Albumin Information and Courses from MediaLab, Inc.
These are the MediaLab courses that cover Albumin and links to relevant pages within the course.
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| Products Used to Facilitate Antibody Identification Monospecific anti-human globulin (IgG) enables sensitized red cells to cross-link so that agglutination is visible.Enhancement media are sometimes used to further promote agglutination and reduce incubation time. Low ionic strength saline (LISS) is the most common enhancement media. LISS reduces the ionic strength in the testing sample and causes reduction of the zeta potential. It increases antibody uptake and decreases incubation time. Polyethylene Glycol (PEG): brings red blood cells (RBCs) closer together and concentrates antibodies by removing water molecules from the testing sample. It is the most sensitive of the enhancement media; strengthening almost all clinically significant antibodies. However, it will also enhance some clinically insignificant antibodies as well. Centrifugation should be avoided when PEG is used. PEG can cause aggregates to form if the sample (red cell - serum mixture) with PEG added is centrifuged. Reaction readings should only be done at the AHG phase. 22% Albumin: reduces zeta potential, bringing the RBCs closer together and enhancing agglutination. Albumin does not contribute much to antibody uptake. Longer incubation time is needed with this media than with the previously discussed media. Detection of some IgG antibodies can be enhanced with enzyme test methods. Proteolytic enzymes (papain and ficin) denature some RBC antigens and remove negative charges from the RBC membranes. This reduces the zeta potential, bringing the cells closer together. Enzyme techniques are particularly useful in the identification of Rh antibodies and antibodies in the Kidd, Lewis, P and I systems. However, enzymes destroy some antigens including Fya, Fyb, M, and N. The effect of proteolytic enzymes on the S and s antigens are variable. | View Page |
| The reagent strip method for protein primarily tests for which type of protein? | View Page |
| Protein Error of Indicators Testing for protein is based on the phenomenon called the "Protein Error of Indicators" (ability of protein to alter the color of some acid-base indicators without altering the pH). In a solution void of protein, tetrabromphenol blue, buffered at a pH of 3, is yellow. However, in the presence of protein (albumin), the color changes to green, then blue, depending upon the concentration. This method is more sensitive to albumin than to globulin, detecting as little as 5 mg albumin/dL urine. Bence Jones protein and mucoprotein are examples of globulin components that are sometimes present in urine, but are not distinguishable by the dipstick method for protein. | View Page |
| Follow-up Testing of Urine Dipstick Protein Results A 24-hour urine protein may be ordered if a large amount of protein is detected with the dipstick method or if protein persists in the urine. A 24-hour urine protein may also be ordered if the physician suspects the release into the urine of protein other than albumin. | View Page |
| Bilirubin Characterization Bilirubin, a product of hemoglobin breakdown, is characterized by its yellow pigment. The presence of bilirubin in urine is always abnormal. It is important to note that unconjugated bilirubin cannot be excreted by the kidneys because it is bound to albumin and is not soluble in water. In the liver, bilirubin combines with glucuronic acid through the action of a glucuronyl transferase to form water soluble bilirubin diglucuronide. Under normal circumstances, conjugated bilirubin passes from the bile duct and then to the intestinal tract. Intestinal bacteria reduce conjugated bilirubin to urobilinogen. Approximately half of the urobilinogen is excreted in the feces; most of the other half is recirculated through the liver. A small amount of urobilinogen bypasses the liver and is excreted in the urine. | View Page |
| Fresh frozen plasma should be used for which of the following: | View Page |
| In preparing red cells for any elution method , one must be particularly careful to: | View Page |
| Which of the following will give the best overall picture of a patient's iron stores: | View Page |
| Which of the following methods is not a quantitative method for the determination of
albumin: | View Page |
| Which of the following contributes most to serum osmolality: | View Page |
| Label this SPE scan. | View Page |
| Which band on the following serum protein electrophoresis scan is not made up of a mixture of proteins: | View Page |
| Bence-Jones proteinuria can be seen in all of the following conditions except: | View Page |
| Which of the following is most responsible for increasing the erythrocyte sedimentation rate (ESR): | View Page |
| Serum proteins can be separated by cellulose acetate electrophoresis into how many basic fractions: | View Page |
| Diseases Associated with Proteinuria Normal urine contains very little protein, usually less than 10mg/dL, and the major serum protein that is found in normal urine is albumin. The presence of an increased amount of protein in the urine (proteinuria) can be an indicator of renal disease. The two mechanisms which can lead to proteinuria are glomerular damage or a defect in the reabsorption process of the tubules in the nephron. The concentration of protein in the urine is not necessarily indicative of the severity of renal disease. | View Page |
