Development and Evaluation of an Eco-Friendly Hand Sanitizer Formulation Valorized from Fruit Peels.
J VermaRashmi MishraDr Avijit MazumderR SinghNour Sh El-GendyPublished in: International journal of biomaterials (2023)
Hand sanitizer usage has proven to be a common and practical method for reducing the spread of infectious diseases which can be caused by many harmful pathogens. There is a need for alcohol-free hand sanitizers because most hand sanitizers on the market are alcohol-based, and regular use of them can damage the skin and can be hazardous. India is the world's largest producer of fruits and one of the major problems after fruit consumption is their peels, causing waste management problems and contributing to the formation of greenhouse gases leading to air pollution and adding to the problem of climate change. Valorization of such wastes into other value-added products and their incorporation into formulations of eco-friendly alcohol-free hand sanitizers would solve these issues, save the environment, benefit the society, and help in achieving the sustainable development goals. Thus, this research focuses on formulating an effective natural alcohol-free hand sanitizer that harnesses the antimicrobial properties of the various types of bioactive components found in fruit peels of pomegranate, sweet lime, and lemon. The peel extracts and the formulated sanitizer proved considerable antimicrobial activity against the pathogenic Escherichia coli and hand microflora. Molecular docking was also applied to examine ligand-protein interaction patterns and predict binding conformers and affinity of the sanitizer phytocompounds towards target proteins in COVID-19, influenza, and pneumonia viruses. The binding affinities and the protein-ligand interactions virtual studies revealed that the sanitizer phytocompounds bind with the amino acids in the target proteins' active sites via hydrogen bonding interactions. As a result, it is possible to formulate a natural, alcohol-free hand sanitizer from fruit peels that is effective against pathogenic germs and viruses using the basic structure of these potential findings.
Keyphrases
- molecular docking
- escherichia coli
- climate change
- air pollution
- mental health
- alcohol consumption
- amino acid
- infectious diseases
- coronavirus disease
- staphylococcus aureus
- sars cov
- binding protein
- public health
- oxidative stress
- pseudomonas aeruginosa
- molecular dynamics simulations
- drug delivery
- risk assessment
- health insurance
- single cell
- chronic obstructive pulmonary disease
- particulate matter
- gram negative
- acute respiratory distress syndrome
- low cost
- multidrug resistant
- global health
- biofilm formation
- dna binding