Volume 21, number 2
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Chandrasekaran Y, Jagadeeswari S, Dakshinamoorthi R. M, Rushika S. D, Sharma B. K. Scaling New Depths: Innovations in Fish Collagen Extraction and Biomedical Frontiers Explored. Biotech Res Asia 2024;21(2).
Manuscript received on : 18-03-2024
Manuscript accepted on : 13-06-2024
Published online on:  01-07-2024

Plagiarism Check: Yes

Reviewed by: Dr. Vishal Patel

Second Review by: Dr. Durgeshranjan Kar

Final Approval by: Dr. Wagih Ghannam

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Scaling New Depths: Innovations in Fish Collagen Extraction and Biomedical Frontiers Explored

Yuvashree Chandrasekaran1 , Jagadeeswari S2 , Balakumaran Manickam Dakshinamoorthi1 , Rushika Sri D1 and Kiran Sharma B1*

1Department of Biotechnology, Dwaraka Doss Goverdhan Doss Vaishnav College (Autonomous), University of Madras, Chennai, Tamil Nadu, India

2Department of Microbiology, Dwaraka Doss Goverdhan Doss Vaishnav College (Autonomous), University of Madras, Chennai, Tamil Nadu, India

Corresponding Author E-mail: kiransharma@dgvaishnavcollege.edu.in

DOI : http://dx.doi.org/10.13005/bbra/3240

ABSTRACT: Collagen is a fibrous protein commonly found in the bodies of human and other animals. It is referred to be the most abundant protein which comprises 30% of animal’s overall protein. It is broadly used in diverse applications such as food, pharmaceutical, biomaterials, cosmetics, and biomedical industries. Fish waste is one of the cost-effective sources of collagen. The increasing adoption of marine-based and freshwater-based collagen is driven by their distinctive properties, which include advantages over mammalian-based collagen. These advantages encompass the absence of disease transmission risks, freedom from religious restrictions, cost-effective production, biocompatibility, and enhanced absorption within the human biological system. This review provides an overview of recent research regarding the extraction of collagen from marine and freshwater sources, with a specific focus on fish by-products. It encompasses subjects including the primary sources of fish collagen, pretreatment of fish materials, extraction techniques, collagen characterization, and its wide-ranging applications. More particularly, the study focuses at the procedures used to extract fish collagen, with an emphasis on isolating acid-soluble collagen (ASC) and pepsin-soluble collagen (PSC). Likewise, the fish derived collagen’s application in biomedical engineering such as drug delivery systems, tissue engineering, therapeutic applications and cosmetic industry is summarized.

KEYWORDS: biomedical applications; collagen; characterization; extraction techniques; Fish waste

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Chandrasekaran Y, Jagadeeswari S, Dakshinamoorthi R. M, Rushika S. D, Sharma B. K. Scaling New Depths: Innovations in Fish Collagen Extraction and Biomedical Frontiers Explored. Biotech Res Asia 2024;21(2).

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Chandrasekaran Y, Jagadeeswari S, Dakshinamoorthi R. M, Rushika S. D, Sharma B. K. Scaling New Depths: Innovations in Fish Collagen Extraction and Biomedical Frontiers Explored. Biotech Res Asia 2024;21(2). Available from: https://bit.ly/4cGF7mj

Introduction

Collagen, a naturally occurring structural protein in mammals, accounts for around 30% of the total protein composition inside an animal’s connective tissues.1,2 Collagen provides structural support and promotes tissue growth by utilizing mechanochemical signalling mechanisms that preserve tissue tensile resilience, firmness and elasticity. It is vital for functions such as movement, regeneration, and overall structural support.3

Collagen’s distinctive function as a wound repairing substance involves safeguarding and expediting the regeneration process by hindering the absorption and proliferation of pathogens, especially harmful microorganisms.4 Transforming the waste materials of fish processing like scales, skin, and muscles into collagen can help address the environmental and public health concerns linked to how seafood processors dispose of these materials. This will automatically lead to a reduction in improper waste dumping in landfills.5

Furthermore, due to the large daily consumption of fish and the yearly creation of approximately 20 million tons of by-products from fish processing, which include components like the head, fins, skin. These materials are often disposed of as ‘trash’.6,7 To address the growing demand for collagen, numerous researchers have been exploring alternative collagen sources, with a particular emphasis on marine sources, including fish by-products. Hence, further research is in progress to investigate various extraction procedures and characterization process of collagen obtained from fish processing by-products.1,8

Some of the fishes include Sardinella longiceps, Catla Catla, Cirrhinus mrigala, Nile tilapia (Orechromis niloticus) and silver catfish (Pangasius sp.).5,9,1,10 Fish collagen offers numerous benefits, including its exceptional safety profile (free from pig-related foot-and-mouth disease, bovine spongiform encephalopathy in cattle, and cow-transmissible spongiform encephalopathy), excellent absorbability, absence of religious restrictions, cost-effectiveness, and biocompatibility. These attributes position fish collagen as a versatile and highly applicable resource in diverse domains such as health foods, cosmetics, and biomedicine.11,12,13,14,15

The analysis of purified collagen’s amino acid composition indicated the existence of 18 different amino acids, including the relatively uncommon tryptophan, in collagen obtained from carp fish scales.16 The extracellular matrix is typically described as the noncellular part of tissue, offering crucial biochemical and structural support to its cellular components.17 Collagen, considered through the lens of materials science, stands out as an exceptionally prevalent polymeric biomaterial extensively employed across diverse domains, spanning from the realms of nutrition and beauty products to pharmaceuticals.18,19

Type I collagen, the most common collagen type, acts as a great foundational component for cosmetics and biomaterials. It is generally derived from the dermal tissues of bovine or pig sources.20 Collagen exhibits varying amino-acid compositions based on its source, resulting in the identification of 28 distinct collagen types to date. The prevalent types are categorized as types I to V and distinguished by their macromolecular structures.

