Abstract: A method for fractional measurement of small, dense LDL, which is adaptable for an autoanalyzer, and a reagent for measurement, are provided, making it possible to conduct rapid and convenient analysis with good sensitivity without pretreatment of a specimen. The method for quantitatively determining small, dense LDL cholesterol in a sample comprises the steps of: (1) eliminating cholesterol in LDL other than small, dense LDL in the presence of phospholipase; and (2) quantitatively determining cholesterol in lipoproteins remaining in step (1) above.

Abstract: A rapid and convenient method capable of performing fractional measurement of small, dense LDLs without pretreatment of a specimen, which is adaptable for an autoanalyzer, is provided. A method for quantitatively determining small, dense LDL cholesterol is provided, which comprises adding enzymes for cholesterol measurement to a test sample in the presence of a polyoxyethylene-polyoxypropylene copolymer or a derivative thereof, causing the polyoxyethylene-polyoxypropylene copolymer or the derivative thereof to selectively act on small, dense LDLs among lipoproteins, and then measuring the amount of cholesterol generated.

Abstract: Disclosed is a method for quantifying HDL2 cholesterol in a test sample without requiring laborious operations. The method for quantifying cholesterol comprises allowing phospholipase to act on HDL to quantify cholesterol. Also disclosed is a method comprising: a first step of transferring cholesterols other than high-density lipoproteins in a test sample to the outside of the reaction system; and a second step of quantifying high-density lipoprotein 2 cholesterol among the high-density lipoproteins remaining in the reaction system; wherein, by performing the second step by the above method, high-density lipoprotein 2 cholesterol in the test sample can be quantified.

Abstract: A method for fractional measurement of small, dense LDL, which is adaptable for an autoanalyzer, and a reagent for measurement, are provided, making it possible to conduct rapid and convenient analysis with good sensitivity without pretreatment of a specimen. The method for quantitatively determining small, dense LDL cholesterol in a sample comprises the steps of: (1) eliminating cholesterol in LDL other than small, dense LDL in the presence of phospholipase; and (2) quantitatively determining cholesterol in lipoproteins remaining in step (1) above.

Abstract: A method that enables quantification of cholesterol in high-density lipoprotein 3 (HDL3) in a test sample without requiring a laborious operation is disclosed. The method for quantifying cholesterol in HDL3 comprises: Step 1 wherein phospholipase and/or sphingomyelinase is/are allowed to act on a test sample to transfer cholesterol to the outside of the reaction system; and Step 2 wherein cholesterol remaining in the reaction system is quantified. The method enables specific quantification of HDL3 cholesterol in a test sample using an automatic analyzer without requirement of a laborious operation such as ultracentrifugation or pretreatment. Further, quantification of the HDL2 cholesterol level can also be carried out by subtracting the HDL3 cholesterol level from the total HDL cholesterol level obtained by a conventional method for quantifying the total HDL cholesterol in a test sample.

Abstract: A method that enables quantification of cholesterol in high-density lipoprotein 3 (HDL3) in a test sample without requiring a laborious operation is disclosed. The method for quantifying cholesterol in HDL3 comprises reacting, with a test sample, a surfactant that specifically reacts with high-density lipoprotein 3, and quantifying cholesterol. The method enables specific quantification of HDL3 cholesterol in a test sample using an automatic analyzer without requirement of a laborious operation such as ultracentrifugation or pretreatment. Further, quantification of the HDL2 cholesterol level can also be carried out by subtracting the HDL3 cholesterol level from the total HDL cholesterol level obtained by a conventional method for quantifying the total HDL cholesterol in a test sample.

Abstract: A method that enables quantification of cholesterol in high-density lipoprotein 3 (HDL3) in a test sample without requiring a laborious operation is disclosed. The method for quantifying cholesterol in HDL3 comprises: Step 1 wherein a surfactant that reacts with lipoproteins other than high-density lipoprotein 3 is reacted with a test sample to transfer cholesterol to the outside of the reaction system; and Step 2 wherein cholesterol remaining in the reaction system is quantified. The method enables specific quantification of HDL3 cholesterol in a test sample using an automatic analyzer without requirement of a laborious operation such as ultracentrifugation or pretreatment. Further, quantification of the HDL2 cholesterol level can also be carried out by subtracting the HDL3 cholesterol level from the total HDL cholesterol level obtained by a conventional method for quantifying the total HDL cholesterol in a test sample.

Abstract: A method for fractional measurement of small, dense LDL, which is adaptable for an autoanalyzer, and a reagent for measurement, are provided, making it possible to conduct rapid and convenient analysis with good sensitivity without pretreatment of a specimen. The method for quantitatively determining small, dense LDL cholesterol in a sample comprises the steps of: (1) eliminating cholesterol in LDL other than small, dense LDL in the presence of phospholipase; and (2) quantitatively determining cholesterol in lipoproteins remaining in step (1) above.

