases. When there is liver damage like infections or in viral infections, there is fall of the cholesterol esters. Severe acute necrosis of the liver usually shows a decrease of the total cholesterol and the cholesterol esters.

2. Prothrombin time

This is reduced in liver diseases particularly when damage of the hepatic cells due to the reduced production of prothrombin. Decreased production of prothrombin may be bought about in two ways:

a. In obstructive jaundice, the absence of bile salts severely reduce the absorption of Vitamin K from the intestine.

b. Less production of prothrombin occur in liver diseases with injury to the hepatic cells even in the presence of adequate amount of vitamins.

These two conditions may be distinguished by the Vitamin K tolerance test.

3. Vitamin K Tolerance Test

a. Determine the prothrombin time on several different to find the range or level for the patient.

b. Then give intramuscularly 76 mg Synkavit for 4 consecutive days.

c. Determine the prothrombin time daily just before the injection and on the day following the last injection

d. In normal individual, there is normal prothrombin time and no change occurs following administration of Vitamin K.

e. In Vitamin K deficiency, the prothrombin time is elevated and is decreased or return to normal following administration of Vitamin K. In this condition, the liver function is not seriosuly impaired.

4. Fetoglobulins

Also known as alpha–fetoprotein which has been noted in the serum of about two third of patients with primary hepatocellular carcinoma. Fetoglobulin is present in fetal serum during the development of the fetus, but falls to a low level and disappear completely by the first week after life.

The protein is determined by agar or cellulose acetate electrophoresis while the test is specific for carcinoma of the liver, not all hepatocellular carcinoma give a positive test.

Fetoglobulin may also be present in the serum of some patients with testicular tumor.

ENZYMES RELATED TO LIVER FUNCTION

A. Hepatocellular enzymes – used for the evaluation of hepatic diseases reflecting active liver damage, both chronic and acute.

1. Alanine aminotransferase (ALT/SGOT)

2. Aspartate aminotransferase (AST/SGPT)

3. Gamma glutamyltransferase (GGT)

4. Alkaline phosphatase

5. Lactate dehydrogenase (LDH–5 and LDH–4)

6. Aldolase

B. Obstructive liver enzyme – used for the evaluation of hepatic diseases reflecting hepatocellular injury from cholestasis or biliary obstruction.

1. Alkaline phosphatase (ALP)

2. Gamma glutamyltransferase (GGT)

3. 5’–nucleotidase

4. Leucine aminopeptidase (LAP)

· Discussions of the above mentioned enzymes can be seen on Lecture # 11: Enzymology.

DISEASES ASSOCIATED WITH LIVER MALFUNCTION

I. Jaundice

Jaundice, also known as Icterus is the most common manifestation of liver diseases signifying hyperbilirubinemia, characterized by the yellowish discoloration of the skin, mucous membranes and sclera of the eyes. Conjugated bilirubin causes more jaundice than unconjugated bilirubin because of its easier absorption into tissues and higher water solubility. This form of bilirubin is easily bound to elastic tissue and other tissues that have a high protein content, making the yellow color particularly evident.

Classification of Jaundice:

A. Pre–hepatic jaundice is caused by:

1. Excessive destruction of circulating erythrocytes (hemolysis).

2. Ineffective erythropoeisis is a pathologic process in which a very low proportion of red cells formed in the bone marrow enters the circulation and those remaining in the bone marrow are prematurely destroyed. An increase in the amount of bilirubin released from the bone marrow results and is called early–labeled bilirubin since the bilirubin has not been circulating within RBC for 120 days.

3. Increased turnover of non–hemoglobin heme compounds in the liver and other organs.

4. Phagocytic breakdown of extravasated RBC (hematoma)

B. Hepatic jaundice

1. Retention jaundice – cause by a defect in the transport of unconjugated bilirubin into the hepatocyte.

2. Regurgitation jaundice – occur when hepatic cell is damaged or defective or the excretion of products from hepatocyte is impaired.