Type I collagen is prevalent in several connective tissues, including these. Type I collagen has a triple-helix structure made of two α1 chains and one α2 chain Within this structure, a linkage between two α chains is termed a β chain, forming a chain dimer, while a linkage among three chains is referred to as a γ chain, forming a trimer.5,21,22,23,2

Marine collagen offers a sustainable solution that is safer than mammalian collagen due to the absence of exposure to zoonotic diseases. Additionally, the utilization of discarded fish scales from food processing to extract type I collagen presents an appealing opportunity for efficiently recycling organic resources and reducing waste. Nevertheless, the majority of techniques for extracting type I collagen from fish scales rely on enzymatic processes.24,25

Collagen fibres play a crucial role in vertebrate tissues by not only preventing premature mechanical issues but also aiding in the storage, dispersion, and transmission of energy originating from musculoskeletal or externally applied forces. These fibers are crucial in providing structural support to every organ inside the body maintaining the appropriate firmness, elasticity, and strength required for optimal movement, tissue renewal, and the healing process, all of which are achieved through mechanochemical transduction processes.26

Exploring the full potential for utilizing waste generated during fish processing is crucial. By embracing reuse practices, we can not only reduce costs but also enhance product nutritional value while minimizing waste emissions and environmental pollution.4 Research has indicated that fish scales are rich in protein, comprising approximately 70% of their composition, and primarily consist of collagen and keratin, resulting in an important resource with substantial biological significance.27 Exploring the potential of fish scales presents a promising avenue for generating value-added products and contributing to environmental conservation. Current study focuses on obtaining collagen from the scales of freshwater fish.28

The aim of this review is to present a contemporary examination of collagen production from fish scales, with a particular emphasis on the methods employed for extraction and characterization.

Primary Sources of Fish Collagen

Fish collagen may be derived from a variety of fish by-products, such as fish bones, scales, and skins. These by-products are extensively eaten in many regions of the world, but they also generate a substantial quantity of trash, accounting for 50% to 70% of the original raw materials generated by fish shops and processing plants.29 The fish derived sources of collagen is given in Figure 1

Fish Scales

A substantial quantity of waste is generated in the fish processing industry, with fish scales being a significant contributor. Recent research has indicated that collagen extracted from fish scales exhibits characteristics consistent with Type I collagen, comprising two α1 chains and α2 chain.30,31,32 Fish scale-derived collagen exhibits effective water absorption at a rate of 13.3% and strong water retention capabilities at 15%, rendering it well-suitable for medical and therapeutic uses.31 However, since fish scales contain significant amount of calcium, ranging from 16% to 59% of their mineral composition by weight, decalcification must be carried out using ethylenediaminetetraacetic acid (EDTA).20

Fish Skin

Fish skin typically contains around 70% type I collagen, with variations depending on the species, age and seasonal conditions.16 Collagen derived from fish skin showcases impressive water retention capabilities, absorbing approximately 6% of its weight when exposed to 63% humidity for 24 hours. Additionally, it poses no irritant risks, making it a suitable choice for use in dermal applications.33 Aside from the traditional methods of collagen extraction such as Acid Soluble Collagen (ASC) and Pepsin Soluble Collagen (PSC), a different approach for collagen extraction from the skin of fish involves utilizing carbon-dioxide acidified water, a technique previously employed to isolate collagen from Atlantic cod (Gadus morhua). Collagen extracted with acidifies water exhibited a total proline-like amino acid content of 151 per 1000 residues, and the extraction yield was 13.8%,34 while Acid Soluble Collagen (ASC) and Pepsin Soluble Collagen (PSC) method being the classical method.35

Fish Bones

The collagen derived from fish bones resembles characteristics of type I collagen, comprising two α1 chains and α2 chain.28,36 Collagen derived from bones of tilapia, catfish, pomfret, and mackerel requires a greater extraction temperature (16.6 ◦C–19.03 ◦C) and a shorter recovery duration (73.16 hours) in comparison to collagen derived from scales and skin of fish. Moreover, it exhibits lower extraction yields (0.64%) when contrasted with collagen obtained from fish skin.37 In an earlier study, the maximum collagen output attained from fish bones using a 1% pepsin solution was 16.13 mg/mL. Desalting is recommended as a crucial step in bone collagen extraction because of the elevated hydroxyapatite and calcium levels, both of which are eliminated during pretreatment using EDTA or HCl. Nevertheless, it’s worth noting that HCl usage can lead to collagen degradation.38

Fish Cartilage

Collagen from fish cartilage is mostly made up of type II collagen, with smaller amounts of other collagen types like type IX and type XI. For example, type IX and type XI collagen variants have been found in the nasal cartilage of Hoki (Macruronus novaezelandiae),33 the cartilage of Sphyrna lewini, Dasyatis akajei, and Raja porosa included type I collagen.39 The cartilage yielded collagen type II in it’s Acid Soluble Collagen (ASC), collagen type II solubilized with pepsin (PSC) and type II gelatine.38

Figure 1: Collagen origins from fish environments

 

 

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Extraction Methods of Collagen

The process of collagen isolation commences with preparation, advances to the extraction stage, and culminates in the recovery phase.2 The process of collagen production includes pretreatment, extraction, separation, purification, and characterization,40 which is expressed as a flowchart of collagen extraction procedure in Figure 2. Pretreatment procedures, comprising cleaning, washing, and size reduction are required before extraction to reduce the contamination of the samples.32

Figure 2: Process of Fish derived collogen extraction

 

 

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Pretreatments involving both acidic and alkaline solutions are frequently employed in the fish processing industry to eliminate non-collagenous compounds like proteins, fats, and pigments, thereby enhancing collagen purity, while simultaneously optimizing collagen yield and quality.42 Acidic pretreatment is a suitable method for materials that are raw containing collagen with less cross-links because it enables the controlled breaking of noncovalent bonds at specific temperatures. This process involves immersing the raw materials in an acidic solution. In contrast, pretreatment with alkaline solutions is commonly employed to break down the intermolecular and intramolecular cross links found in dense and tough raw materials, aiming to eliminate non-collagenous components.41,42

