The inventors demonstrate that the phosphatase and hydrolase domains of soluble epoxide hydrolase (sEH) regulate the cardiovascular calcification process and revealed that inhibition of the phosphatase domain of sEH could represent a new pharmacological target in the prevention of cardiovascular calcification. The present invention thus relates to a therapeutically effective amount of an inhibitor of phosphatase activity of soluble epoxide hydrolase for use in a method of treating cardiovascular calcification in a subject in need thereof.

Disclosed is a method for quantifying phosphatidylinositol in a sample, comprising the following step: (1) treating the sample with phospholipase D and inositol dehydrogenase; and a kit for quantifying phosphatidylinositol, containing phospholipase D and inositol dehydrogenase.

The problem of detecting whether a urine sample is true human urine or a counterfeit urine product is solved by the use of reagent systems that detect two markers normally present in human urine. The markers acid phosphatase and alkaline phosphatase catalyze the substrates thymolphthalein monophosphate and p-nitrophenol phosphate, respectively. These substrates are formulated as spot tests on a dip stick or as reagents for use in automated chemical analyzers. The presence of the markers can be qualitatively detected by color-changes in the sample, formed by the pH-specific chromogens that result from catalysis of the substrates with the markers. The control reagent can further indicate whether a counterfeit urine product contains one or both of the chromogens.

The problem of detecting whether a urine sample is true human urine or a counterfeit urine product is solved by the use of reagent systems that detect two markers normally present in human urine. The markers acid phosphatase and alkaline phosphatase catalyze the substrates thymolphthalein monophosphate and p-nitrophenol phosphate, respectively. These substrates are formulated as spot tests on a dip stick or as reagents for use in automated chemical analyzers. The presence of the markers can be qualitatively detected by color-changes in the sample, formed by the pH-specific chromogens that result from catalysis of the substrates with the markers. The control reagent can further indicate whether a counterfeit urine product contains one or both of the chromogens.

The present invention is a patch-sized apparatus for use with an apparel to detect seminal fluid that includes disposable housing. The disposable housing is removably attached to the apparel. The disposable portion incorporates therein a fluid channel comprising a chemical solution to detect seminal fluid present on the surface of the apparel. The chemical solution includes but not limited to 1-Naphthylphosphate (disodium salt); and prostate-specific antigen (PSA)(A67-B/E3).

The present invention discloses a method to discover selective inhibitors of phosphatases. Thus the invention provides a method for screening a test compound to determine whether the compound binds a holophosphatase selectively or non-selectively comprising: i) providing a first holophosphatase wherein said holophosphatase is captured/immobilised; ii) testing a test compound for its ability to bind to the first holophosphatase; iii) providing a second holophosphatase wherein said second holophosphatase is captured/immobilised; iv) testing the same test compound for its ability to bind to the second holophosphatase; v) comparing the binding of the test compound to said first holophosphatase with the binding to said second phosphatase wherein a compound that binds a holophosphatase selectively will bind to said first holophosphatase but not said second holophosphatase; or will bind to said second holophosphatase but not said first; or wherein a compound that binds a holophosphatase non-selectively will bind to both said first holophosphatase and said second holophosphatase.

The present invention discloses a method to discover selective inhibitors of phosphatases. Thus the invention provides a method for screening a test compound to determine whether the compound binds a holophosphatase selectively or non-selectively comprising: i) providing a first holophosphatase wherein said holophosphatase is captured/immobilised; ii) testing a test compound for its ability to bind to the first holophosphatase; iii) providing a second holophosphatase wherein said second holophosphatase is captured/immobilised; iv) testing the same test compound for its ability to bind to the second holophosphatase; v) comparing the binding of the test compound to said first holophosphatase with the binding to said second phosphatase wherein a compound that binds a holophosphatase selectively will bind to said first holophosphatase but not said second holophosphatase; or will bind to said second holophosphatase but not said first; or wherein a compound that binds a holophosphatase non-selectively will bind to both said first holophosphatase and said second holophosphatase.

The present invention relates to inhibitors of PPP1 R15A and PPP1 R15B and their use in therapy, particularly in the treatment of a disease state alleviated by the inhibition of PPP1 R15A and PPP1 R15B, for example a disorder associated with accumulation of misfolded proteins or proteostatsis disorder. Compounds of the invention include compounds having the formula IA or a pharmaceutically acceptable salt thereof, wherein R.sup.1a, R.sup.3a, R.sup.5a, X.sup.a and Y.sup.a are as defined herein. ##STR00001##

The present invention relates to inhibitors of PPP1 R15A and PPP1 R15B and their use in therapy, particularly in the treatment of a disease state alleviated by the inhibition of PPP1 R15A and PPP1 R15B, for example a disorder associated with accumulation of misfolded proteins or proteostatsis disorder. Compounds of the invention include compounds having the formula IA or a pharmaceutically acceptable salt thereof, wherein R.sup.1a, R.sup.3a, R.sup.5a, X.sup.a and Y.sup.a are as defined herein. ##STR00001##

A detoxification method includes the steps of inducing flow of patient blood through an extracorporeal device inlet and outlet in fluid connection to the circulatory system of a patient. Biological agents including lipopolysaccharide (LPS) contained within patient blood can be detoxified by passing patient blood over a biochemical reactor surface having attached or immobilized Saccharomyces boulardii alkaline phosphatase enzyme, with the biochemical reactor being contained within the extracorporeal device. An acyloxyacyl hydrolase enzyme may also be used on the biochemical reactor surface.