Formulation and characterization of antibiotic drug loaded aquasome for the topical application.

Aim: This study aimed to develop a topical antibiotic drug delivery system using aquasomes for enhanced treatment of skin and soft tissue infections (SSTIs). Materials & methods: Cephalothin was loaded into aquasomes using a multi-step process and optimized using design of experiment. The aquasomes were characterized for FT-IR, SEM and zeta potential analysis. Entrapment efficacy, In vitro drug release studies, antibacterial assays and stability study was performed to evaluate the efficacy of the formulated aquasomes. Results & conclusion: The formulated cephalothin-loaded aquasomes exhibited stable properties, controlled drug release and significant antibacterial activity against bacteria. This proves that the developed aquasome-based delivery system has the potential for sustained treatment of SSTIs.

Cephalothin is a medicine that helps fight bacteria, but it doesn't work well on the skin because it does not come in a gel form. We created a special way, called a magic vehicle, to help the medicine reach the skin better. Infections on the skin and in soft tissues, caused by germs. We found that our new way of giving the medicine is small, strong and fights germs very well. This could be a great way to treat skin infections and help people feel better.

Aquasomes nanoformulation for controlled release of drug and improved effectiveness against bacterial infections.

Aim: The study aimed to develop and evaluate an aquasome drug-delivery system for controlled drug delivery of cefprozil monohydrate. Materials & methods: Aquasomes were prepared by the spinal method with a calcium phosphate core, sugar-coated using cellobiose and drug-loaded by adsorption. The formulations were characterized for size, morphology and drug release. An antibacterial study was conducted for Gram-positive and -negative bacteria. Results: It showed particle size of 2791.9 nm, zeta potential of -0.3 mV with good stability, and 99.08% of drug loading and drug release were controlled and prolonged, achieving 56% within 8 h and possessing potential for 100% release beyond 12 h. Conclusion: An aquasome drug-delivery system was developed for novel controlled drug delivery for pharmaceutical antibiotic therapeutics.

We made tiny sponge-like balls carrying a medicine called cefprozil monohydrate. We wanted to determine whether these sponge-like balls could effectively carry medicine, release it inside the body when someone is sick and fight germs. We prove that these sponge-like balls release the medicine slowly for hours. These sponge-like balls could potentially be used to deliver medication more effectively to people better to get rid of skin infections.