 Treating collagen derived raw materials such as scales or skin is essential prior to their utilization.43 NaOH is a popular choice for alkaline pretreatment due to its exceptional swelling characteristic, which enhances the collagen by maximizing the rate of mass transfer inside the tissue matrix.44 Besides, to prevent environmental pollution, it is crucial to carefully choose a suitable method for pre-treating raw materials, ensuring the minimal production of excess waste liquid and the formation of reagent residues in collagen.1

The demineralization process, often known as pretreatment, is an important step in enhancing the efficacy of collagen extraction. This technique is employed when extracting collagen from raw materials naturally containing minerals, such as scales and bones. During the demineralization process, ethylenediaminetetraacetic acid (EDTA) is utilized to facilitate the removal of these minerals.42

Collagen extraction has been performed through various techniques, including chemical extractions involving strong acids and alkalis, thermal extractions, and other innovative non-conventional methods.45 The choice of extraction method significantly influences both quantity and quality of the resultant collagen.10 An example of collagen extraction commonly employs acid and enzymes as the primary method.46,10,47,48 A comparative study is done on extraction procedure and types of collagens of various species and represented collectively in Table 1.

Acid-Soluble Collagen (ASC) Extraction Procedure

Acid Solubilized Collagen (ASC), represents a specialized collagen variant obtained exclusively through acid-based extraction methods. The interaction between acid and collagen effectively breaks the cross-links inside the collagen helix, thereby elevating the quality of the extracted collagen. Consequently, researchers have continuously investigated the application of diverse acidic agents to optimize the efficiency, purity, and yield of collagen extraction.10 The acid extraction solution, with concentrations ranging from 0.5 M to 1 M, allows for the breaking of both intramolecular and intermolecular crosslinks while maintaining the integrity of the collagen chains.43

Pepsin Soluble Collagen (Psc) Extraction Procedure:

Another commonly employed technique for collagen extraction involves the utilization of Pepsin Soluble collagen (PSC) extraction, wherein pepsin is introduced into the extraction method.49 The PSC extraction method has been fine-tuned by optimizing three crucial parameters: achieving the highest PSC extraction efficiency entailed employing a pepsin concentration that was 1389 U/g, maintaining a ration of solids-liquids of 1:57, and a hydrolysis duration of 8.67 hours. These maximized parameters produced an impressive PSC extraction yield of 84.85%.50

Consequently, numerous research endeavours have incorporated an enzymatic pre-treatment involving pepsin to enzymatically break down the telopeptide ends of collagen chains, thus enhancing the ease of proteins extracted from the residual matrix.40,51 Additionally, a prior study documented the extraction of collagen from several tissues of bighead carp, including scales, skins, fins, bones. This extraction process involved treatment with a 0.1 M NaOH and a solution that was alkaline, followed by the use of PSC.52

Table 1: Comparison of extraction methods of fish derived collagen and its collagen type across distinct species.

FISH SPECIES

SOURCE

EXTRACTION METHOD

TYPE OF COLLAGEN

REFERENCES

Nile tilapia (Oreochromis niloticus)

Skin

acid-soluble collagen (ASC) and pepsin-soluble collagen (PSC)

Type I

1

Silver carp (Hypophthalmichthys molitrix)

Scales

acid-soluble collagen (ASC) and pepsin-soluble collagen (PSC)

Type I

4

Carp (Cyprinus carpio)

Bone

acid-soluble collagen (ASC)

Type I

28

Silvertip shark (Carcharhinus albimarginatus

Cartilage

acid-soluble collagen (ASC) and pepsin-soluble collagen (PSC)

Type II

31

Channel Catfish (Ictalurus punctatus)

Skin

acid-soluble collagen (ASC) and pepsin-soluble collagen (PSC)

Type I

43

Bigeye tuna (Thunnus obesus)

 

Bone

acid-soluble collagen (ASC) and pepsin-soluble collagen (PSC)

Type I

49

Giant croaker (Nibea japonica)

Skin

pepsin-solubilised collagen (PSC)

Type I

50

Bighead carp (Hypophthalmichthys nobilis)

Fins

pepsin-solubilised collagen (PSC)

Type I

52

Collagen Characterization Methods

Analysing the structural properties of isolated collagen provides a meaningful connection between its characteristics and the obtained results. Various methods can be employed to evaluate marine collagen. With a particular emphasis on its structure and morphological properties. Various approaches can be employed for the evaluation of marine collagen, whether it’s in a liquid or solid state, to examine its structural, chemical, and morphological characteristics.2 A schematic representation of few characterization methods are shown in Figure 3.

Figure 3: Characterization of extracted collagen thourgh SDS-PAGE and Chromatographic method.

 


 

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FT-IR Studies

The Fourier transform infrared (FTIR) technique serves as a valuable tool for assessing collagen’s presence, chemical composition, and type recognition. Furthermore, it enables comparisons of collagen compositions obtained through various extraction methods and exploration of how isolation techniques impact collagen composition.53,31,6 Fourier transform infrared (FTIR) spectroscopy stands out is a popular method for investigating the secondary structure of proteins during collagen characterization.54 FTIR spectroscopy holds significance as it unveils the absorption wavenumbers spanning from 500 to 4000 cm-1 within the spectrum.55

The FTIR spectra of collagens derived from seabass scales through both PSC and ASC extraction methods were studied. Their findings revealed that the extracted collagen is type I, and that the treatment processes did not cause any damage to the functional groups within the collagen’s triple helix structure.6 Complementary research utilized FTIR spectra to analyse the composition of PSCs obtained from mackerel (Scomber japonicus) bones and skin. Their investigation unveiled that mackerel bones and skin predominantly comprise type I collagen, which is a molecular structure composed of two identical α1-chains and one α2-chain, forming a heterotrimeric configuration.56 

