Extraction and Worth Evaluation of Chitosan from Shrimp and Prawn Co-products

Islam, Amirul; Islam, Md. Sazedul; Zakaria, M.U.M.A.; Paul, Sylvianne; Mamun, Abdullah Al

doi:10.3923/ajft.2020.43.48

Cited by 10 publications

(4 citation statements)

References 14 publications

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“…Because of the presence of amino groups, this material may be employed immediately in solid form for adsorption applications (complexation of cations or organic molecules, electrostatic attraction or ion exchange in acidic media). 202 It may also be employed in liquid form (dissolved in acidic media) to neutralize charges, coagulate-flocculate anionic species (dissolved materials, colloids, and suspended particles), and complex metal ions. 203 Chitosan, in particular, has been identified as a potential cationic adsorbent for removing anions, heavy metals, poisonous organic dyes, aromatic compounds, oil spills, and pharmaceutical residues.…”

Section: Materials For Wastewater Treatmentsmentioning

confidence: 99%

“…It is biocompatible and nontoxic, with chemical tunability and antimicrobial and antioxidant action. , It is used in various applications, including but not limited to medicinal aids, molecular sieves, viscosity builders, heavy metal adsorbents, chelating agents, and desalination membranes. Because of the presence of amino groups, this material may be employed immediately in solid form for adsorption applications (complexation of cations or organic molecules, electrostatic attraction or ion exchange in acidic media) . It may also be employed in liquid form (dissolved in acidic media) to neutralize charges, coagulate-flocculate anionic species (dissolved materials, colloids, and suspended particles), and complex metal ions …”

Section: Use Of Biobased Nms As Potential Materials For Wastewater Tr...mentioning

confidence: 99%

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Progress in the Sustainable Development of Biobased (Nano)materials for Application in Water Treatment Technologies

Saud,

Gupta,

Allal

et al. 2024

ACS Omega

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Section: Materials For Wastewater Treatmentsmentioning

confidence: 99%

Section: Use Of Biobased Nms As Potential Materials For Wastewater Tr...mentioning

confidence: 99%

Progress in the Sustainable Development of Biobased (Nano)materials for Application in Water Treatment Technologies

Saud,

Gupta,

Allal

et al. 2024

ACS Omega

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“…The mixture was then heated at 60 to 70ᵒC for four hours using a magnetic stirrer at 50 revolutions per minute. After being dried, the residue is cooled in a desiccator and then weighed 9 .…”

Section: Deproteinasimentioning

confidence: 99%

Formulation of Hand Sanitizer Gel from Chitosan Shell of Fresh Water Lobster (Cherax Quadricarinatus)

Andreansyah

Ridwanto

2022

Nusantara Scientific Medical Research Journal

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Certain aberrant disorders impair the operation of a portion or the entire body. Infectious diseases can be spread by touching a person's hands or after contact with inanimate objects contaminated with bacteria, which can cause a variety of ailments, including diarrhoea. Using hand sanitizer as the primary deterrent is one of the methods to avoid this transmission. This time, the primary element is a natural substance, such as chitosan. Chitosan can be extracted from the shells of freshwater crayfish and utilized as an antibacterial agent in hand sanitizer formulations. This project intends to produce chitosan from crab shells. Crustacean chitosan can be utilized as an active ingredient in hand sanitizer gel. The production of chitosan begins with the demineralization, deproteination, and deacetylation processes. The resulting chitosan was then used to make hand sanitizer gels with 1, 2, and 3% concentrations. Organoleptic, homogeneity, pH, dispersion, and viscosity tests were then conducted on the gel preparation. The results revealed that the hand sanitizer preparations subjected to organoleptic tests on F1, F2, and F3 did not exhibit any changes in odor, shape, or color; the homogeneity test revealed the absence of coarse grains; the pH obtained on average was within the skin pH range; and the spreadability test revealed that the average was in the range of 5-7 cm, indicating that the formula satisfies the specifications.

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“…Chitosan production using marine-based organisms has been reported in various parts of the world, adopting different treatment strategies. A study on chitosan extraction from shrimp and prawn co-products (Islam et al, 2020 ), shrimp shell waste (Nadia et al, 2019, Abirami et al, 2021, crab shell waste (Tissera et al, 2021), shrimp and crab shell wastes (Premasudha et al, 2017 ), sea prawn (Sneha Paul, 2014), Mussel shell (Abdulkarim et al, 2013), seafood waste (Shruti et al, 2021) suggest the possible utilisation of marine organism as the major source of chitosan. Though marine organisms are an important source for chitosan production, the extraction process is complex, involving difficulties in the collection, availability (seasonal), and high cost.…”

Section: Introductionmentioning

confidence: 99%

Antinociceptive activity of marine derived chitosan coated triphala extract against formalin-induced zebrafish pain model

Namasivayam¹,

Avinash²,

Samrat³

et al. 2023

JEB

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Aim: The present study aimed to evaluate the antinociceptive effect of Triphala extract coated with marine derived chitosan against the formalin-induced adult zebrafish (Danio rerio) model. Methodology: Marine derived chitosan was extracted from Aspergillus niger and the extracted chitosan was coated witha commercial formulation of Triphala by a simple dispersion method. The prepared formulation was administrated to formalin-induced zebra fish model followed by studying changes in various behavioural parameters like swimming pattern, dark-light cycle pattern, antioxidants which include catalase, superoxide dismutase, lipid peroxidase, glutathione S. transferase, glutathione peroxidase and the expression pattern of inflammatory markers genes like tumour necrosis factor (TNF) and induced nitrous oxide synthase (, iNOs). Results: Marine derived chitosan-coated extract reveals notable antinociceptive activity by modulation of behavioural changes and inflammatory marker gene expression. The marine derived chitosan treatment group exhibits normal swimming patterns, dark-light cycle patterns, and morphological parameters as in the control group marine derived chitosan-coated Triphala treatment showed notable changes in the antioxidants. MARINE DERIVED CHITOSAN treatment did not induce any inflammatory signals, confirmed by a less expression pattern of inflammatory marker genes. Interpretation: These findings imply that marine derived chitosan-coated Triphala can be used as an antinociceptive agent through active phyto-principles involved in the molecular mechanism of pain manifestation. Key words: Antinociceptive, Chitosan, Marker genes, Triphala, Zebrafish

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Extraction and Worth Evaluation of Chitosan from Shrimp and Prawn Co-products

Cited by 10 publications

References 14 publications

Progress in the Sustainable Development of Biobased (Nano)materials for Application in Water Treatment Technologies

Progress in the Sustainable Development of Biobased (Nano)materials for Application in Water Treatment Technologies

Formulation of Hand Sanitizer Gel from Chitosan Shell of Fresh Water Lobster (Cherax Quadricarinatus)

Antinociceptive activity of marine derived chitosan coated triphala extract against formalin-induced zebrafish pain model

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