Lipid Information and Courses from MediaLab, Inc.

We are all aware of the clinical laboratory's role in assessing overall health and we are also aware that measuring a patient's serum lipids will provide some insight into their cardiovascular health. The traditional measurements of low-density lipoprotein cholesterol (LDL-C), high-density lipoprotein cholesterol (HDL-C), and triglycerides are the 'classic' cardiovascular risk markers.Laboratorians, and even the general public are now well-aware that LDL-C ('bad' cholesterol) concentrations should be low while HDL-C ('good' cholesterol) concentrations should be high. Triglycerides should be kept in check as well. Optimal levels are shown in the table below. So what is the risk if these values are not within optimal ranges?Cardiovascular risk can be simply defined as increasing the odds of having a pathology which affects blood flow and/or the heart. The most common cardiovascular pathology is atherosclerosis. Other cardiovascular pathologies whose odds increase as serum lipids and other cardiovascular markers become suboptimal are myocardial infarction (heart attack), stroke, congestive heart disease and coronary artery disease. Other diseases such as diabetes and the metabolic syndrome are also strongly associated with the classic cardiovascular risk markers LDL-C, HDL-C and triglycerides.

Lipoproteins differ in size and density as well as in their content (what they tend to carry). They also can differ in their origination (where they are made). Another significant difference between lipoprotein molecules is the proteins they have on their surfaces. These proteins, known as apolipoproteins, are the major identifying characteristics of a lipoprotein. There are many different apolipoproteins and we are continually learning more about them. Apolipoproteins have multiple roles. One role is that these amphipathic (detergent-like) proteins increase the overall solubility of the lipid particle, helping it to dissolve in the aqueous environment of the blood. Apolipoproteins can also function as enzyme co-factors (receptor ligands) and facilitate the transfer of their lipid cargo to specific cells. Thus, the apoliproteins are the smart or working-end of the lipoprotein particle. The apolipoproteins dictate where the particles will dock and where they can bind, and in so doing the apolipoproteins regulate lipid metabolism in the body.

How do physicians interpret risk marker results? Assuming the laboratory offers, and physicians order, cardiovascular risk marker tests, how are these results used? The National Cholesterol Education Program periodically assembles scientists and physicians to create lipid treatment guidelines for patients. These panels are referred to as the Adult Treatment Panel (ATP). The third assembly of the ATP did not give specific guidelines regarding risk marker use in patients but they did acknowledge their potential utility. The general consensus is that novel cardiovascular risk markers should be used in selected patients, such as those who already have significant risk factors (hypertension, smoking, obesity, etc.) or in patients who have family histories of cardiovascular disease. The value in using risk markers is that they will not only uncover cardiovascular risk but they can also be used to motivate patients to alter lifestyle and diet. It is expected that as these emerging cardiovascular risk markers continue to be validated in clinical studies, they will become very useful and perhaps even be part of a new standard of care for patients.If risk marker levels can be correlated to treatment strategies, physicians will find them especially useful in tracking patient success.

LpPLA2 refers to lipoprotein-associated phospholipase A2. This enzyme is also known as platelet-activating factor acetylhydrolase(PAF). The LpPLA2 enzyme is a lipase found predominantly on the surface of LDL particles. Note that LpPLA2 is a lipase enzyme and not an apolipoprotein. LpPLA2 is made by inflammatory cells (T cells, mast cells, macrophages) and then integrated onto the surface of lipoprotein particles. The enzymatic function of LpPLA2 is to hydrolyze oxidized phospholipids in LDL.LpPLA2 plays a corrective role in removing oxidized phospholipids. Thus, it might seem that having high levels of LpPLA2 would be good. However, although LpPLA2 has a positive role in removing oxidized lipids, it also generates inflammatory products in the process. So in fact, high levels of LpPLA2 are associated with increased cardiovascular risk. Researchers have identified high amounts of LpPLA2 in human atherosclerotic lesions. The LpPLA2 that accumulates in the vessel wall can come from LDL (which can carry LpPLA2 on its surface) or it can come from immune cells that have invaded the vessel wall. Since Lp-PLA2 is produced or localized in the plaque itself, it may be a more specific marker of cardiovascular function compared to systemic, more general inflammatory markers like hs-CRP.

