Wound repair is a complex and tightly regulated physiological process, involving the activation of various cell types throughout each subsequent step (homeostasis, inflammation, proliferation, and tissue remodeling). Any impairment within the correct sequence of the healing events could lead to chronic wounds, with potential effects on the patience quality of life, and consequent fallouts on the wound care management. Nature itself can be of inspiration for the development of fully biodegradable materials, presenting enhanced bioactive potentialities, and sustainability. Naturally-derived biopolymers are nowadays considered smart materials. They provide a versatile and tunable platform to design the appropriate extracellular matrix able to support tissue regeneration, while contrasting the onset of adverse events. In the past decades, fabrication of bioactive materials based on natural polymers, either of protein derivation or polysaccharide-based, has been extensively exploited to tackle wound-healing related problematics. However, in today's World the exclusive use of such materials is becoming an urgent challenge, to meet the demand of environmentally sustainable technologies to support our future needs, including applications in the fields of healthcare and wound management. In the following, we will briefly introduce the main physico-chemical and biological properties of some protein-based biopolymers and some naturally-derived polysaccharides. Moreover, we will present some of the recent technological processing and green fabrication approaches of novel composite materials based on these biopolymers, with particular attention on their applications in the skin tissue repair field. Lastly, we will highlight promising future perspectives for the development of a new generation of environmentally-friendly, naturally-derived, smart wound dressings.
Sustainable biocomposites have been developed by solvent mixing of poly(lactic acid) (PLA) with a fine powder of cocoa bean shells (CBS) and subsequent solution casting, using different concentrations of CBS. The inclusion of CBS recovers the crystallinity of the initially amorphous PLA films and improves the physical properties of the composites. Young's modulus increases by 80% with 75 wt % CBS inclusion; however, the composites maintain plasticity. The barrier properties of the hydrophobic composites were characterized, and the water vapor permeability is found to be ca. 3.5 × 10 −5 g•m −1 •day −1 •Pa −1 and independent of the CBS content. On the other hand, oxygen permeability is found to depend on the CBS content, with values as low as 10 000 mL•μm•m −2 •day −1 • atm −1 for 50 wt % CBS. Furthermore, CBS confer antioxidant activity to the composites and improve swelling properties rendering the composites biodegradable in aquatic environments, reaching 70% of the maximum biodegradability in just 30 days. The above, in conjunction with the low level of migration measured in food simulant, make the PLA/CBS composites a highly promising material for active food packaging.
Ordinary
textiles are very often malodorous and the origin of cross-infection.
Their microclimate, consisting of moisture, contaminants, and sweat,
provides favorable conditions for microbial growth. Therefore, simple
approaches of surface modification using functional materials are
widely adopted to introduce antibacterial properties. This study reports
a simple and low cost technique that renders cotton fabrics antibacterial.
Manganese (Mn)-doped photocatalytic titanium dioxide (TiO2) nanoparticles of ∼150 nm average diameter have been prepared
by sol gel and applied on textile fabrics using a silicone binder.
The treated fabrics displayed 100% reduction of Staphylococcus
aureus (Gram-positive) and Klebsiella pneumoniae (Gram-negative) populations within 120 min under sunlight, demonstrating
first order of reduction kinetics. Moreover, the functionalized fabrics
demonstrated complete degradation of a methylene blue (MB) dye adsorbed
on their surface, under both UV and visible light irradiation, turning
them white. A similar effect was observed when the treated fabrics
were immersed in a MB dye solution and subsequently irradiated. Here,
the cotton fabrics functionalized with Mn-doped TiO2 nanoparticles
were able to discolour the dissolved MB dye, demonstrating a water
purification effect. In addition, the modified fabrics were resistant
to several laundry cycles. Physical properties like mechanical strength,
color, breathability, and aesthetic of the treated cotton fabrics
remained unchanged. The modified cotton fabrics can be envisioned
as antibacterial, antiodorous, and self-cleaning textiles for sports,
medical uses, uniforms, fashion, home furnishing, and leisure activities.
Finally, the treated textiles were found to be biocompatible.
Novel electrospun fibrous biocomposites have been fabricated, based on two naturally derived materials, namely wool keratin and cinnamon essential oil, and their efficacy as treatment of skin burns caused by...
Alterations of skin homeostasis are widely diffused in our everyday life both due to accidental injuries, such as wounds and burns, and physiological conditions, such as late-stage diabetes, dermatitis, or psoriasis. These events are locally characterized by an intense inflammatory response, a high generation of harmful free radicals, or an impairment in the immune response regulation, which can profoundly change the skin tissue’ repair process, vulnerability, and functionality. Moreover, diabetes diffusion, antibiotic resistance, and abuse of aggressive soaps and disinfectants following the COVID-19 emergency could be causes for the future spreading of skin disorders. In the last years, hydroxycinnamic acids and derivatives have been investigated and applied in several research fields for their anti-oxidant, anti-inflammatory, and anti-bacterial activities. First, in this study, we give an overview of these natural molecules’ current source and applications. Afterwards, we review their potential role as valid alternatives to the current therapies, supporting the management and rebalancing of skin disorders and diseases at different levels. Also, we will introduce the recent advances in the design of biomaterials loaded with these phenolic compounds, specifically suitable for skin disorders treatments. Lastly, we will suggest future perspectives for introducing hydroxycinnamic acids and derivatives in treating skin disorders.
There is a continuous demand for sensitive and efficient cancer drug delivery systems that, when administered at low concentrations, are capable of detecting early-stage pathological conditions and increasing patient survival without adverse side effects. Recent developments in the design of chitosan-based smart drug delivery nanocomplexes are able to respond to the distinctive features of the tumor microenvironment and have provided powerful tools for cancer targeted treatment. Due to its biocompatibility and pH-responsiveness, chitosan has emerged as a promising candidate for the formulation of novel, supramolecular multifunctional materials. This review will first present an overview of the characteristics of solid tumors and their microenvironment, with a particular emphasis on the role of pH as a key factor. In the second part of the review, the stimuli-responsive potential of chitosan-based micelles, current challenges in delivery, and strategies to improve therapeutic efficacy will be discussed.
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