Bioactive Films Research Articles

Green Packaging Films with Antioxidant Activity Based on Pectin and Camellia sinensis Leaf Extract.

In the packaging materials sector, increasing globalization has created the need for increased efforts to develop consumer protection measures. Consequently, new packaging materials are being sought to replace petroleum-based materials in the future. For this reason, global awareness of the environmental problems associated with the use of synthetic and non-degradable packaging has increased the attention paid to bio-packaging based on natural and biodegradable polymers. The bio-packaging sector is developing innovations to address the sustainability issues facing the food packaging industry. Our research has shown that green matcha extract can be a promising source of antioxidants for the production of bioactive pectin films. This study further confirmed that green matcha extract can be a promising source of antioxidants for the production of bioactive pectin films. The antioxidant activity test showed high activity of films containing matcha extract. The antioxidant activity of films without matcha addition, P, PJ, PC, PJC, was negligible. The addition of matcha to the polymer matrix did not significantly affect the mechanical properties (TS, EB) of the films obtained. The addition of cellulose had the greatest effect on changing the mechanical properties. It caused a twofold increase in the mechanical properties of the obtained packaging films. The addition of matcha significantly improved the barrier properties (for PM films, the WVTR was 3.40 [g/m2d]; for PJM films the WVTR was 1.70 [g/m2d]). The green packaging films showed no toxic effects on the plants (Phacelia tanacetifolia, Salvia hispanica, Brassica napus) and invertebrates (Daphnia pulex, Chaoborus, Chironomus aprilinus) tested. The half-solubility time of the membranes in a solution mimicking gastric acid was also determined. The longest half-dissolution time of the films was about 2 min. Our research has therefore shown that the biodegradable and environmentally safe green packaging films with antioxidant activity that we have developed can be used as edible functional casings in the future, e.g., for sausages and other food products.

Carboxymethyl cellulose – Polyvinyl alcohol bioactive films loaded with green extracted date seed polyphenols for active packaging of Shiitake mushrooms

This study investigated the use of a natural deep eutectic solvent-based polyphenolic extract (DSE) from date fruit seed as a bioactive and functional component for the development of carboxyl methylcellulose-poly(vinyl)alcohol (CMCPVA) packaging films. The impacts on the physicochemical, structural, water barrier and bioactive properties of the CMCPVA films were studied. Different concentrations of DSE (1.5%, 2%, 2.5%, and 3%) incorporated into CMCPVA film increased the total phenolic content (0.08–0.17 mg GAE/mL), DPPH scavenging activity (4.08–5.11 mmol GAE/mL), and ferric ion-reducing antioxidant power (0.82–1.46 μmol TE/mL) of the films. The antibacterial activities against S. aureus, L. monocytogenes, S. typhimurium, and E. coli were also improved. In particular, a 4–5 log reduction was recorded for CMCPVA film incorporated with 3% DSE. Also, the presence of DSE enhanced elongation at break (25.53%–93.23%) and film thickness (0.10–0.19 mm), whereas tensile strength (6.39–1.40 MPa) and Young's modulus (25.89–2.85 MPa) decreased. Furthermore, UV-shielding performance improved, opacity decreased from 2.93 to 0.86, while the water vapor permeability was not significantly affected which ranged from 3.01 to 5.83 (X 10−10 g/m.s.Pa). The application of CMCPVA film incorporated with 3% DSE (CMCPVA_3) as a bioactive film for preserving sliced and whole shiitake mushrooms at refrigeration temperature for 8–12 days was studied. The CMCPVA_3 film preserved the mushrooms' color, browning degree, and texture compared to the cling film-covered samples. There is a potential for the successful application of NADES-based polyphenolic extract in biopolymer films for food preservation.

Green synthesized CeO2 nanoparticles-based chitosan/PVA composite films: Enhanced antimicrobial activities and mechanical properties for edible berry tomato preservation.