SDS-PAGE Technique

SDS-PAGE, (Sodium dodecyl sulfate polyacrylamide gel electrophoresis), is a technique used to separate proteins and protein fragments according to their sizes. This technique helps to determine the molecular weight of collagen.57 Collagen type I peptides exhibit a versatile structure, composed of three alpha chains that can vary in composition depending on the specific type of collagen. For instance, in type I collagen, the arrangement comprises two alpha 1 chains and one alpha 2 chain, whereas in type II collagen, three alpha 1 chains are present. Furthermore, the assembly and post-translational modifications give rise to dimers (β-chains) or trimers (γ-chains), as observed in SDS-PAGE analysis. Fish collagen typically follows a similar pattern with two alpha 1 chains and one alpha 2 chain.58,59 A study discovered that the collagen extracted from sole fish skin (Solea solea) consisted of three distinctive -chains: (α1)2, α2 chains (M.W. 118, 116 kDa), along with a single β chain (M.W. 200 kDa).60

Circular Dichroism

On a similar note, with other proteins, one can evaluate collagen’s secondary structure, binding properties, and folding characteristics using circular dichroism (CD), a technique that relies on measuring the distinct right and left circularly polarized light absorption.61,62 By integrating CD spectroscopy with complementary techniques like rheology, we can unlock valuable insights into the type I collagen fibril’s secondary structure and the collagen fibril signals development, ultimately advancing our understanding of collagen-based biomaterials.2 It is demonstrated that employing an ultrasound-assisted extraction method on collagen from crown featherback (Chitala ornata) skin resulted in collagen samples exhibiting distinctive triple-helical structural features, as evidenced by CD spectrometry.47

Chromatography

Chromatographic techniques can be employed to separate, identify, and quantify amino acids for the purpose of amino acid analysis.63 Collagen type I is renowned for its richness in the amino acids like glycine, alanine, proline, and hydroxyproline.64

For instance Wu et al., demonstrated that the amino acid analyses of extracted collagen obtained from silver carp (Hypophthalmichthys molitrix) scales using PSC and ASC methods revealed the presence of collagen type I with a substantial 34% content of glycine and a relatively low level of amino acid content, specifically 20% consisting of proline (Pro) and hydroxyproline (Hyp).4

Differential Scanning Calorimetry (DSC)

Elevated temperatures lead to the unfolding of collagen molecule structures, and the maximum transformation and collagen’s denaturation temperature can be determined by quantifying the calorimetric energy flux.6 Differential scanning calorimetry (DSC) is used to analyse the collagen thermo behaviour. When temperature rises during DSC analysis, collagen gradually absorbs heat, eventually reaching a species-specific threshold temperature where it begins to undergo structural unfolding.65 The depicted findings of collagen through characterization methods are illustrated in Table 2. The collagen extracted using pepsin, known for its elevated Hyp content, exhibited a peak denaturation temperature of 39.32°C and a corresponding enthalpy change (∆H) of 0.91 J/g. In contrast, the collagen isolated with acid demonstrated slightly lower values, with a denaturation temperature of 38.17°C and a ∆H of 0.72 J/g.6 In another study, it was found that the Hyp content in the skin of seabass (Lates calcarifer) reached 79 residues per 1000 residues. The skin demonstrated a maximum temperature threshold of 33.33°C, along with a ∆H value of 0.860 J/g.66

Table 2: A comparative findings of characterization methods of extracted collagen through various studies

CHARACTERIZATION METHODS

FISH SPECIES

ILLUSTRATED FINDINGS

REFERENCES

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Scomber japonicus

Bone and skin are primarily composed of type I collagen, featuring a molecular structure consisting of two identical α1-chains and one α2-chain, arranged in a heterotrimeric configuration.

6

FTIR

Hypophthalmichthys molitrix

The FTIR spectra indicated that both ASC and PSC were likely structured in their native triple helical conformation.

4

 

Sardinella longiceps

The FTIR spectra analysis of ASC and PSC, extracted from sardine scales, skin, and muscles, revealed the distinct presence of various functional groups across a broad range of wavelengths (4,000–400 cm−1).

5

 

 

 

 

 

 

 

 

 

Solea solea

The fish skin exhibited three distinct -chains: (α1)2, α2 chains (M.W. 118,116 kDa), in addition to a single β chain (M.W. 200 kDa).

60

SDS-PAGE

Oreochromis niloticus

The skin showcased comparable protein profiles, featuring α1 and α2 chains weighing around 123 and 113 kDa.

1

 

Hypophthalmichthys molitrix

Both the ASC and PSC demonstrate the presence of α1 and α2 chains, suggesting that the collagen found in silver carp scales is consistent with type I collagen.

4

 

 

 

 

 

 

Chitala ornata

The collagen samples derived from skin displayed notable triple-helical structural characteristics.

47

CIRCULAR DICHROISM

Hypophthalmichthys molitrix

The CD spectra of ASC and PSC closely resemble each other, exhibiting a peak of rotation at 220 nm and a trough at 197 nm. This pattern mirrors the characteristic spectrum associated with the collagen triple-helix structure.

4

 

Acipenser schrenckii

The CD spectra of collagen revealed a distinctive pattern: a peak rotation at 221 nm, a trough at 198 nm, and a consistent crossover point around 213 nm. This pattern is a typical characteristic of collagen’s triple helical conformation.

32

 

Hypophthalmichthys molitrix

The analysis of collagen derived from scales unveiled the dominance of collagen type I, boasting a significant 34% glycine and low level of proline (Pro) and hydroxyproline (Hyp).

4

CHROMATOGRAPHY

Silurus triostegus

Reverse phase HPLC analysis revealed a distinct array of protein peaks within the PSC samples in contrast to the ASC and type I collagen standard samples. This variation is likely attributed to the process of pepsin hydrolysis.