Abstract: This invention provides a method for separately or simultaneously quantifying cholesterol in a total amount of HDL-C, cholesterol in an HDL subfraction of apoE-containing HDL-C, and cholesterol in an HDL subfraction of apoE-deficient HDL-C. The method comprises enzymatically and separately quantifying cholesterol in apoE-containing HDL and cholesterol in apoE-deficient HDL by adding a surfactant selected from the group consisting of a surfactant with an apoE-containing HDL response rate/apoE-deficient HDL response rate ratio of 0.7 to less than 1.3, a surfactant with an apoE-containing HDL response rate/apoE-deficient HDL response rate ratio of less than 0.7, and a surfactant with an apoE-containing HDL response rate/apoE-deficient HDL response rate ratio of 1.3 or more to a test sample, allowing cholesterol esterase and cholesterol oxidase to react therewith, and quantifying the hydrogen peroxide generated.

Abstract: An object of the present invention is to provide an excellent method for detection and diagnosis of familial combined hyperlipidemia. The present invention relates to a method for detection of familial combined hyperlipidemia by measuring the concentration of small, dense LDL cholesterol in a sample collected from a subject.

Abstract: A reagent for fractional measurement of small, dense LDLs without pretreatment of a specimen, which is adaptable to a rapid and convenient autoanalyzer, is provided. A method for quantitatively determining cholesterol in small, dense LDLs in a sample is further provided. The method includes first step of eliminating lipoproteins other than small, dense LDLs in a sample in the presence of cholesterol esterase and 0.05 g/L to 1.0 g/L of a surfactant that acts on the lipoproteins other than small, dense LDLs, and a second step of quantitatively determining cholesterol in small dense LDLs that remain after the first step.

Abstract: The present invention provides a fast and simple method for fractional measurement of small particle low density lipoprotein (LDL). The method for quantifying small particle LDL in a test sample entails a first step of separating the small particle LDL from other low density lipoproteins, and a second step of measuring cholesterol, triglycerides or proteins in the separated small particle LDL.

Abstract: A method for fractional measurement of small, dense LDL, which is adaptable for an autoanalyzer, and a reagent for measurement, are provided, making it possible to conduct rapid and convenient analysis with good sensitivity without pretreatment of a specimen. The method for quantitatively determining small, dense LDL cholesterol in a sample comprises the steps of: (1) eliminating cholesterol in LDL other than small, dense LDL in the presence of phospholipase; and (2) quantitatively determining cholesterol in lipoproteins remaining in step (1) above.

Abstract: A reagent for fractional measurement of small, dense LDLs without pretreatment of a specimen, which is adaptable to a rapid and convenient autoanalyzer, is provided. A method for quantitatively determining cholesterol in small, dense LDLs in a sample is further provided, comprising: a first step of eliminating lipoproteins other than small, dense LDLs in a sample in the presence of cholesterol esterase and 0.05 g/L to 1.0 g/L of a surfactant that acts on the lipoproteins other than small, dense LDLs; and a second step of quantitatively determining cholesterol in small, dense LDLs that remain after the first step.

Abstract: An object of the present invention is to provide an excellent method for detection and diagnosis of familial combined hyperlipidemia. The present invention relates to a method for detection of familial combined hyperlipidemia, comprising measuring the concentration of small, dense LDL cholesterol in a sample collected from a subject.

Abstract: A rapid and convenient method capable of performing fractional measurement of small, dense LDLs without pretreatment of a specimen, which is adaptable for an autoanalyzer, is provided. A method for quantitatively determining small, dense LDL cholesterol is provided, which comprises adding enzymes for cholesterol measurement to a test sample in the presence of a polyoxyethylene-polyoxypropylene copolymer or a derivative thereof, causing the polyoxyethylene-polyoxypropylene copolymer or the derivative thereof to selectively act on small, dense LDLs among lipoproteins, and then measuring the amount of cholesterol generated.

Abstract: This invention provides a method for differentially and simultaneously quantifying two target analytes via a single assay operation with the use of a single type of reagent in each of the two steps, i.e., the first step and the second step. In this method, the reaction product associated with the first target analyte is detected at an early stage of the second step and the reaction product associated with the second target analyte is then detected.

Abstract: The object of the present invention is to provide a fast and simple method for fractional measurement of a small particle LDL. A method for quantifying a small particle low density lipoprotein in a test sample, comprising a first step for separating the small particle low density lipoprotein from other low density lipoproteins, and a second step for measuring cholesterol, triglycerides or proteins in the separated small particle low density lipoprotein.

Abstract: A fast and simple method for fractional measurement of a small particle LDL entails separating the small particle LDL and HDL from other lipoproteins, and then measuring cholesterol, triglycerides, or proteins in the separated small particle LDL.

Abstract: The object of the present invention is to provide a fast and simple method for fractional measurement of a small particle LDL. A method for quantifying a small particle low density lipoprotein in a test sample, comprising a first step for separating the small particle low density lipoprotein from other low density lipoproteins, and a second step for measuring cholesterol, triglycerides or proteins in the separated small particle low density lipoprotein.