Proprietary Information and Courses from MediaLab, Inc.
These are the MediaLab courses that cover Proprietary and links to relevant pages within the course.
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| Importance of Determining Size and Number of Lipoprotein Particles In the clinical laboratory, we routinely measure the cholesterol content of high-density lipoprotein and low-density lipoprotein particles and not the apolipoproteins on the particles or the number of particles. Proprietary detergents and reagents are used in assays for HDL-C and LDL-C to separate lipoproteins, allowing the cholesterol content of specific lipoproteins to be measured. For example, HDL-C is commonly measured using a solution of dextran sulfate and magnesium to selectively precipitate HDL from the other lipoproteins present in the sample. Once isolated, the HDL particles are 'dissolved' and the amount of cholesterol in them is determined photometrically using a color-producing enzyme reaction. LDL-C can be measured directly or can be estimated using the HDL-C, triglycerides and total cholesterol (TC) values. The Friedewald formula is often used to calculate LDL: LDL-C = TC - (HDL-C)+(Triglycerides/5). The important point to consider here is that traditional LDL-C and HDL-C measurements only tell us how much cholesterol is associated with each lipoprotein particle class. We are now learning that the number and size of the particles are important as well. The number of LDL particles appears to be more strongly predictive of cardiovascular disease than the LDL-C content, and small dense LDL are known to be more atherogenic than larger, less dense LDL particles. | View Page |
| Nuclear Magnetic Resonance 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. | View Page |