67

 

Pterygoplichthys pardalis

 

A comprehensive analysis revealed the presence of

16 amino acids. Notably, glycine emerged as the predominant amino acid in both ASC and PSC samples, constituting 28.3% and 27.9% of the total composition, respectively.

68

 

 

 

 

 

 

Lates calcarifer

The skin exhibited a maximum temperature limit of 33.33°C, accompanied by a ∆H value of 0.860 J/g.

66

DIFFERENTIAL SCANNING CALORIMETRY

Cyprinus carpio

An endothermic peak was observed at 116°C on the DSC diagram, indicating a heat absorption of 3.7 J/g.

16

 

Acipenser schrenckii

The DSC pattern revealed that the temperature at which the material started to change (Tm) was 120.23°C for ASC and 118.80°C for PSC.

32

An Overview on the application of Fish collagen in various yields

Fish derived collagen has received research attention for biomaterial applications due to its solubility in water, safety, versatility, biodegradation, ease of extraction, and minimal immunogenicity.69,70 The biocompatibility and biodegradability characteristics of fish atelocollagen make it a suitable choice for scaffolds in regenerative medicine.71 The various collective applications are shown in Figure 4.

Utilizing type I collagen from fish as a compostable spacer and scaffold proves highly effective in mimicking the natural extracellular matrix. This replication facilitates the spatial organization of cells, offers environmental cues, and allows for site-specific cellular control.72,73,74

Fish collagen has been evaluated as a scaffold for achieving tissue engineering objectives.75,76 Incorporating fish collagen in situ may promote the formation of hard tissue, serving not just as both a framework for implanted cells and a nutritive component.67 Furthermore, various types of collagens, obtained through different techniques, have been shown to be instrumental in promoting the regeneration of dental tissue, underscoring their potential for use in biomedical applications aimed at restoring tooth tissue.76,77

Moreover, they play a vital role in drug delivery systems, including their use in ophthalmology through collagen shields, facilitating protein delivery via pills and mini-pellets, controlling transdermal administration with gel formulations in combination with liposomes, and facilitating gene delivery through nanoparticles.78,79,80,81,82,83

In an effort to enhance the allopurinol efficacy as a pharmaceutical agent for addressing gout and elevated uric acid concentration in the human body, a pH-sensitive hydrogel by utilizing fish scale-derived collagen and carrageenan was prepared as a drug delivery system.84 The application of this hydrogel resulted in enhanced drug bioactivity and favourable changes in the drug’s physical characteristics when exposed to simulated body fluids. Notably, the release of drug rate was much slower, ranging from 1.5 to 6.7 times more gradual than the control sample.

In a separate study, hydrogel microneedles were created using crosslinked collagen derived from fish scales via an altered lower temperature press technique, and these microneedles were successfully loaded with ferrous gluconate.85 Researchers aim to target the delivery of drugs to particular body tissues or organs, with the goal of mitigating substantial issues such as low bioavailability, instability, poor solubility, and inadequate absorption.86

The process of bone regeneration is a multifaceted physiological phenomenon, encompassing both the creation and breakdown of bone tissue.87 A primary objective within the field of tissue engineering involves the restoration of impaired, infected, or tissues and destroyed organs by employing permeable, biocompatible, and naturally degradable scaffolds.88,89,90,91

Usage of marine collagen in creating scaffolds has been investigated for its potential to promote osteogenic activity in the context of bone tissue engineering applications.2 Hoyer et al., used the combination of salmon skin collagen and hydroxyapatite to fabricate scaffolds tailored for bone regeneration. They harnessed the biomimetic mineralization principle as the foundation for their approach. In addition to its impressive mechanical elasticity, these scaffolds demonstrated remarkable absorbent qualities along with a well-established network of interconnected pores. This architecture facilitated the adhesion and proliferation of human Mesenchymal Stem Cells (hMSCs), making it a promising platform for fostering osteogenic differentiation.92

A collagen fibril using collagen extracted via the swim bladder of Bester sturgeon fish was successfully developed. They created hydrogels utilizing a double network structure. These double network hydrogels displayed outstanding mechanical characteristics, and the hydrogel exhibited excellent mechanical properties in vivo. As a result, they claimed that this hydrogel offers promise for applications such as artificial cartilage.93 A chitosan-collagen composite scaffold, incorporating collagen derived from tilapia scales, was engineered for the explicit aim of facilitating oral mucosa regeneration.94

In an attempt to enhance the wound healing process using a skin engineering approach Hu et al., undertook a study. They assessed the wound repair potential of marine derived collagen peptides produced from Nile tilapia skin (Oreochromis niloticus) through both in vitro and in vivo experiments. The marine derived collagen peptides they synthesized primarily consisted of polypeptides. Their findings from both in vitro and in vivo experiments indicated that the collagen extracted from Nile tilapia had the potential to promote and accelerate the wound-healing process.95

Collagen is of significant importance in the biomedical field because of its biocompatibility, biodegradability, and enhanced capability to permeate lipid free surfaces. Its biological uses are numerous, primarily because collagen has the unusual capacity to self-organize and create cross-linked collagen fibres, which exhibit remarkable strength and stability.96,97

Numerous studies have established that collagen hydrogels stand out as prime materials for wound dressings. Their effectiveness stems from their three-dimensional structure, closely resembling the natural moisture of the extracellular skin environment.98 Marine collagen has the potential to serve a dual purpose as both a dressing for wounds and a medication carrier. To illustrate, curcumin was incorporated within fish scale-derived collagen, along with Hydroxy methylcellulose nanogel, for applications in wound healing.99

