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61,005 resultsShowing papers similar to Bacterial Nanocellulose toward Green Cosmetics: Recent Progresses and Challenges
ClearApplications of regenerated bacterial cellulose: a review
This review examines bacterial cellulose as a sustainable alternative to synthetic polymers that contribute to microplastic pollution. Bacterial cellulose is biodegradable, renewable, and has strong mechanical properties, making it suitable for packaging, textiles, and biomedical applications. The study highlights recent advances in processing techniques that could make bacterial cellulose more commercially viable as a replacement for plastics in everyday products.
Applicability of bacterial cellulose in cosmetics – bibliometric review
Researchers reviewed scientific literature on bacterial cellulose — a natural material produced by bacteria — and its potential uses in cosmetics as a sustainable alternative to synthetic ingredients. Studies show it shows strong promise for use in face masks for delivering active compounds and improving skin hydration, making it a candidate to replace some petroleum-based cosmetic materials.
Biotechnology in Food Packaging Using Bacterial Cellulose
This review explores bacterial cellulose as a biodegradable, biocompatible alternative to conventional plastic food packaging, which contributes to micro- and nanoplastic pollution that threatens both the environment and human health. While bacterial cellulose shows strong potential due to its mechanical strength and food preservation abilities, scaling up production remains a challenge due to higher costs and manufacturing difficulties.
Nanocellulose as Sustainable Bio-Nanomaterial for Packaging and Biomedical Applications
This review examines the potential of nanocellulose, a material derived from plant fibers, as a sustainable alternative to conventional plastics in packaging and biomedical applications. Researchers found that nanocellulose can provide effective moisture and gas barriers when used in paper-based packaging, reducing the need for plastic coatings. The study highlights nanocellulose as a biodegradable, renewable material that could help address both plastic waste and food preservation challenges.
Nanocelluloses review: Preparation, biological properties, safety, and applications in the food field
This review examined nanocelluloses — including cellulose nanofibrils, nanocrystals, and bacterial cellulose — as sustainable food ingredients and packaging materials, highlighting their use as edible coatings, emulsion stabilizers, fat substitutes, and prebiotics while noting that safety assessments and regulatory frameworks still require development.
Bacterial Cellulose—A Remarkable Polymer as a Source for Biomaterials Tailoring
This review explores bacterial cellulose, a natural polymer produced by non-pathogenic bacteria, as a versatile and eco-friendly biomaterial for medical and pharmaceutical applications. Researchers highlight its unique properties including high purity, strength, and biocompatibility, which make it suitable for wound dressings, drug delivery, and tissue engineering. The material offers a sustainable alternative to synthetic polymers, aligning with growing efforts to reduce plastic-based materials in healthcare.
Flexible, high-strength, and porous nano-nano composites based on bacterial cellulose for wearable electronics: a review
This review examined bacterial cellulose-based nano-nano composites for flexible wearable electronics, finding that bacterial cellulose's high purity, biodegradability, and three-dimensional nano-networked structure make it a promising sustainable alternative to petroleum-based polymer substrates.
Effect of bacterial nanocellulose and plant-containing facial serum on hyperpigmentation in in-vitro conditions
Researchers investigated herbal extract formulations combined with bacterial nanocellulose and bioactive compounds for treating skin hyperpigmentation. The study tested ingredients including licorice root, green tea, and niacinamide for their ability to inhibit tyrosinase and reduce melanin production. While not directly about microplastics, the research explores nanocellulose-based delivery systems that represent alternatives to synthetic polymer materials in cosmetic applications.
Bacterial cellulose: A smart biomaterial for biomedical applications
This review covers bacterial cellulose, a natural material produced by bacteria that has unique properties like high purity, biodegradability, and excellent water retention. It shows promise for medical uses including wound healing, drug delivery, and tissue engineering as a sustainable alternative to synthetic materials. As concerns grow about microplastic contamination from synthetic polymers in medical products, biodegradable alternatives like bacterial cellulose become increasingly relevant.
In Situ Synthesis of Plasticized Bacterial Cellulose Films for Daily Packaging Using Biobased Plasticizers
Researchers synthesized plasticized bacterial cellulose films in situ and characterized their mechanical, optical, and barrier properties for daily packaging applications, finding the bio-based materials offered competitive performance with lower environmental impact than petroleum-based alternatives.
Bacterial cellulose biopolymers: The sustainable solution to water-polluting microplastics
Researchers developed bacterial cellulose (BC) biopolymer filters as a sustainable alternative to petroleum-based polymer filters used in wastewater treatment plant microplastic removal. BC filters showed high MP capture efficiency and are biodegradable, addressing both microplastic pollution and the environmental costs of conventional synthetic filter maintenance.
Application Possibilities of Sustainable Nanostructured Silica-Based Materials in Cosmetics
This review explores the application of sustainable nanostructured silica-based materials in the cosmetics industry, emphasizing green synthesis methods that use plant-derived raw materials. The study highlights how these biocompatible materials could serve as alternatives to synthetic microplastic ingredients currently used in cosmetic products, potentially reducing microplastic pollution from personal care products.