The current study is intended to enhance unique bioactive and eco-friendly composite films following a simple solvent-casting approach by incorporating cerium oxide nanoparticles (CeO2 NPs) with a chitosan (CS)/polyvinyl alcohol (PVA) matrix. Antimicrobial activity, preservation impact, mechanisms for the edible berry tomatoes and physicochemical properties of the produced films were tested. FTIR, SEM-EDX, XRD, UV–vis spectroscopy and contact angle were used to characterize the films. Incorporated (3.0 wt%) CeO2 NPs practically developed composite film's thermal stability, structural, mechanical, bioactive, antioxidant, barrier and wettability properties. The tomatoes' look, weight loss and stiffness were better preserved after 25 days of storage at room temperature (25 ± 5 °C) when 3.0 wt% CeO2 NPs films were used instead of the original CS/PVA film. CS and CeO2 NPs have unique physiochemical and antibacterial properties. Food packaging extensively investigates the modified films as antimicrobials and preservatives to increase the shelf life of packaged foods, owing to their ability to inhibit gram-positive bacteria (Bacillus cereus and Staphylococcus aureus), gram-negative bacteria (Klebsiella pneumoniae and Pseudomonas aeruginosa), and filamentous fungi (Bipolaris sorokiniana, Fusarium op., and Alternaria sp.). Our findings indicated that the CeO2/CS/PVA composite films could be used as effective wrapping materials for food preservation.

Fabrication and characterization of bioactive curdlan and sodium alginate films for enhancing the shelf life of Volvariella volvacea

This study aimed to develop bioactive films based on curdlan (CD) and sodium alginate (SA) to enhance the shelf life of the Volvariella volvacea mushroom. A stable nanoemulsion of droplet size of 150.1 ± 5 nm was first formulated using 5% soy protein (Sp) and 10% lavender essential oil (LEO), achieved by ultrasound treatment for 10 min, resulting in small droplet sizes. In parallel, a CD-SA film was prepared by mixing them in a 1:1 ratio. The SpLEO nanoemulsion was then ex situ added to the CD-SA film at varying concentrations (4%, 6%, 8%, and 10%). The resulting bioactive film exhibited desirable properties, including water vapor permeability (1.15 ± 0.05 × 10−10 g m−1 Pa−1 s−1), swelling rate (547%), and tensile strength (10.1 ± 1.3 MPa). Docking and structural analyses suggested that ultrasound treatment enhanced the intermolecular hydrogen bonding, creating a uniform and regular surface and reduced crystallinity. The CD-SA film with ultrasound-treated 8% SpLEO nanoemulsion [i.e., (CD-SA/SpLEO-8)US] showed antibacterial activity against Escherichia coli and Staphylococcus aureus and extended the freshness of straw mushrooms prevention of spoilage during storage. Additionally, the film reduced respiration rate (975 mg CO₂/kg/h at 96 h) and ethylene production (160 ng/kg/s by 96 h) while effectively inhibiting straw mushroom autolysis. This led to a reduction in browning (2.91), total soluble solids (7.5%), weight loss (13.9%), and polyphenol oxidase activity (0.08 ΔOD420/min⋅g), thereby extending the shelf life of the mushrooms to 96 h. These findings highlight the potential of incorporating different molecules using ultrasound treatment to develop innovative edible films for food preservation.

Correction: Khan et al. The Extraction and Impact of Essential Oils on Bioactive Films and Food Preservation, with Emphasis on Antioxidant and Antibacterial Activities—A Review. Foods 2023, 12, 4169

There was an error in the original publication [...]

Introducing Hydrogen Bond Networks in the Self‐Assembly of Chitin Nanocrystals: Strong and Flexible Bioactive Films Containing Natural Polyphenols

Introducing Hydrogen Bond Networks in the Self‐Assembly of Chitin Nanocrystals: Strong and Flexible Bioactive Films Containing Natural Polyphenols

Анализ эффективности применения биоактивного покрытия для обеспечения качества и биобезопасности мяса птицы при хранении

Abstract. Poultry meat is the most common type of raw meat, in demand among consumers, but at the same time a perishable product. The quality and safety of poultry meat during storage can be ensured by using bioactive film coatings. The scientific novelty of the work lies in the receipt of new scientific data on the effect of a bioactive alginate coating with protein hydrolysate on the performance of broiler chicken breast fillet during storage. The purpose of the research is to establish the effectiveness of a bioactive coating based on sodium alginate with protein hydrolysate as an active component during the storage of poultry meat. Research methods. For samples of broiler chicken breast fillet coated with bioactive alginate films and for a control sample without coating, color characteristics, pH, mass fraction of moisture and weight loss during storage, as well as microbiological indicators (total microbial count, and coliforms) were determined. The studies were carried out using standard generally accepted methods. Results. It has been established that coated meat better retains its appearance and color, the moisture content remains at a fairly high level compared to the initial value, and shrinkage is reduced. It was also found that the alginate coating provides microbiological stability of breast fillet for a longer time compared to the control sample: after 7 days of storage, the total microbial number in the control sample was 1.4 106 CFU/g, which is higher than the permissible level according to the requirements of EAEU TR 051/ 2021, while in alginate coating samples this indicator remained within acceptable values. Thus, film coatings based on sodium alginate with the addition of protein hydrolysate as an active component have the potential to ensure the safety and biosafety of poultry meat during storage.