Analogously, collagens are increasingly acknowledged for their remarkable biological effects and significant potential for application in the cosmetic industry. As new generations pursue novel beauty and youth-maintenance goals while continually seeking safe and cost-effective ingredients, proteins of marine, particularly marine derived collagens, are currently emerging as outstanding functional components for the cosmetic sector.100,79,80,101 Within the cosmetic industry, marine collagen is sourced from the skin of cold-water fishes such as cod, haddock, and salmon.102,103 Furthermore, it is also made from scales of fish by procedures such as decalcification and enzymatic hydrolysis.104

In the food sector, the core purpose of food packaging is to safeguard and maintain the quality of food, chiefly by shielding it from oxidative and microbial deterioration. This is achieved by improving the packaging’s barrier and mechanical properties, which, in turn, extends the food’s shelf life. Fish collagen has also garnered increasing attention for its capacity to introduce innovative and intelligent attributes to traditional packaging solutions.105,106,107,108

Figure 4: Fish derived collagen in diverse applications

 


 

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Conclusion

Collagen sourced from marine and freshwater environments, especially fish collagen, is increasingly acknowledged for its value owing to its easy accessibility, minimal transfer of disease risk, absence of religious restrictions, and the potential for larger collagen yields. Progressive research and development in the extraction and application of fish collagen from aquatic sources makes it a promising and sustainable alternative to conventional collagen sources like bovine or porcine collagen. Consequently, by-products of fish are emerging as a favoured option for collagen extraction. The choice of extraction method significantly influences collagen quality and quantity, with acid-soluble and pepsin-soluble collagen methods yielding high results. The implications of several fish derived collagens in biomedical industries, therapeutic, cosmetic industry, food, biomaterials are noteworthy. Therefore, it is desirable to focus research on developing environmentally sustainable and cost-efficient approaches for collagen synthesis.

Acknowledgement

We acknowledge the support provided by the Management and Principal, Dwaraka Doss Goverdhan Doss Vaishnav College, Chennai.

Conflict of Interest

There is no conflict of interest.

Funding Sources

There are no funding sources.

Authors’ Contribution

All authors contributed equally to this work.

