Provided is a technology related to a horseshoe crab factor B variant, and also provided is means for performing endotoxin measurement with high sensitivity. A polypeptide having an amino acid sequence in which the amino acid residue at the 193-position in an amino acid sequence of a polypeptide of horseshoe crab factor B is substituted with a cysteine (Cys) residue, is produced. Endotoxin measurement can be carried out with high sensitivity by configuring a Limulus reagent by combining this polypeptide with horseshoe crab factor C.

Provided is a technology related to a horseshoe crab factor B variant, and also provided is means for performing endotoxin measurement with high sensitivity. A polypeptide having an amino acid sequence in which the amino acid residue at the 193-position in an amino acid sequence of a polypeptide of horseshoe crab factor B is substituted with a cysteine (Cys) residue, is produced. Endotoxin measurement can be carried out with high sensitivity by configuring a Limulus reagent by combining this polypeptide with horseshoe crab factor C.

The present application is directed to to a method for therapy guidance and/ or therapy monitoring and/ or therapy stratification in a patient with shock and/or in a patient running into shock. In particular, the method comprises providing a sample from said patient, determining a level of DPP3 in said sample, and wherein the level of DPP3 in said sample is indicative of whether a treatment with an anti-ADM antibody or anti-ADM antibody fragment or anti-ADM non-Ig scaffold is required. In a preferred embodiment of the invention, the method comprises additionally determining in a sample from said patient a level of ADM-NH.sub.2.

The present application is directed to to a method for therapy guidance and/ or therapy monitoring and/ or therapy stratification in a patient with shock and/or in a patient running into shock. In particular, the method comprises providing a sample from said patient, determining a level of DPP3 in said sample, and wherein the level of DPP3 in said sample is indicative of whether a treatment with an anti-ADM antibody or anti-ADM antibody fragment or anti-ADM non-Ig scaffold is required. In a preferred embodiment of the invention, the method comprises additionally determining in a sample from said patient a level of ADM-NH.sub.2.

The current disclosure provides antibodies that bind to peptides associated with the primary immunodeficiency disorders (PIDD) Wiskott-Aldrich Syndrome (WAS) and X-linked agammaglobulinemia (XLA). The antibodies can be used in peptide immunoaffinity enrichment coupled to selected reaction monitoring mass spectrometry (immuno-SRM) assays for clinical diagnosis and newborn screening of WAS and XLA, among other uses.

A2M polypeptide compositions containing a non-natural bait region are disclosed. Methods of producing wild-type and variant A2M polypeptides and polynucleotides containing a non-natural bait region are also disclosed. The bait regions of the variant A2M polypeptides demonstrate enhanced protease inhibitory characteristics compared to wild-type A2M. Variant A2M polypeptides that demonstrate longer half-lives upon administration to an organism compared to wild-type A2M are disclosed. The A2M compositions are useful in treating a number of diseases and conditions including inflammation, chronic wounds, and diseases with a pathology associated with proteases.

A2M polypeptide compositions containing a non-natural bait region are disclosed. Methods of producing wild-type and variant A2M polypeptides and polynucleotides containing a non-natural bait region are also disclosed. The bait regions of the variant A2M polypeptides demonstrate enhanced protease inhibitory characteristics compared to wild-type A2M. Variant A2M polypeptides that demonstrate longer half-lives upon administration to an organism compared to wild-type A2M are disclosed. The A2M compositions are useful in treating a number of diseases and conditions including inflammation, chronic wounds, and diseases with a pathology associated with proteases.

The current disclosure provides for specific peptides, and derived ionization characteristics of the peptides, from the ALK, Ros, Ron, Ret, TS, and/or FGFR1 proteins that are particularly advantageous for quantifying the ALK, Ros, Ron, Ret, TS, and/or FGFR1 proteins directly in biological samples that have been fixed in formalin by the methods of Selected Reaction Monitoring (SRM) mass spectrometry, or as Multiple Reaction Monitoring (MRM) mass spectrometry. Such biological samples are chemically preserved and fixed wherein the biological sample is selected from tissues and cells treated with formaldehyde containing agents/fixatives including formalin-fixed tissue/cells, formalin-fixed/paraffin embedded (FFPE) tissue/cells, FFPE tissue blocks and cells from those blocks, and tissue culture cells that have been formalin fixed and or paraffin embedded. A protein sample is prepared from the biological sample using the Liquid Tissue™ reagents and protocol and the ALK, Ros, Ron, Ret, TS, and/or FGFR1 proteins are quantitated in the Liquid Tissue™ sample by the method of SRM/MRM mass spectrometry, by quantitating in the protein sample at least one or more of the peptides described. These peptides can be quantitated if they reside in a modified or an unmodified form. An example of a modified form of an ALK, Ros, Ron, Ret, TS, and/or FGFR1 fragment peptide is phosphorylation of a tyrosine, threonine, serine, and/or other amino acid residues within the peptide sequence.

The current disclosure provides for specific peptides, and derived ionization characteristics of the peptides, from the ALK, Ros, Ron, Ret, TS, and/or FGFR1 proteins that are particularly advantageous for quantifying the ALK, Ros, Ron, Ret, TS, and/or FGFR1 proteins directly in biological samples that have been fixed in formalin by the methods of Selected Reaction Monitoring (SRM) mass spectrometry, or as Multiple Reaction Monitoring (MRM) mass spectrometry. Such biological samples are chemically preserved and fixed wherein the biological sample is selected from tissues and cells treated with formaldehyde containing agents/fixatives including formalin-fixed tissue/cells, formalin-fixed/paraffin embedded (FFPE) tissue/cells, FFPE tissue blocks and cells from those blocks, and tissue culture cells that have been formalin fixed and or paraffin embedded. A protein sample is prepared from the biological sample using the Liquid Tissue™ reagents and protocol and the ALK, Ros, Ron, Ret, TS, and/or FGFR1 proteins are quantitated in the Liquid Tissue™ sample by the method of SRM/MRM mass spectrometry, by quantitating in the protein sample at least one or more of the peptides described. These peptides can be quantitated if they reside in a modified or an unmodified form. An example of a modified form of an ALK, Ros, Ron, Ret, TS, and/or FGFR1 fragment peptide is phosphorylation of a tyrosine, threonine, serine, and/or other amino acid residues within the peptide sequence.

The present invention relates to a colorimetric detection system for rapid detection of lung diseases. The detection system comprises antibodies and/or aptamers coupled to a substrate for capturing a lung disease specific antigen. The colorimetric system further comprises dyed microspheres modified with the antibodies and/or aptamers for visually detecting the lung disease specific antigen. The present invention also relates to a method of producing said detection system and a mask with such a detection system.