Effect of Lipid-soluble rosemary (Rosmarinus Officinalis L.) extract (carnosic acid) on properties of microcrystalline cellulose/corn starch composite films

The development of biodegradable bioactive films is crucial due to the environmental pollution caused by petroleum-based materials and the food spoilage. Microcrystalline cellulose (MCC)/corn starch (CS) composite films containing lipid-soluble rosemary extract (carnosic acid) (RE) (1 %∼7 %, w/w) were prepared and the effect of RE on the structural, physicochemical, antimicrobial and antioxidant properties of MCC/CS composite films was investigated. The incorporation of lower RE content (1 %) promoted the interactions between film components, thus forming a compact and smooth surface and cross structures. The incorporation of RE changed the long-range order structure of MCC/CS composite film, strengthened the intermolecular interaction between film components, and improved thermal stability. The tensile strength increased from 8.35 MPa to 10.53 MPa and the water vapor permeability decreased from 0.63 to 0.58 g.mm.h-1.m-2.KPa-1. Moreover. Antibacterial (Escherichia coli and Staphylococcus aureus) and antioxidant activity were upsurged as RE contents increased. TOPSIS method indicated the MCC/CS-3 % film and MCC/CS-5 % film were the best films. The above results indicated that an effective use of RE as an enhancer and bacteriostatic agent showed a promising application in food packaging.

Cordia dichotoma fruit mucilage and flaxseed oil nanoemulsion loaded bioactive film: Synergistic approach to enhance antimicrobial properties and bread shelf-life

Recently, non-conventional sources of mucilage have gained significant attention due to their exceptional techno-functional properties and easy availability. This study aimed to utilize Cordia dichotoma fruit mucilage (CDM) for fabricating bioactive films to evaluate the shelf-life of bread. For the development of nanoemulsion, different concentrations of flaxseed oil (1–5% w/w) were employed. Selection was carried out based on droplet size, encapsulation efficiency, and antimicrobial activity. The selected nanoemulsion (CDM-FO1) was subsequently used to develop CDM-based films with the incorporation of carboxymethyl cellulose (CMC) and sodium alginate (SA). Results revealed that the droplet size of the nanoemulsions was significantly increased from 101.25 ± 4.68 nm to 205.15 ± 7.14 nm with increasing flaxseed oil concentration. However, the addition of CMC and SA improved the tensile strength (13.97 ± 0.34 MPa) of the CDM-F11 film compared to control films CDM (6.98 ± 0.68 MPa) and CDM-FC (7.76 ± 1.65 MPa). The CDM-F11 film exhibited excellent barrier properties compared to the control film. The control film showed higher yeast and mold growth, starting at 0.84 ± 0.57 Log CFU/g on the 3rd day and increased to 3.12 ± 0.39 Log CFU/g by the 9th day. In contrast, the CDM-FC film demonstrated better antimicrobial properties, with microbial growth at 0.52 ± 0.39 Log CFU/g on the 3rd day and 2.84 ± 0.38 Log CFU/g on the 9th day. Overall, CDM film loaded with flaxseed oil nanoemulsion can be effectively used as a sustainable food packaging material with enhanced antimicrobial efficiency for bread preservation.