Renewable cellulosic nanocomposites for food packaging to avoid fossil fuel plastic pollution: a review
Researchers reviewed how cellulose nanoparticles extracted from plant biomass can replace petroleum-based plastics in food packaging, finding that adding just 1–5% cellulose nanoparticles significantly improves strength, reduces oxygen and water vapor permeability, and keeps packaging biodegradable. The review positions cellulose nanocomposites as a scalable, eco-friendly alternative to fossil-fuel plastics that contribute to microplastic pollution.
Citric acid cross-linked regenerated bacterial cellulose as biodegradable and biocompatible film for food packaging
Researchers developed biodegradable packaging films from regenerated bacterial cellulose cross-linked with citric acid. The films showed good mechanical strength, biocompatibility, and biodegradability. Bacterial cellulose-based packaging could serve as a sustainable alternative to petroleum-based plastic films and reduce microplastic generation from food packaging.
Nanocellulose Bio-Based Composites for Food Packaging
This review explores the use of nanocellulose-based bio-composites as sustainable alternatives to synthetic plastic packaging in the food industry. Researchers found that nanocellulose materials offer improved mechanical strength, barrier properties, and biodegradability compared to conventional plastics. The study highlights how these plant-derived materials could help reduce plastic packaging waste while maintaining food quality and safety standards.
From Nature to Lab: Sustainable Bacterial Cellulose Production and Modification with Synthetic Biology
This review explores how bacterial cellulose, a versatile biopolymer produced by Komagataeibacter and Novacetimonas species, can be sustainably manufactured using agricultural and food waste as growth substrates. Researchers highlight advances in genetic engineering and synthetic biology that enable the production of novel functionalized biomaterials, positioning bacterial cellulose as a green alternative with applications spanning medicine, food packaging, and electronics.
Microplastics in Cosmetics: Open Questions and Sustainable Opportunities
This review examines the role of microplastics in cosmetic products and the industry's transition toward sustainable alternatives as regulations tighten worldwide. Researchers surveyed the properties that make plastic particles useful in cosmetics, such as texture and appearance enhancement, alongside their environmental drawbacks. The study provides an overview of emerging bio-based and biodegradable replacement materials that could help the personal care industry eliminate microplastics from formulations.
Recent Advances in Cellulose Nanofiber Modification and Characterization and Cellulose Nanofiber-Based Films for Eco-Friendly Active Food Packaging
This review covers advances in cellulose nanofibers, a plant-based material being developed as an eco-friendly alternative to plastic food packaging. These nanofibers are biodegradable, can be extracted from agricultural waste, and can be enhanced with antimicrobial or barrier properties. Replacing conventional plastic packaging with bio-based films like these could help reduce the microplastic contamination that enters the food supply.
New perspectives in fashion sustainability through the use of bacterial cellulose
This review examines how bacterial cellulose can open new sustainability pathways for the fashion industry, exploring its potential as a bio-based material to reduce the sector's high environmental impact from accelerating production cycles and increasing textile waste.
Free standing nanocellulose films – fabrication methods, surface engineering and recyclability
This review examines fabrication methods, surface engineering approaches, and recyclability of free-standing nanocellulose films, highlighting their potential as sustainable alternatives to synthetic plastic films across various applications.
Innovative Approaches to an Eco-Friendly Cosmetic Industry: A Review of Sustainable Ingredients
This review examines sustainable alternatives to conventional cosmetic ingredients, including plant-based, microbial, and recycled materials that could replace synthetic and potentially harmful components. While not directly about microplastics, cosmetic microbeads have been a significant source of microplastic pollution, and the push for eco-friendly ingredients helps reduce plastic particles entering waterways. The shift toward sustainable cosmetics is part of broader efforts to decrease human exposure to synthetic microparticles.
Biopolymers as renewable polymeric materials for sustainable development - an overview
This review examines biopolymers as renewable polymer materials for sustainable development, covering starch-, cellulose-, bacteria-, soy-, and natural polyester-based biopolymers, their applications, and their potential to replace conventional synthetic plastics derived from fossil resources.
Microplastics (MPs) in Cosmetics: A Review on Their Presence in Personal-Care, Cosmetic, and Cleaning Products (PCCPs) and Sustainable Alternatives from Biobased and Biodegradable Polymers
This review documents how microplastics are widely used in personal care products, cosmetics, and cleaning supplies as exfoliants, film formers, and texture enhancers. These products wash down the drain and contribute to environmental microplastic pollution, which can ultimately cycle back to humans through contaminated water and food.
Ecological packaging: Creating sustainable solutions with all-natural biodegradable cellulose materials
Researchers developed a pure cellulose food packaging material by combining bacterial cellulose and ethyl cellulose — both natural, biodegradable materials — into a strong, water-resistant film that degrades naturally and avoids the microplastic pollution associated with conventional single-use plastic packaging. The material's mechanical strength, water resistance, and recyclability position it as a practical plastic replacement for food packaging.