Abstract: Antimicrobial peptides represent a relatively new discovery in the immune system pathway. Recent designs of synthetically engineered antimicrobial peptides have demonstrated increased potency and efficacy/tolerability, enhanced specificity, and reduced toxicity in comparison. One such peptide, XYLENTRA®, has shown/demonstrated significant promise from significant in vitro studies against a large + pathogens. Additionally, extensive animal studies have shown that the XYLENTRA® is an antimicrobial peptide against a large number of pathogens. The XYLENTRA® peptide is also solute resistant. The peptide XYLENTRA® has shown/demonstrated significant antibacterial activity on test organisms Staphylococcus aureus MTCC 96 and Pseudomonas aeruginosa. MTCC741. A substantial decrease in the microbial population level was observed in animals treated with peptide using the protocol described in detail in the application.
Abstract: Antimicrobial peptides represent a relatively new discovery in the immune system pathway. Recent designs of synthetically engineered antimicrobial peptides have demonstrated increased potency and efficacy/tolerability, enhanced specificity, and reduced toxicity in comparison. One such peptide, XYLENTRA, has shown/demonstrated significant promise from significant in vitro studies against a large number of pathogens. Additionally, extensive animal studies have shown that the XYLENTRA is an antimicrobial peptide against a large number of pathogens. The XYLENTRA is also solute resistant. The test compound Xylentra® has shown/demonstrated significant antibacterial activity on test organisms Staphylococcus aureus MTCC 96 and Pseudomonas aeruginosa. MTCC741.