The effect of bioactive film on the shelf life of bread

Relevance. The development of bioactive films is currently relevant due to the need to replace synthetic polymers used in food packaging materials. However, the established positive properties of the films themselves do not always guarantee the predicted effect and do not ensure the preservation of food products during storage. In this regard, for the recommendation of biodegradable films of a specific composition for use as packaging material for a particular type of product, experimental confirmation is required.Methods. The objects of study are samples of wheat bread packaged in alginate films and in polyethylene film as a control. For bread samples after baking and cooling, as well as after 1, and 3 days of storage, sensory characteristics, color characteristics, microbiological indicators, and mass losses were determined.Results. The conducted tests of bread samples revealed the positive effect of the bioactive film based on sodium alginate with the introduction of protein hydrolysate on reducing the growth of bacteria and molds. The research results showed that in alginate films, there is an intensive loss of bread mass — up to 19.27 ± 0.51% (p ≤ 0.05) after 3 days of storage in the film without protein hydrolysate, which is more significant compared to the bread sample in polyethylene film (9.12 ± 0.32%). At the same time, microbiological indicators (total microbial count and mold count) remained more stable in bread samples in alginate films. Thus, the results of microbiological studies confirmed the known data on the antimicrobial properties of protein hydrolysates in the composition of bioactive films. However, when choosing films for bread packaging, it is necessary to consider their vapor permeability to avoid moisture losses during storage..Results. The results of the study showed the need to review the practice of using manure (manure) processing technologies to reduce greenhouse gas emissions

Harnessing pomegranate rind waste to develop novel bioactive packaging films using citric acid crosslinked polyvinyl alcohol (PVA)/starch-based polymer matrix

Harnessing pomegranate rind waste to develop novel bioactive packaging films using citric acid crosslinked polyvinyl alcohol (PVA)/starch-based polymer matrix

Alginate edible films as delivery systems for green tea polyphenols

This study investigated the potential of alginate edible films to act as vehicles for the delivery of polyphenols to the intestinal tract. Sodium alginate (0.5–2% w/v) and green tea extract (GTE, 25–50% w/w) were combined to form films with different microstructural properties via the casting method, where their physical, mechanical and barrier properties were analysed. Release studies into a 50% ethanol (v/v) food simulant and under simulated in vitro digestion were also conducted, and the resulting kinetics of polyphenols release was investigated. Composite alginate films with 25% w/w GTE (E∼2500 MPa; EAB∼14%; k∼0.04) showed significantly enhanced mechanical properties and slower rates of polyphenol release than samples with 50% w/w GTE (E∼6000 MPa; EAB∼6%; k∼0.18). Polyphenols entrapped within the 2% alginate – GTE films were successfully released during digestion (∼54%), demonstrating their bioaccessibility and availability for absorption by the gastrointestinal tract. The bioaccessibility of green tea polyphenols was significantly enhanced by films with good sustained-release effect (2% alginate – GTE, C/C0 = 54.41 ± 0.75%) respect to the free GTE (C/C0 = 33.73 ± 6.57%). These findings highlight the versatility of bioactive alginate edible films and create a blueprint for the design of sustainable active packaging alternatives with dual functionality.

A grafting approach for nisin-chitosan bio-based antibacterial films: preparation and characterization

Nisin is a bacteriocin produced by Gram-positive lactic acid bacterium,Lactococcus lactisand currently recognized in the Generally Recognızed as Safe (GRAS) category due to its non-toxicity. Herein, nisin has been grafted to chitosan structure to obtain natural bio-active films with enhanced antibacterial activity. Grafting was performed using ethyl ester lysine diisocyanate and dimer fatty acid-based diisocyanate (DDI); two different close to fully bio-based diisocyanates and Disuccinimidyl suberate; a homo-bifunctional molecule acting as a crosslinker between amino groups. The grafting process allowed the chemical immobilization of nisin to chitosan structure. Physicochemical characterization studies showed the successful grafting of nisin. The antibacterial activity againstStaphylococcus aureuswas evident for all nisin modified chitosan films and best pronounced when DDI was used as a crosslinker with a maximum zone of inhibition of ∼13 mm. All nisin grafted chitosan films were cytocompatible and the cell viability of L929 fibroblasts were >80% pointing out the non-toxic structure. Considering the results of the presented study, bio-based diisocyanates and homo-bifunctional crosslinkers are effective molecules in synthesis of nisin grafted chitosan structures and the new chitosan based antibacterial biopolymers obtained after nisin modification come forward as promising non-toxic and bioactive candidates to be applied in medical devices, implants, and various food coating products.

