Up-regulation of caspase has been found in COVID-19 patients, and also occurs in patients suffering from diabetes, hypertension, metabolic syndrome, and other conditions. Such up-regulation can be responsible for poor clinical outcomes in patients having such diseases or disorders, as such up-regulation leads to a process called pyroptosis: death and malfunction of immune system cells, particularly of certain types of lymphocytes. An inhibitor of caspase such as a caspase 1 inhibitor, or “pan-caspase” inhibitor (i.e., an inhibitor of multiple caspase types including caspase-1), can be used to treat COVID-19 patients or individuals at risk of infection, by limiting the malfunction of the immune system. A caspase-1 or pan-caspase inhibitor is advantageously administered before or very early in the course of infection by a positive-sense, single-stranded RNA virus such as SARS-CoV, MERS-CoV, or SARS-Cov-2.

Up-regulation of caspase has been found in COVID-19 patients, and also occurs in patients suffering from diabetes, hypertension, metabolic syndrome, and other conditions. Such up-regulation can be responsible for poor clinical outcomes in patients having such diseases or disorders, as such up-regulation leads to a process called pyroptosis: death and malfunction of immune system cells, particularly of certain types of lymphocytes. An inhibitor of caspase such as a caspase 1 inhibitor, or “pan-caspase” inhibitor (i.e., an inhibitor of multiple caspase types including caspase-1), can be used to treat COVID-19 patients or individuals at risk of infection, by limiting the malfunction of the immune system. A caspase-1 or pan-caspase inhibitor is advantageously administered before or very early in the course of infection by a positive-sense, single-stranded RNA virus such as SARS-CoV, MERS-CoV, or SARS-Cov-2.

A biochemical scaffold for regulating mammalian cell function. The biochemical scaffold includes a base liquid medium, a bioenergetic platform and a vibrational platform. The bioenergetic platform includes at least one Krebs cycle modulator and the vibrational platform includes at least one energy signature component, e.g., an herb. The biochemical scaffold is subjected to sequential harmonic oscillation at defined frequency ranges for a defined, predetermined period of time, wherein the energy signature of the energy signature component is imparted to, captured, replicated, and retained by liquid medium, and, when the biochemical scaffold is delivered to and, thus, in communication with biological tissue, the biochemical scaffold induces specific biochemical activities via the resonant transfer of the retained energy signature to the biological tissue and, hence, endogenous cells thereof, the biochemical activities including increased bioavailability of ATP.

A biochemical scaffold for regulating mammalian cell function. The biochemical scaffold includes a base liquid medium, a bioenergetic platform and a vibrational platform. The bioenergetic platform includes at least one Krebs cycle modulator and the vibrational platform includes at least one energy signature component, e.g., an herb. The biochemical scaffold is subjected to sequential harmonic oscillation at defined frequency ranges for a defined, predetermined period of time, wherein the energy signature of the energy signature component is imparted to, captured, replicated, and retained by liquid medium, and, when the biochemical scaffold is delivered to and, thus, in communication with biological tissue, the biochemical scaffold induces specific biochemical activities via the resonant transfer of the retained energy signature to the biological tissue and, hence, endogenous cells thereof, the biochemical activities including increased bioavailability of ATP.

A biochemical scaffold for regulating mammalian cell function. The biochemical scaffold includes a base liquid medium, a bioenergetic platform and a vibrational platform. The bioenergetic platform includes at least one Krebs cycle modulator and the vibrational platform includes at least one energy signature component, e.g., an herb. The biochemical scaffold is subjected to sequential harmonic oscillation at defined frequency ranges for a defined, predetermined period of time, wherein the energy signature of the energy signature component is imparted to, captured, replicated, and retained by liquid medium, and, when the biochemical scaffold is delivered to and, thus, in communication with biological tissue, the biochemical scaffold induces specific biochemical activities via the resonant transfer of the retained energy signature to the biological tissue and, hence, endogenous cells thereof, the biochemical activities including increased bioavailability of ATP.

This invention relates to the use of the combination of 25-hydroxyvitamin D3 (“25-OH D3”) and antioxidants/anti-inflammatories (ascorbic acid vitamin E and canthaxanthin) to make a premix or feed which can ameliorate various problems observed in poultry which have been subject to overfeeding. Feeds containing the 25-OH D3 and antioxidants/anti-inflammatories and premixes are also provided.

This invention relates to the use of the combination of 25-hydroxyvitamin D3 (“25-OH D3”) and antioxidants/anti-inflammatories (ascorbic acid vitamin E and canthaxanthin) to make a premix or feed which can ameliorate various problems observed in poultry which have been subject to overfeeding. Feeds containing the 25-OH D3 and antioxidants/anti-inflammatories and premixes are also provided.

The present invention is directed to combinations of a β-lactamase inhibitor with sulbactam and, optionally, imipenem/cilastatin. The combinations are useful for the treatment of bacterial infections, including infections caused by drug resistant organisms, including multi-drug resistant pathogens. More particularly, the invention relates to a combination of β-lactamase inhibitor compound 1: or a pharmaceutically acceptable salt thereof, with sulbactam, or a pharmaceutically acceptable salt thereof, and, optionally, imipenem/cilastatin, or a pharmaceutically acceptable salt thereof.

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The present invention is directed to combinations of a β-lactamase inhibitor with sulbactam and, optionally, imipenem/cilastatin. The combinations are useful for the treatment of bacterial infections, including infections caused by drug resistant organisms, including multi-drug resistant pathogens. More particularly, the invention relates to a combination of β-lactamase inhibitor compound 1: or a pharmaceutically acceptable salt thereof, with sulbactam, or a pharmaceutically acceptable salt thereof, and, optionally, imipenem/cilastatin, or a pharmaceutically acceptable salt thereof.

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Our invention is a mixture of carboxylic acids: citric acid, succinic acid, fumaric acid and malic acid, and any possible combinations thereof. This product is used orally or also intravenously, in the treatment of patients with chronic renal failure, hyperammonemia or human conditions having negative nitrogen balance. This product is beneficial in decreasing the serum values of urea and serum ammonium, while promoting by transamination of the oxalacetate formed via succinate, fumarate and malate, the biosynthesis of non-essential amino acids; by transamination of the alpha ketoglutarate formed via citrate, it generates glutamic acid and related amino acids such as glutamine. This treatment prevents, preserves and even improves kidney function. In other patients it delays deterioration of renal function and the urgent need for renal replacement therapy. In others, it is used as a supplemental renal replacement treatment to improve the patient's quality of life and improve laboratory parameters.