Data Availability Statement

Not applicable

Ethics Approval Statement

Not applicable

References

  1. Song Z., Liu H., Chen L., Chen L., Zhou C., Hong P., Deng C. Characterization and comparison of collagen extracted from the skin of the Nile tilapia by fermentation and chemical pretreatment. Food Chem. 2021; 340:128139.
    CrossRef
  2. Jafari H., Lista A., Siekapen MM., Ghaffari-Bohlouli P., Nie L., Alimoradi H., Shavandi A. Fish collagen: Extraction, characterization, and applications for biomaterials engineering. Polymers. 2020;12(10):2230.
    CrossRef
  3. Ge B., Wang H., Li J., Liu H., Yin Y., Zhang N., Qin S. Comprehensive assessment of Nile tilapia skin (Oreochromis niloticus) collagen hydrogels for wound dressings. drugs. 2020;18(4):178.
    CrossRef
  4. Wu J., Kong L., Zhang J., Chen W. Extraction and properties of acid-soluble collagen and pepsin-soluble collagen from silver carp (Hypophthalmichthys molitrix) scales: Prerequisite information for fishery processing waste reuse. J. Environ. Stud. 2019;28(4):2923-30.
    CrossRef
  5. Srinivasan S., Durairaj B. Collagen isolation and characterization from Sardinella longiceps. JAVAR. 2021;8(4):679.
    CrossRef
  6. Chuaychan S., Benjakul S., Kishimura H. Characteristics of acid-and pepsin-soluble collagens from scale of seabass (Lates calcarifer). LWT. 2015;63(1):71-6.
    CrossRef
  7. Caruso G. Fishery wastes and by-products: a resource to be valorised. FisheriesSciences.com. 2015;9(4): 080-083.
  8. Bhuimbar MV., Bhagwat PK., Dandge PB. Extraction and characterization of acid soluble collagen from fish waste: Development of collagen-chitosan blend as food packaging film. Environ. Chem. Eng. 2019;7(2):102983.
    CrossRef
  9. Mahboob S. Isolation and characterization of collagen from fish waste material-skin, scales and fins of Catla catla and Cirrhinus mrigala. JFST. 2015; 52:4296-305.
    CrossRef
  10. Hukmi NM., Sarbon NM. Isolation and characterization of acid soluble collagen (ASC) and pepsin soluble collagen (PSC) extracted from silver catfish (Pangasius sp.) skin. Food Res. J. 2018;25(6).
  11. Sahithi B., Ansari SK., Hameeda SK., Sahithya GM., Prasad DM., Lakshmi Y. A review on collagen-based drug delivery systems. IJRPB. 2013;1(3):461.
  12. Pan MH., Tsai ML., Chen WM., Hwang A., Sun Pan B., Hwang YR., Kuo JM. Purification and characterization of a fish scale-degrading enzyme from a newly identified Vogesella sp. Agric. Food Chem. 2010;58(23):12541-6.
    CrossRef
  13. Prahasanti C., Wulandari DT., Ulfa N. Viability test of fish scale collagen (Oshpronemus gouramy) on baby hamster kidney fibroblasts-21 fibroblast cell culture. World. 2018;11(4):506.
    CrossRef
  14. Zhou T., Wang N., Xue Y., Ding T., Liu X., Mo X., Sun J. Development of biomimetic tilapia collagen nanofibers for skin regeneration through inducing keratinocytes differentiation and collagen synthesis of dermal fibroblasts. ACS Appl. Interfaces. 2015;7(5):3253-62.
    CrossRef
  15. El-Rashidy AA., Gad A., Abu-Hussein AE., Habib SI., Badr NA., Hashem AA. Chemical and biological evaluation of Egyptian Nile Tilapia (Oreochromis niloticas) fish scale collagen. J. Biol. Macromol. 2015; 79:618-26.
    CrossRef
  16. Chinh NT., Manh VQ., Trung VQ., Lam TD., Huynh MD., Tung NQ., Trinh ND., Hoang T. Characterization of collagen derived from tropical freshwater carp fish scale wastes and its amino acid sequence. Prod. Commun. 2019;14(7):1934578X19866288.
    CrossRef
  17. Walker C., Mojares E., del Río Hernández A. Role of extracellular matrix in development and cancer progression. J. Mol. Sci. 2018;19(10):3028.
    CrossRef
  18. Gurney TA., Kim DW. Applications of porcine dermal collagen (ENDURAGen) in facial plastic surgery. Facial Plast. Surg. Clin. 2007;15(1):113-21.
    CrossRef
  19. Asai T., Takahashi A., Ito K., Uetake T., Matsumura Y., Ikeda K., Inagaki N., Nakata M., Imanishi Y., Sato K. Amount of collagen in the meat contained in Japanese daily dishes and the collagen peptide content in human blood after ingestion of cooked fish meat. Agric. Food Chem. 2019;67(10):2831-8.
    CrossRef
  20. Gauza-Włodarczyk M., Kubisz L., Mielcarek S., Włodarczyk D. Comparison of thermal properties of fish collagen and bovine collagen in the temperature range 298–670 K. Sci. Eng. C. 2017; 80:468-71.
    CrossRef
  21. Brodsky B., Thiagarajan G., Madhan B., Kar K. Triple‐helical peptides: An approach to collagen conformation, stability, and self‐association. Biopolymers: Original Research on Biomolecules. 2008;89(5):345-53.
    CrossRef
  22. Veit G., Kobbe B., Keene DR., Paulsson M., Koch M., Wagener R. Collagen XXVIII, a novel von Willebrand factor A domain-containing protein with many imperfections in the collagenous domain. 2006;281(6):3494-504.
    CrossRef
  23. Ricard-Blum S., Ruggiero F. The collagen superfamily: from the extracellular matrix to the cell membrane. Biol.2005;53(7):430-42.
    CrossRef
  24. Chen J., Li L., Yi R., Gao R., He J. Release kinetics of Tilapia scale collagen I peptides during tryptic hydrolysis. Food Hydrocoll. 2018; 77:931-6.
    CrossRef
  25. Liu W., Zhang Y., Cui N., Wang T. Extraction and characterization of pepsin-solubilized collagen from snakehead (Channa argus) skin: Effects of hydrogen peroxide pretreatments and pepsin hydrolysis strategies. Process Biochem. 2019; 76:194-202.
    CrossRef
  26. Tziveleka LA., Ioannou E., Tsiourvas D., Berillis P., Foufa E., Roussis V. Collagen from the marine sponges Axinella cannabina and Suberites carnosus: Isolation and morphological, biochemical, and biophysical characterization. drugs. 2017;15(6):152.
    CrossRef
  27. Debipersadh S., Selvarajan R., Sibanda T., Naidoo R. Assessing toxic elemental concentrations in marine fish trachurus capensis (cape horse mackerel) and implications for public health. J. Environ. Stud. 2018;27(3):1395-400.
    CrossRef
  28. Duan R., Zhang J., Du X., Yao X., Konno K. Properties of collagen from skin, scale and bone of carp (Cyprinus carpio). Food Chem. 2009;112(3):702-6.
    CrossRef
  29. Blanco M., Vázquez JA., Pérez-Martín RI., Sotelo CG. Hydrolysates of fish skin collagen: An opportunity for valorizing fish industry byproducts. drugs. 2017;15(5):131.
    CrossRef
  30. Van De Water L., Varney S., Tomasek JJ. Mechanoregulation of the myofibroblast in wound contraction, scarring, and fibrosis: opportunities for new therapeutic intervention. Advances in wound care. 2013;2(4):122-41.
    CrossRef
  31. Jeevithan E., Bao B., Bu Y., Zhou Y., Zhao Q., Wu W. Type II collagen and gelatin from silvertip shark (Carcharhinus albimarginatus) cartilage: Isolation, purification, physicochemical and antioxidant properties. drugs. 2014;12(7):3852-73.
