Abstract: Disclosed herein are methods of manufacturing injectable microgel scaffolds, including methods of producing, purifying and concentrating microgel particles therein. The microgel scaffolds of the present disclosure are useful for a wide range of applications, such as stabilizing an implanted medical device in an implant site in a subject. The microgel scaffolds are fluidic during application and annealed or crosslinked after application to the implant site in the subject. The microgel scaffolds may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Disclosed herein are systems for promoting healing of a wound or surgical incision at a medical device site (e.g., implanted medical device) in a subject, by administering a microporous gel to the medical implant site. Also disclosed are systems for the treatment and prevention of infection at a medical implant site in a subject, by administering a microporous gel to the medical implant site. The microporous gel may be fluidic during application and annealed or crosslinked after application. The microporous gels may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Disclosed herein are methods of manufacturing injectable microgel scaffolds, including methods of producing, purifying and concentrating microgel particles therein. The microgel scaffolds of the present disclosure are useful for a wide range of applications, such as stabilizing an implanted medical device in an implant site in a subject. The microgel scaffolds are fluidic during application and annealed or crosslinked after application to the implant site in the subject. The microgel scaffolds may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Disclosed herein are systems for promoting healing of a wound or surgical incision at a medical device site (e.g., implanted medical device) in a subject, by administering a microporous gel to the medical implant site. Also disclosed are systems for the treatment and prevention of infection at a medical implant site in a subject, by administering a microporous gel to the medical implant site. The microporous gel may be fluidic during application and annealed or crosslinked after application. The microporous gels may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Provided are methods for the treatment and prevention of fibrosis at a medical implant site in a subject, by administering a microporous gel to the medical implant site. Also provided are methods of preventing or treating an infection at the medical implant site in a subject. Also disclosed herein are methods for promoting healing of a wound or surgical incision at a medical implant site in a subject, by administering a microporous gel to the medical implant site. The microporous gel may be fluidic during application and annealed or crosslinked after application. The microporous gels may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Disclosed herein are systems for promoting healing of a wound or surgical incision at a medical device site (e.g., implanted medical device) in a subject, by administering a microporous gel to the medical implant site. Also disclosed are systems for the treatment and prevention of infection at a medical implant site in a subject, by administering a microporous gel to the medical implant site. The microporous gel may be fluidic during application and annealed or crosslinked after application. The microporous gels may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Disclosed herein are methods of manufacturing injectable microgel scaffolds, including methods of producing, purifying and concentrating microgel particles therein. The microgel scaffolds of the present disclosure are useful for a wide range of applications, such as stabilizing an implanted medical device in an implant site in a subject. The microgel scaffolds are fluidic during application and annealed or crosslinked after application to the implant site in the subject. The microgel scaffolds may contain various therapeutic agents, including antibiotics and analgesics, throughout the gel.

Abstract: Compositions and methods are disclosed that relate to aminoglycoside-linker-peptide (P-L-A) conjugates having unexpectedly advantageous dual-function bactericidal properties. Encompassed compounds are shown to be capable of energy independent bacterial plasma membrane disruption and to exhibit potent toxicity to bacteria including antibiotic-resistant bacteria. These and related embodiments will find uses for treating bacterial infections including overcoming antibiotic resistance.