Bioactive chitosan films: Integrating antibacterial, antioxidant, and antifungal properties in food packaging

In this work, chitosan was combined with bio-vanillin (BV) and kaolin clay (KC) to create a novel antifungal and biodegradable food packaging film. The chitosan/KC/BV film exhibited an antioxidant capacity of 80 % as measured by DPPH assay, which was significantly higher than that of the chitosan film which has 55.6 %). The film also demonstrated strong antimicrobial activity with a reduction of 90 % in the growth of E. coli and S. aureus compared to the control. Additionally, the chitosan/KC/BV film showed a 75 % reduction in fungal growth compared to chitosan film. Furthermore, the water vapor permeability of the chitosan film was reduced as 5.38 with the addition of KC/BV. The degradation study revealed that the chitosan/KC film degraded by 88 % within 20 days under composting conditions. Additionally, fresh-cut apple slices were used to examine the effectiveness of chitosan/KC/BV film as a packaging material. The fruit's weight loss and browning index showed satisfactory food preservation. Our research suggests that the chitosan/KC/BV film has great potential for use in the food sector due to its strong antioxidant, antimicrobial, and biodegradable properties.

Barley β-glucan bioactive films: Promising eco-friendly materials for wound healing

Mixtures containing β-glucans were extracted from barley, under both mild and high alkaline conditions, to prepare biodegradable films (MA and HA, respectively), as natural dressings with intrinsic therapeutic properties. An in-depth characterization was performed to evaluate the impact of mild and high alkaline conditions on chemical, physicochemical, and biological features for potential use in wound treatments. Both MA and HA films exhibited a good ability to absorb water and simulate wound fluid, which helps maintain optimal tissue hydration. Moreover, their oxygen permeability (147.6 and 16.4 cm3 × μm/m2 × 24 h × Pa × 107, respectively) appeared adequate for the intended application. Biocompatibility tests showed that the films do not harm human dermal fibroblasts. Impressively, they promote cell attachment and growth, with MA having a stronger effect due to its higher β-glucan content. Furthermore, MA films can modulate macrophage behaviour in an inflamed microenvironment, reducing oxidative stress and pro-inflammatory cytokines, while simultaneously increasing levels of anti-inflammatory cytokines. In a scratch test, HA films allowed for faster fibroblast migration within the first 16 h compared to MA.Overall, this study demonstrates that developing β-glucan based films from barley, through a sustainable and cost-effective process, holds great promise for skin applications. These films exhibit significant potential to promote wound healing and modulate inflammation.

A crayfish chitosan-based bioactive film to treat vaginal infections: A sustainable approach

Polymicrobial communities are seen to be a sign of health, but they can turn detrimental when an excess of pathogenic species leads to recurring vaginal infections. This microbiological imbalance may decrease women's fertility, increasing also the risk of infection by Human Papillomavirus (HPV) and/or other sexually transmitted infections (STIs). There is a worldwide need for smart/sustainable solutions to tackle these types of infections. Hereupon, we investigated, as a potential solution, the use of crayfish chitosan-based membrane as a mucoadhesive, antimicrobial, biocompatible and biodegradable material. Chitosan was chemically extracted with a process yield of ca. 63 % and a degree of deacetylation of ca. 65 %. Further chitosan was characterized by FTIR, DSC, XRD and zeta potential. Antimicrobial and antioxidant activities were tested by microbicide concentration and ABTS methods. The extracted chitosan was confirmed to be antioxidant and antimicrobial against Escherichia coli, Candida albicans, Staphylococcus aureus (methicillin resistant and susceptible strains). Vaginal films using chitosan extracted from crayfish shells were produced by solvent casting, and the biological profile was tested in simulated vaginal fluid as a proof of concept. The main data showed that the vaginal films prepared were active against several microorganisms responsible for vaginal infections, demonstrating their potential in the field.

Preparation and characterisation of fish skin collagen–chitosan–cinnamon essential oil composite film

