Abstract: Provided herein are methods for measuring a molecular flux rate proteins and polypeptides based on analysis of isotopologue abundances of immonium ion fragments within a mass isotopomer using a high resolution mass spectrometric measurement. Such methods may be used, inter alia, to calculate a fraction of newly synthesized protein or polypeptide molecules of interest, a replacement rate of target molecules of interest, and/or a rate of breakdown or degradation of target molecules of interest, e.g., based on isotopologue relative abundances.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides the necessary information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired. In one aspect of the invention, stable isotope-labeled substrate molecules are administered to a subject and the label is incorporated into targeted molecules in a manner that reveals molecular flux rates through one or more metabolic pathways of interest.

Abstract: Provided herein are methods for measuring molecular flux rates of molecules of interest in a tissue sample in spatially-organized manner and generating output (e.g., an image, a heat map, a contour map, a table or a database) representing the molecular flux rates of each spatially-defined location of the sample. Provided herein are also the output, as well as systems and computer-readable medium with computer-executable instructions for determining molecular flux rates of molecules of interest in the sample.

Abstract: The present invention is based on the finding that enrichment of D3-creatinine in a urine sample following oral administration of a single defined dose of D3-creatine can be used to calculate total-body creatine pool size and total body skeletal muscle mass in a subject. The invention further encompasses methods for detecting creatinine and D3-creatinine in a single sample. The methods of the invention find use, inter alia, in diagnosing disorders related to skeletal muscle mass, and in screening potential therapeutic agents to determine their effects on muscle mass.

Abstract: Provided herein are methods for measuring a molecular flux rate based on analysis of isotopologue abundance within a mass isotopomer, e.g., using a high resolution mass spectrometric measurement. Such methods may be used, inter alia, to calculate a fraction of newly synthesized target molecules of interest, a replacement rate of target molecules of interest, and/or a rate of breakdown or degradation of target molecules of interest, e.g., based on isotopologue relative abundance.

Abstract: The present invention is based on the finding that enrichment of D3-creatinine in a urine sample following; oral administration of a single defined dose of D3-creatine can be used to calculate total-body creatine pool size and total body skeletal muscle mass in a subject. The invention further encompasses methods for detecting creatinine and D3-creatinine in a single sample. The methods of the invention find use, inter alia, in diagnosing disorders related to skeletal muscle mass, and in screening potential therapeutic agents to determine their effects on muscle mass.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides the necessary information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired. In one aspect of the invention, stable isotope-labeled substrate molecules are administered to a subject and the label is incorporated into targeted molecules in a manner that reveals molecular flux rates through one or more metabolic pathways of interest.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides the necessary information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired.

Abstract: The present invention is based on the finding that enrichment of D3-creatinine in a urine sample following oral administration of a single defined dose of D3-creatine can be used to calculate total-body creatine pool size and total body skeletal muscle mass in a subject. The invention further encompasses methods for detecting creatinine and D3-creatinine in a single sample. The methods of the invention find use, inter alia, in diagnosing disorders related to skeletal muscle mass, and in screening potential therapeutic agents to determine their effects on muscle mass.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides the necessary information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired.

Abstract: The present invention is based on the finding that enrichment of D3-creatinine in a urine sample following oral administration of a single defined dose of D3-creatine can be used to calculate total-body creatine pool size and total body skeletal muscle mass in a subject. The invention further encompasses methods for detecting creatinine and D3-creatinine in a single sample. The methods of the invention find use, inter alia, in diagnosing disorders related to skeletal muscle mass, and in screening potential therapeutic agents to determine their effects on muscle mass.

Abstract: The present invention is based on the finding that enrichment of isotope-labeled creatinine in a urine sample following oral administration of a single defined dose of isotope-labeled can be used to calculate total-body creatine pool size and total body skeletal muscle mass in a subject. The invention further encompasses methods for detecting creatinine and isotope-labeled creatinine in a single sample. The methods of the invention find use, inter alia, in diagnosing disorders related to skeletal muscle mass, and in screening potential therapeutic agents to determine their effects on muscle mass.

Abstract: Provided herein are method for measuring the rate of synthesis, breakdown, transport, or other kinetic parameters of a protein in a tissue of medical interest, without requiring physical sampling of the tissue, by a measurement of the protein in a body fluid.

Abstract: Disclosed here is a method for measuring the kinetics (i.e., the molecular flux rates—synthesis and breakdown or removal rates) of a plurality of proteins or organic metabolites in living systems. The methods may be accomplished in a high-throughput, large-scale automated manner, by using existing mass spectrometric profiling techniques and art well known in the fields of static proteomics and static organeomics, without the need for additional biochemical preparative steps or analytic/instrumental devices.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired. In one aspect of the invention, stable isotope-labeled substrate molecules are administered to a subject and the label is incorporated into targeted molecules in a manner that reveals molecular flux rates through metabolic pathways of interest.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired. In one aspect of the invention, stable isotope-labeled substrate molecules are administered to a subject and the label is incorporated into targeted molecules in a manner that reveals molecular flux rates through metabolic pathways of interest.

Abstract: Disclosed here is a method for measuring the kinetics (i.e., the molecular flux rates-synthesis and breakdown or removal rates) of a plurality of proteins or organic metabolites in living systems. The methods may be accomplished in a high-throughput, large-scale automated manner, by using existing mass spectrometric profiling techniques and art well known in the fields of static proteomics and static organeomics, without the need for additional biochemical preparative steps or analytic/instrumental devices.

Abstract: The invention disclosed herein describes a novel therapeutic target for motoneuron diseases (altered dynamics of microtubules in neurons); a method for measuring the state of activity of this therapeutic target in subjects with established, incipient, or potential motoneuron disease; the discovery of drug agents that modulate neuronal microtubule dynamics in living subjects with motoneuron diseases; the discovery that administration of such agents, alone or in combinations, can provide marked neuroprotective therapy for living subjects with motoneuron diseases including delay in symptoms and prolongation of survival; and the discovery that monitoring of neuronal microtubule dynamics in subjects with motoneuron diseases, in response to therapeutic interventions, allows diagnostic monitoring for optimization of therapeutic regimen and strategy for individual subjects or for drug trials.

Abstract: Provided herein are methods for measuring molecular flux rates of molecules of interest in a tissue sample in spatially-organized manner and generating output (e.g., an image, a heat map, a contour map, a table or a database) representing the molecular flux rates of each spatially-defined location of the sample. Provided herein are also the output, as well as systems and computer-readable medium with computer-executable instructions for determining molecular flux rates of molecules of interest in the sample.

Abstract: The methods described herein enable the evaluation of compounds on subjects to assess their therapeutic efficacy or toxic effects. The target of analysis is the underlying biochemical process or processes (i.e., metabolic process) thought to be involved in disease pathogenesis. Molecular flux rates within the one or more biochemical processes serve as biomarkers and are quantitated and compared with the molecular flux rates (i.e., biomarker) from control subjects (i.e., subjects not exposed to the compounds). Any change in the biomarker in the subject relative to the biomarker in the control subject provides the necessary information to evaluate therapeutic efficacy of an administered drug or a toxic effect and to develop the compound further if desired. In one aspect of the invention, stable isotope-labeled substrate molecules are administered to a subject and the label is incorporated into targeted molecules in a manner that reveals molecular flux rates through one or more metabolic pathways of interest.