Natural β-chitin-protein complex film obtained from waste razor shells for transdermal capsaicin carrier

Aylanç, Volkan; Ertosun, Seymanur; Akyüz, Lalehan; Bilican, Behlül Koç; Gokdag, Semih; Bilican, İsmail; Çakmak, Yavuz Selim; Yılmaz, Bahar; Kaya, Murat

doi:10.1016/j.ijbiomac.2020.03.232

Cited by 17 publications

(4 citation statements)

References 61 publications

(69 reference statements)

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“…Hydrophobicity is a desirable feature for many industrial applications. The dorsal dark area of the natural chitin film herein shows higher hydrophobicity than chitin film structures obtained from other organisms (Aylanc et al, 2020;Kaya et al, 2018;Kaya, Sargin et al, 2017). In view of these results, natural chitin film may be used for industrial applications requiring hydrophobic surfaces.…”

Section: Water Contact Anglementioning

confidence: 68%

Production of natural chitin film from pupal shell of moth: Fabrication of plasmonic surfaces for SERS-based sensing applications

Chen

Pekdemir

Bilican

et al. 2021

Carbohydrate Polymers

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Section: Water Contact Anglementioning

confidence: 68%

Production of natural chitin film from pupal shell of moth: Fabrication of plasmonic surfaces for SERS-based sensing applications

Chen

Pekdemir

Bilican

et al. 2021

Carbohydrate Polymers

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“…It is said that a degradation temperature in the window 250 to 350°C is a distinct characteristic of chitin in β-form. 29 The third stage occurred in the range of 400 to 600°C is attributed to thermal degradation of pyranose ring and the decomposition of the residual carbon. DSC gave similar thermal profiles for β-chitin, PANI and β-chitin-g-PANI as that of TGA.…”

Section: Resultsmentioning

confidence: 99%

Revamping squid gladii to biodegradable composites: In situ grafting of polyaniline to β-chitin and their antibacterial activity

Balitaan

Martin

Santiago

2020

Journal of Bioactive and Compatible Polymers

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The global health concern on wound care is becoming more challenging with the emerging prevalence of inexorable antibiotic resistance. Amidst this crisis, various material innovations have been made to combat this dilemma. Herein, squid pens, which are regarded as discards in the seafood industry, were biorefined into β-chitin-graft-polyaniline (β-chitin-g-PANI) composites for possible wound dressing development. β-chitin was first chemically extracted from gladii, and was then grafted with PANI via in situ chemical oxidative polymerization of various concentrations of aniline, to produce the β-chitin-g-PANI composites. Supporting data from FTIR, UV-Vis, SEM, TGA, and DSC suggest that β-chitin was successfully grafted with PANI. Moreover, improved conductivity and in vitro degradation of the composites were observed as compared to β-chitin and PANI alone, respectively. Zones of inhibition observed from agar diffusion method suggest that the synthesized composites have antibacterial activity against E. coli and S. aureus. The resulting physicochemical and biological properties of integrating conducting PANI to β-chitin substantiated and rendered the β-chitin-g-PANI composites desirable candidates for the development wound care products.

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“…The loss that occurs in the first step can be attributed to the water molecules during evaporation in the chitin and chitosan molecules, and the loss that occurs in the second step can be attributed to the degradation of chitin and chitosan (Ofem, 2015). The first loss of the chitin and chitosan from different mollusk shells ranged from 5% to 9.61%, whereas the second mass loss ranged from 51.9% to 63.5% (Aylanc et al, 2020;Cabrera-Barjas et al, 2021;Huang & Tsai, 2020;Ianiro et al, 2014;Kaya et al, 2016;Mohan et al, 2019;Varma et al 2021). The maximum temperatures (DTG max) for the degradation of chitin and chitosan from several mollusk shells ranged from 380 to 444 • C (Mohan et al, 2019;Rajathy et al, 2021).…”

Section: Thermogravimetric Analysismentioning

confidence: 99%

“…Meanwhile, the structural and functional properties of chitin and its derivatives from various mollusk shells have been reported earlier (Akpan et al, 2018;Aylanc et al, 2020;Cabrera-Barjas et al, 2021;Hazeena et al, 2022;Mohan et al, 2019;Nouj et al, 2022). However, no comprehensive review were focused on the edible mollusk shell waste derived chitin and chitosan.…”

Section: Introductionmentioning

confidence: 99%

β‐Chitin and chitosan from waste shells of edible mollusks as a functional ingredient

Karthick Rajan,

Mohan,

Rajarajeswaran

et al. 2023

Food Frontiers

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The marine food‐processing industries were producing large quantities of shell wastes as a discard. Currently, this waste material was underutilized and leads to the landfill as a significant environmental issue. The outer shells or exoskeletons of mollusks serve as the best source of chitin. Three different allomorphs of chitin (γ, β, and γ) were extracted from different species of crustaceans, mollusks, and fungi. β‐Allomorphs predominantly exist in the shells of mollusks. β‐Chitin and its deacetylated product chitosan has been utilized for its special characteristic features, including biocompatibility, environmental friendly, and nontoxic properties. The extraction of β‐chitin and chitosan from the mollusk shell waste were evaluated in this work. Hence, this review aims to explore edible mollusk shell waste sources and its suitable extraction techniques, characterizations, and functional properties of mollusk‐based β‐chitin and chitosan. Further, the genetic pathway of synthesizing mollusk chitin was discussed. The entire life cycle assessment with techno‐economic aspects were extrapolated to study the bottlenecks and tangible solution for the industrial upscaling of obtaining β‐chitin and chitosan from the edible mollusk shell waste have been reviewed herein.

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Natural β-chitin-protein complex film obtained from waste razor shells for transdermal capsaicin carrier

Cited by 17 publications

References 61 publications

Production of natural chitin film from pupal shell of moth: Fabrication of plasmonic surfaces for SERS-based sensing applications

Production of natural chitin film from pupal shell of moth: Fabrication of plasmonic surfaces for SERS-based sensing applications

Revamping squid gladii to biodegradable composites: In situ grafting of polyaniline to β-chitin and their antibacterial activity

β‐Chitin and chitosan from waste shells of edible mollusks as a functional ingredient

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