SummaryThe composite film with collagen as the main component has been widely used due to its characteristics of non‐toxicity, environmental protection and health. Fish skin, a by‐product of fish, is an excellent source of collagen. Thus, collagen was extracted from an under‐utilised species, Atlantic cod (Gadus morhua) skin, and the composite film of fish skin collagen–chitosan–cinnamon essential oil was prepared by casting. The effects of the ratio of collagen to chitosan (2:8, 4:6, 5:5, 6:4, 8:2) and the concentration of essential oil (0%, 0.1%, 0.2%, 0.3%, and 0.4% (v/v)) on the composite film were studied. The structures of the composite films were analysed using scanning electron microscopy (SEM), Fourier transforms infrared spectroscopy (FTIR), and X‐ray diffractometry (XRD). The collagen content of Atlantic cod skin is approximately 50.12%, which is significantly higher than that found in basa fish and Nile tilapia (P < 0.05). The content of hydroxyproline was 4.51%. Analyses of tensile strength, elongation at break, water vapor permeability, and water solubility showed Co4Ch6 (Co:Ch = 4:6) had the optimal comprehensive performance, and Co4Ch6–0.2 (Co4Ch6 with 0.2% CEO) had high water resistance in the high‐humidity environment. As the CEO concentration rose, the composite films' infrared absorption bands were enhanced in amplitude, and the XRD peaks were gradually intensified, indicating the internal crystallinity and, thereby, the opacity of the composite films were improved. The bacteriostasis zones Co4Ch6–0.4 against Escherichia coli and Staphylococcus aureus were 2.02 cm and 1.73 cm, respectively. The DPPH radical scavenging rate of Co4Ch6 rose with the increase in CEO concentration, and the DPPH radical scavenging rate of C04Ch6–0.4 was up to 48.56%. Thus, the composite films prepared from fish skin collagen, chitosan, and cinnamon essential oils have outstanding mechanical properties, barrier ability, and antimicrobial activity and are promising for application in food packaging and storage. In addition, the composite films showed a potential antioxidation ability, which might be used as green bioactive films to preserve nutraceutical products.

Comprehensive developmental investigation on simvastatin enriched bioactive film forming spray using the quality by design paradigm: a prospective strategy for improved wound healing

The use of topical antimicrobials in wound healing presents challenges like risk of drug resistance and toxicity to local tissue. Simvastatin (SIM), a lipid-lowering agent which reduces the risk of cardiovascular events, is repurposed for its pleiotropic effect in wound healing. A bioactive bioadhesive polymer-based film forming spray (FFS) formulation of SIM was designed using chitosan, collagen, hyaluronic acid and optimised by employing the DoE approach. Optimised formulation demonstrated moderate viscosity (12.5 ± 0.3 cP), rapid film formation (231 ± 5.6 s), flexibility, tensile strength and sustained drug release (T80 – time for 80% drug release − 9.05 ± 0.7 h). Scanning electron microscopy (SEM) verified uniformly dispersed drug within the composite polymer matrix. SIM FFS demonstrated antimicrobial activity against gram positive and gram negative bacteria. In vivo excision wound model studies in mice affirmed the beneficent role of bioactive polymers and the efficacy of SIM FFS in wound contraction and closure, tissue remodelling and re-epithelization in comparison to standard antimicrobial preparation. Cytokines TNF- alpha, IL-6 were downregulated and IL-10 was upregulated. Biochemical markers; hydroxyproline, hexosamine and histopathology were consistent with wound contraction observed. This is an exploratory effort in repurposing SIM for wound healing in a novel dosage form, underscoring its potential as an alternative to conventional topical antimicrobials.

Biocompatible Co-organic Composite Thin Film Deposited by VHF Plasma-Enhanced Atomic Layer Deposition at a Low Temperature.

Although metal-organic thin films are required for many biorelated applications, traditional deposition methods have proven challenging in preparing these composite materials. Here, a Co-organic composite thin film was prepared by plasma-enhanced atomic layer deposition (PEALD) with cobaltocene (Co(Cp)2) on polydimethylsiloxane (PDMS), using two very high frequency (VHF) NH3 plasmas (60 and 100 MHz), for use as a tissue culture scaffold. VHF PEALD was employed to reduce the temperature and control the thickness and composition. In the result of the VHF PEALD process, the Young's modulus of the Co-organic composite thin film ranged from 82.0 ± 28.6 to 166.0 ± 15.2 MPa, which is similar to the Young's modulus of soft tissues. In addition, the deposited Co ion on the Co-organic composite thin film was released into the cell culture media under a nontoxic level for the biological environment. The proliferation of both L929, the mouse fibroblast cell line, and C2C12, the mouse myoblast cell line, increased to 164.9 ± 23.4% during 7 days of incubation. Here, this novel bioactive Co-organic composite thin film on an elastic PDMS substrate enhanced the proliferation of L929 and C2C12 cell lines, thereby expanding the application range of VHF PEALD in biological fields.

Fabrication of PMMA Borate Bioactive Thin Films for Wound Healing Applications

Fabrication of PMMA Borate Bioactive Thin Films for Wound Healing Applications