| Microalbumin Test The presence of low levels of albumin (microalbumin) in the urine is an important finding in an individual with either type 1 or type 2 diabetes. The development of clinical nephropathy leads to reduced glomerular filtration and eventually may lead to renal failure. For this reason, early detection of microalbumin is important in order to avert renal complications in a diabetic patient. The presence of microalbuminuria has also been associated with an increased risk for cardiovascular disease. Reagent strips that are used for routine urinalysis cannot detect low levels of albumin excretion (1 to 2 mg/dL). Special reagent strips that are sensitive for these low levels of albumin are useful for periodic monitoring of patients with diabetes, hypertension, or peripheral vascular disease. | View Page |
| Albumin is the major serum protein found in normal urine. | View Page |
| Urine Bilirubin Bilirubin is formed as a result of the breakdown of hemoglobin from erythrocytes in the reticuloendothelial system. It becomes bound to albumin and transported through the blood to the liver. This free or unconjugated bilirubin is insoluble in water and cannot be filtered through the glomerulus of the kidney. In the liver, bilirubin becomes conjugated with glucuronic acid to form bilirubin diglucuronide. This conjugated bilirubin, which is also called direct bilirubin, is water soluble and is excreted by the liver through the bile duct and into the duodenum. | View Page |
| Routine Electrophoresis Routine electrophoresis is a generic term for the traditional clinical laboratory electrophoresis performed on a rectangle-shaped slab gel. Routine electrophoresis is mostly used for separation of proteins and has some use in separating nucleic acids. Generally several patient specimens and control(s) can be placed on one gel and solutes separated in one run. This type of electrophoresis is sometimes called zone electrophoresis.A serum sample with normal plasma proteins yields five zones or bands of separated proteins: albumin, alpha-1-globulins, alpha-2-globulins, beta-globulins, and gamma-globulins. Proteins in CSF and urine proteins are also separated with routine electrophoresis. Using whole blood treated with a reagent to lyse red blood cells, variant and glycosylated hemoglobins can be detected. With different visualization methods, isoenzymes and lipoproteins in a serum sample can be identified.A manual agarose gel electrophoresis of eight serum samples is pictured below. After electrophoresis, the gel was stained with Ponceau S. | View Page |
| Protein Binding Most drugs are bound to proteins when they circulate in the body. Albumin is a major drug-binding protein in serum. Albumin is an alkaline protein, so acidic and neutral drugs primarily bind to it. If albumin binding sites become saturated, acidic and neutral drugs can bind to lipoproteins. Alkaline drugs tend to bind to globulins, particularly to the globulin, alpha-1 acid glycoprotein. Only free, unbound drugs are able to bind drug receptors and have therapeutic effects. An equilibrium exists in the systemic circulation between a free and protein-bound drug and between a free and receptor-bound drug. This is illustrated in the image to the right. | View Page |
| Protein Availability and Drug Dosing Drug-binding proteins in serum can fluctuate in disease states. For example, if albumin levels fall, as can occur in liver failure or nephrotic syndrome, less albumin will be available for drug binding; a subsequent dose may produce a toxic concentration of free drug.The image on the right illustrates the loss of equilibrium between a protein-bound drug and a free drug when drug-binding proteins are diminished.Doses of drugs that are highly protein-bound may need to be adjusted in patients with lower drug-binding protein levels. Examples of some common drugs that are highly protein-bound include thyroxine, warfarin, diazepam, heparin, imipramine and phenytoin. � | View Page |
| Hepatic function panel Albumin (Alb)
Bilirubin (Bili)
Alkaline phosphatase (Alk Phos)
Total protein (TP)
Alanine aminotransferase (ALT)
Aspartate aminotransferase (AST)
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| Plasma proteins Numerous types of proteins are dispersed in the plasma. These include:
Coagulation proteins (blood clotting factors), which, if activated, will form a blood clot , and
Serum proteins, which are left dispersed in liquid after the clot is formed. Serum proteins include:
Albumin, a marker of nutrition, and
Globulins, or antibodies. | View Page |
| Testing collection containers In order to test collection containers for sperm collection, the sperm must be held in the container for several hours to ensure that neither the numbers nor motility are adversely affected. Numbers will decline if the sperm adhere to the container. Motility will decline if the container is toxic.
One method of testing involves removing sperm from semen. The specimen would be centrifuged and the sperm pellet diluted in a small volume of culture medium containing an energy source and at least 0.5% of a protein, such as serum albumin. The processed sperm specimen would be placed in the container to be tested. Total count and motility of the sperm would be tested at the start of incubation and 24 hours later. The container is non-toxic if the motility at the end of 24 hours is no less than 50% of the original value.
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