The nuclear magnetic resonance (NMR) spectroscopy technique that was developed by LipoScience (LipoScience, Inc., Raleigh, NC), exploits specific magnetic properties of lipoproteins. This technology does not require separation of lipoproteins; serum or plasma can be run through the NMR sensor probe and all lipoproteins can be measured directly and homogeneously. The NMR platform works by subjecting the patient sample to a pulse of radio energy within a strong magnetic field. The energy that is given off by the lipids in the sample results is a signal that can be analyzed by the instrument to determine the number and size of lipoproteins present. Lipids associated with larger lipoproteins produce a signal that is distinct from those of smaller lipoproteins. A computer algorithm developed by LipoScience deconvolutes the signals into lipoprotein subclasses and then quantifies the number of particles in each class.NMR provides a useful and novel way to quantitate lipoprotein particles. However it is currently a proprietary technology and NMR analyzers are not yet readily-available for purchase and use in smaller clinical laboratories.

Some global specimen collection and handling issues to consider include: Specimens that contain nucleated cells will be of interest in DNA methodologies while specimens lacking nucleated cells are more useful in RNA methodologies. rRNA is more stable than mRNA, which is labile and sensitive to contamination. DNA is relatively stable and can be obtained from nonviable sources. Serum or plasma obtained by standard routine venipuncture procedures can be used as long as proper site selection and decontamination occur. Standard anticoagulants such as Ethylenediaminetetraacetic Acid (EDTA) and Acid Citrate Dextrose (ACD) can be used; however avoid the use of heparin as an anticoagulant as it interferes with some polymerase chain reaction (PCR) methodologies. When using fluorescence, fasting serum or whole blood specimens should be used to decrease the interference by lipids.

Like many other viruses, the HIV has a lipid membrane that covers the capsid. This envelope is acquired when the virus leaves a cell after replication. The HIV envelope has projections known as spikes, which contain specific chemical components that may assist the virus when it attaches to other cells.

Like many other viruses, the HIV has a lipid membrane that covers the capsid. This envelope is acquired when the virus leaves a cell after replication. The HIV envelope has projections known as spikes, which contain specific chemical components that may assist the virus when it attaches to other cells.

This variation of a macrophage signals the presence of a very rare lipid storage disorder. Due to the size and distinctive color of this cell it is also visible during the low power examination.

In addition to protein availability, other factors may affect drug absorption and distribution in the body as a whole or at specific sites within the body. The following table highlights some of these other factors. Factor Discussion Regional blood flow Reduced area blood flow can be seen in diabetics and enhanced blood flow can be seen in tumors. Lipid solubility of the drug The more lipophilic a drug is, the more likely it will enter the central nervous system. The integrity of the GI tract In a diseased gut, an orally-administered drug may not be absorbed as expected. Age Drug kinetics and dispositions change throughout life. In general, metabolism of drugs is reduced in the elderly. Genetics Mutations or deletions in drug metabolizing enzymes can greatly affect a drug's disposition.

Cholesterol High density lipoprotein Low density lipoproteinTriglycerides Lipid profile is run on serum or plasma. It requires a 14 hour fast prior to collection.

Circulating whole blood is a mixture of: Plasma (which contains fluid, proteins, and lipids), and Formed elements, consisting of red cells, white cells, and platelets.

Acanthocytes can also be seen in this slide. Alcoholic cirrhosis is the most common source of acanthocytes seen in blood smears in the laboratory (10-50%). Other sources are lipid disorders and a small number following splenectomy.

Cholesterol crystals may be seen in renal tubular disease. These crystals look like plates of glass, sometimes with a notch out of one corner. Under polarized light, they exhibit a stained glass effect. These crystals are rarely seen unless the specimen has been refrigerated, because the lipids remain in droplet form. Large amounts of protein, lipid droplets, fatty casts or oval fat bodies should be found along with cholesterol crystals. Cholesterol crystals are found in acid or neutral urine.