C. Post–hepatic jaundice or obstructive jaundice – is caused by a blockage of the flow of bile from the liver.

D. Neonatal jaundice

This is a condition defined as having total serum bilirubin levels above 15 mg/dl in few days after birth or bilirubin levels persisting above 10 mg/dl for more than two weeks.

The enzymes necessary for metabolism and conjugation are not present in sufficient concentrations at birth and do not function efficiently for a few days afterward. These two conditions, as well as an increased rate of absorption of unconjugated bilirubin from the infant’s intestinal tract, often cause bilirubin levels to rise to 10 mg/dl before the liver can begin to clear the excess bilirubin from the plasma.

Kernicterus is the deposition of unconjugated bilirubin in the CNS that may cause severe neurologic damage. Interventions may include the administration of phenobarbital to induce enzyme activity or phototherapy with monochromatic blue light to cause the oxidation of bilirubin to move soluble end products and enhance the renal excretion of bilirubin.

Expected laboratory results in Pre–hepatic, Hepatic and Post–hepatic jaundice conditions:

Liver Function Test Pre–hepatic Acute Hepatocellular Chronic Post–hepatic

Jaundice Jaundice Hepatocellular Jaundice

Total bilirubin N to I I I I Conjugated bilirubin N to I I I

Unconjugated bilirubin I I I I

Urine urobilinogen I I I D

Urine bilirubin N I I I

Albumin N N D N

Globulin N N I N

Aminotransferase N I I N

Alkaline phosphatase N N N I

Lactate dehydrogenase I I I N

BSP dye test N I I I

Prothrombin time N N Prolonged N

II. Congenital extrahepatic biliary atresia

Extrahepatic biliary atresia is an acquired defect causing a serious and aggressive condition in which the extrahepatic bile ducts become inflamed and increasingly non–functional. A total bilirubin level of 15 mg/dl is seen in this patients. Females are affected more often than males, and it occurs in approximately 1 in 10,000 live births. Increasing jaundice and hepatomegaly are seen within the first 2 to 3 weeks of life and affected infants have diarrhea and steatorrhea from the lack of bile acids to aid in digestion. The disorder results in an obstructive disease that leads to cirrhotic liver failure and death within two years if not treated successfully.

The clinical and laboratory picture is similar to that of any obstructive process. The key to prompt diagnosis and treatment is the differentiation of extrahepatic biliary atresia from prolonged neonatal jaundice, a true hepatic jaundice or other correctable obstructive diseases. The hyperbilirubinemia is primarily of the conjugated type in biliary atresia (more than 75%), whereas physiologic jaundice results in an unconjugated bilirubinemia. Serum enzymes and lipoprotein X are unreliable because these are all elevated in obstructive biliary disease. In patients with physiologic jaundice, the administration of phenobarbital induces liver enzyme activity and a rapid return to reference ranges for laboratory results is seen. This is not the case with biliary atresia. A liver biopsy is a helpful tool in prompt diagnosis and should not be delayed in those infants with a conjugated hyperbilirubinemia.

Surgery to alter the path of removal of bile from the liver is the only treatment available for those patients with minimal blockage of bile ducts. For most of those affected. Surgery is not indicated because it does not correct the inherent defect. Orthotopic liver transplantation is the only effective treatment for these patients. With recent advances in surgical techniques and immunosuppression therapies, liver transplantation is becoming the treatment of choice for this condition.

III. Hemolytic anemias

Hemolysis refers to premature erythrocyte destruction and includes both ineffective erythropoeisis and increased lysis. Liver function studies are helpful in the assessment of the severity of the hemolytic process but should not be used for an initial diagnosis. Specific laboratory testing to identify the source of the hemolysis is required. The liver is functioning properly in these situations and only when the liver’s ability to dispose of the excess bilirubin is exceeded will liver function studies be abnormal.

IV. Cirrhosis

Cirrhosis literally means a yellow–orange condition of the liver. The architecture of the liver is permanently destroyed and this condition is the end stage of several disease processes.

A. Wilson’s disease

B. Alpha–1–antitrypsin deficiency

C. Hemochromatosis

D. Primary Biliary cirrhosis

30 September 2012

Lecture #6: Liver Function Test

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