Abstract: A gas mixture for treatment of a mycobacterial infection and methods thereof, wherein the gas mixture comprises hydrogen. In certain applications, the gas mixture further comprises oxygen and optionally an inert or anaerobic gas, preferably selected from the group consisting of nitrogen, helium, argon, carbon dioxide, and mixtures thereof. The methods for treatment comprise direct inhalation of the gas mixture comprising hydrogen and oxygen, intubation of a patient with a double lumen endotracheal tube thereby supplying one lung with an anaerobic gas, and administration of a gas mixture comprising hydrogen and oxygen in a hyperbaric setting. Also provided is a method of sterilization of a mycobacterium-contaminated surface comprising administration of the hydrogen-containing gas mixture.

Abstract: Nucleic acid hybridization under steady-state conditions is described by a kinetic model in which the intermediate state is assumed to be locally single stranded. An expression was derived that relates nucleic acid secondary structure to the rate of oligonucleotide-RNA hybridization. The model allows the calculation of a rate factor that is proportional to the rate constant for hybridization between complementary nucleic acids and is generally applicable to any RNA molecule with potential utility for rapid identification of sites for antisense attack of mRNA.

Abstract: Nucleic acid hybridization under steady-state conditions is described by a kinetic model in which the intermediate state is assumed to be locally single stranded. An expression was derived that relates nucleic acid secondary structure to the rate of oligonucleotide-RNA hybridization. The model assumes that the hybridization of nucleic acids occurs through an intermediate state in which the region to be hybridized has a single-stranded conformation prior to binding the antisense oligonucleotide. In the derivation, a steady-state condition is assumed. The model is applicable to the steady-state condition in living cells and the initial stage of single-tube hybridization when full-length hybrid has not significantly accumulated and the concentration of nucleation complex is approximately constant. The model allows the calculation of a rate factor that is proportional to the rate constant for hybridization between complementary nucleic acids.

Abstract: The invention is based on the discovery that, for many drugs (e.g., antiviral or antimicrobial drugs such as antifungal or antibacterial drugs, including bacteriocidal or bacteriostatic drugs) and many pathogen strains (e.g., viral, fungal, or bacterial pathogens), a concentration of drug can be identified at which drug-resistant mutant pathogen strains are not selected. This concentration is herein referred to as the “mutant prevention concentration” (MPC). Maintaining serum concentrations of the drug above the MPC throughout a course of treatment should severely restrict selection of drug-resistant mutants. Additionally, it is discovered that drug-resistant mutant pathogens are selected exclusively within a drug concentration window, termed the “mutant selection window” (MSW). A quantitative expression of this window, which we call the “window index” (WI), is defined as the ratio of the MPC to the MIC.

Abstract: The invention is based on the discovery that, for many drugs (e.g., antiviral or antimicrobial drugs such as antifungal or antibacterial drugs, including bacteriocidal or bacteriostatic drugs) and many pathogen strains (e.g., viral, fungal, or bacterial pathogens), a concentration of drug can be identified at which drug-resistant mutant pathogen strains are not selected. This concentration is herein referred to as the “mutant prevention concentration” (MPC). Maintaining serum concentrations of the drug above the MPC throughout a course of treatment should severely restrict selection of drug-resistant mutants. Additionally, it is discovered that drug-resistant mutant pathogens are selected exclusively within a drug concentration window, termed the “mutant selection window” (MSW). A quantitative expression of this window, which we call the “window index” (WI), is defined as the ratio of the MPC to the MIC.

Abstract: The invention is based on the discovery that, for many drugs (e.g., antiviral or antimicrobial drugs such as antifungal or antibacterial drugs, including bacteriocidal or bacteriostatic drugs) and many pathogen strains (e.g., viral, fungal, or bacterial pathogens), a concentration of drug can be identified at which drug-resistant mutant pathogen strains are not selected. This concentration is herein referred to as the “mutant prevention concentration” (MPC). Maintaining serum concentrations of the drug above the MPC throughout a course of treatment should severely restrict selection of drug-resistant mutants. Additionally, it is discovered that drug-resistant mutant pathogens are selected exclusively within a drug concentration window, termed the “mutant selection window” (MSW). A quantitative expression of this window, which we call the “window index” (WI), is defined as the ratio of the MPC to the MIC.

Abstract: Mutant ribozymes are screened by culturing cells whose survival is dependant upon cleavage of RNA by a ribozyme, which cleavage causes the cells to survive in the presence of an agent which otherwise would kill the cells, and selecting cells which survive.