Abstract: Bacterial resistance to antibiotics is increasing worldwide creating a global threat. Tuberculosis (TB), caused by the bacterium Mycobacterium tuberculosis, is a bacterial infectious disease that results in over one million deaths annually. The discovery outlined here involves a tablet composition for patient administration and subsequently a new paradigm in drug delivery vehicles in vivo and in vitro and is applied to existing TB antibiotics in order to increase their efficacy. The drug delivery system is a three component complex that is administered with the TB antibiotic or a combination of TB antibiotics. The components are a saccharide or saccharides, a transition metal ion or a combination of metal ions that can bind a nitrogen and/or oxygen atom(s), and a water soluble polymer capable of aggregating and enclosing the other constituents. The three component molecular delivery approach has demonstrated ability to overcome M. tuberculosis bacterial resistance to an existing antibiotic.

Abstract: Many types of artificial reefs have been deployed in the world's oceans, bays and estuaries. These range from sinking ships to dispersing old building debris. In most approaches, the material placed in the marine environment lacks any nutrients needed for growth or concern regarding proper chemical conditions necessary to start and sustain life. In this discovery, concrete is made from both inorganic and organic components. The inorganic components are selected to include species that will be used to create a receptive surface to start and sustain life. Moreover, other conditions such as pH, chemical toxicity, nutrient levels and biodegradability are considered in the formulation. Additionally, there is an organic component that is part of the concentration mixture which provides trace nutrients and serves to weaken the structures so it will biodegrade over time. The biodegradable concrete slowly releases small quantities of resources (over months and years) providing a steady flux of essential nutrients.

Abstract: Bacterial resistance to antibiotics is increasing worldwide creating a global threat. Tuberculosis (TB), caused by the bacterium Mycobacterium tuberculosis, is a bacterial infectious disease that results in over one million deaths annually. The discovery outlined here involves a tablet composition for patient administration and subsequently a new paradigm in drug delivery vehicles in vivo and in vitro and is applied to existing TB antibiotics in order to increase their efficacy. The drug delivery system is a three component complex that is administered with the TB antibiotic or a combination of TB antibiotics. The components are a saccharide or saccharides, a transition metal ion or a combination of metal ions that can bind a nitrogen and/or oxygen atom(s), and a water soluble polymer capable of aggregating and enclosing the other constituents. The three component molecular delivery approach has demonstrated ability to overcome M. tuberculosis bacterial resistance to an existing antibiotic.

Abstract: Methods for utilizing copper ions to bind to and help transport medicinal agents that contain a nitrogen atom or atoms are disclosed. The copper ion or ions serve as a delivery platform for a known pharmaceutical agent. The copper ions may be used to impact the polarity of the medicinal agents so they perform more efficiently in a physiological environment. The copper ions may also improve the efficacy of the drug by impacting their stability.

Abstract: Methods for producing and obtaining natural products from microbial amplification chambers are described. This approach utilizes the concept of green chemistry to synthesize and extract the marine and terrestrial natural products. The method describes techniques to colonize and grow the selected bacteria and to continuously harvest the pharmaceutical agent from the broth without using any commercial solvents.

Abstract: A recirculating loop method for producing and/or using ozone is disclosed. The method comprises the steps of: supplying a gas mixture comprising oxygen and a catalyst, generating ozone from the gas mixture, and recirculating the gas mixture. In a preferred method, the method comprises the additional steps of: reacting the ozone with a chemically reactive species and adding sufficient oxygen to the oxygen and noble gas mixture to maintain the specific oxygen to noble gas ratio. Preferably, the ozone is generated by electrical discharge from oxygen and noble gas mixtures of a volume ratio of not greater than 9 to 1 oxygen to catalyst gas.