    CrossRef
  32. Liang Q., Wang L., Sun W., Wang Z., Xu J., Ma H. Isolation and characterization of collagen from the cartilage of Amur sturgeon (Acipenser schrenckii). Process Biochem. 2014;49(2):318-23.
    CrossRef
  33. Cumming MH., Hall B., Hofman K. Isolation and characterisation of major and minor collagens from hyaline cartilage of hoki (Macruronus novaezelandiae). drugs. 2019;17(4):223.
    CrossRef
  34. Sousa RO., Martins E., Carvalho DN., Alves AL., Oliveira C., Duarte AR., Silva TH., Reis RL. Collagen from Atlantic cod (Gadus morhua) skins extracted using CO2 acidified water with potential application in healthcare. Polym. Res. 2020;27(3):73.
    CrossRef
  35. Oslan SN., Li CX., Shapawi R., Mokhtar RA., Noordin WN., Huda N. Extraction and characterization of bioactive fish by-product collagen as promising for potential wound healing agent in pharmaceutical applications: Current trend and future perspective. J. Food Sci. 2022;2022.
    CrossRef
  36. Kimura S., Miyauchi Y., Uchida N. Scale and bone type I collagens of carp (Cyprinus carpio). Comparative biochemistry and physiology. Comp. Physiol. B. 1991;99(2):473-6.
    CrossRef
  37. Ramli L., Natsir H., Dali S., Danial S. Collagen extraction from bone of Lutjanus sp. and toxicity assay. Jurnal Akta Kimia Indonesia (Indonesia Chimica Acta). 2019;67-72.
    CrossRef
  38. Luo QB., Chi CF., Yang F., Zhao YQ., Wang B. Physicochemical properties of acid-and pepsin-soluble collagens from the cartilage of Siberian sturgeon. 2018; 25:31427-38.
    CrossRef
  39. Brazee SL., Carrington E. Interspecific comparison of the mechanical properties of mussel byssus. Bull. 2006;211(3):263-74.
    CrossRef
  40. Blanco M., Vázquez JA., Pérez-Martín RI., G. Sotelo C. Collagen extraction optimization from the skin of the small-spotted catshark (S. canicula) by response surface methodology. drugs. 2019;17(1):40.
    CrossRef
  41. Schmidt MM., Dornelles RC., Mello RO., Kubota EH., Mazutti MA., Kempka AP., Demiate IM. Collagen extraction process. Food Res. J. 2016;23(3):913.
  42. Pal GK., Suresh PV. Sustainable valorisation of seafood by-products: Recovery of collagen and development of collagen-based novel functional food ingredients. 2016; 37:201-15.
    CrossRef
  43. Tan Y., Chang SK. Isolation and characterization of collagen extracted from channel catfish (Ictalurus punctatus) skin. Food Chem. 2018; 242:147-55.
    CrossRef
  44. Liu D., Wei G., Li T., Hu J., Lu N., Regenstein JM., Zhou P. Effects of alkaline pretreatments and acid extraction conditions on the acid-soluble collagen from grass carp (Ctenopharyngodon idella) skin. Food Chem. 2015; 172:836-43.
    CrossRef
  45. Kuwahara J. Extraction of type I collagen from tilapia scales using acetic acid and ultrafine bubbles. Processes. 2021;9(2):288.
    CrossRef
  46. Senadheera TR., Dave D., Shahidi F. Sea cucumber derived type I collagen: A comprehensive review. drugs. 2020;18(9):471.
    CrossRef
  47. Petcharat T., Benjakul S., Karnjanapratum S., Nalinanon S. Ultrasound‐assisted extraction of collagen from clown featherback (Chitala ornata) skin: yield and molecular characteristics. Sci. Food Agric. 2021;101(2):648-58.
    CrossRef
  48. Bai C., Wei Q., Ren X. Selective extraction of collagen peptides with high purity from cod skins by deep eutectic solvents. ACS Sustain. Chem. Eng. 2017;5(8):7220-7.
    CrossRef
  49. Ahmed R., Haq M., Chun BS. Characterization of marine derived collagen extracted from the by-products of bigeye tuna (Thunnus obesus). J. Biol. Macromol.  2019; 135:668-76.
    CrossRef
  50. Yu F., Zong C., Jin S., Zheng J., Chen N., Huang J., Chen Y., Huang F., Yang Z., Tang Y., Ding G. Optimization of extraction conditions and characterization of pepsin-solubilised collagen from skin of giant croaker (Nibea japonica). drugs. 2018;16(1):29.
    CrossRef
  51. Vallejos N., González G., Troncoso E., Zúñiga RN. Acid and enzyme-aided collagen extraction from the byssus of Chilean mussels (Mytilus Chilensis): Effect of process parameters on extraction performance. Food biophysics. 2014; 9:322-31.
    CrossRef
  52. Liu D., Liang L., Regenstein JM., Zhou P. Extraction and characterisation of pepsin-solubilised collagen from fins, scales, skins, bones and swim bladders of bighead carp (Hypophthalmichthys nobilis). Food Chem. 2012;133(4):1441-8.
    CrossRef
  53. Kan M., Qian X., Zhang T., Yue D., Zhao Y. Highly Active IrO x Nanoparticles/Black Si Electrode for Efficient Water Splitting with Conformal TiO2 Interface Engineering. ACS Sustain. Chem. Eng. 2017;5(11):10940-6.
    CrossRef
  54. Dong X., Shen P., Yu M., Yu C., Zhu B., Qi H. (−)-Epigallocatechin gallate protected molecular structure of collagen fibers in sea cucumber Apostichopus japonicus body wall during thermal treatment. Lwt. 2020; 123:109076.
    CrossRef
  55. Abraham LC, Zuena E, Perez‐Ramirez B, Kaplan DL. Guide to collagen characterization for biomaterial studies. Journal of Biomedical Materials Research Part B: Applied Biomaterials: An Official Journal of The Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and the Korean Society for Biomaterials. 2008;87(1):264-85.
    CrossRef
  56. Asaduzzaman AK, Getachew AT, Cho YJ, Park JS, Haq M, Chun BS. Characterization of pepsin-solubilised collagen recovered from mackerel (Scomber japonicus) bone and skin using subcritical water hydrolysis. J. Biol. Macromol. 2020;148:1290-7.
    CrossRef
  57. León-López A., Morales-Peñaloza A., Martínez-Juárez VM., Vargas-Torres A., Zeugolis DI., Aguirre-Álvarez G. Hydrolyzed collagen—sources and applications. Mol. 2019;24(22):4031.
    CrossRef
  58. Bielajew BJ, Hu JC, Athanasiou KA. Collagen: quantification, biomechanics and role of minor subtypes in cartilage.Rev. Mater. 2020;5(10):730-47.
    CrossRef
  59. Gelse K, Pöschl E, Aigner T. Collagens—structure, function, and biosynthesis. Drug Deliv. Rev. 2003;55(12):1531-46.
    CrossRef
  60. Arumugam GK, Sharma D, Balakrishnan RM, Ettiyappan JB. Extraction, optimization and characterization of collagen from sole fish skin. Chem. Pharm. 2018;9:19-26.
    CrossRef
  61. Polavarapu PL., He J. Peer reviewed: chiral analysis using mid-IR vibrational CD spectroscopy. Chem. 2004;61-A
    CrossRef
  62. Greenfield NJ. Using circular dichroism spectra to estimate protein secondary structure. Protoc. 2006;1(6):2876-90.
    CrossRef
  63. Molnár-Perl I., editor. Quantitation of amino acids and amines by chromatography: Methods and protocols. Chromatogr. 2005;70(1st ed.)
    CrossRef
  64. Silvipriya KS., Kumar KK., Bhat AR., Kumar BD., John A. Collagen: Animal sources and biomedical application. Appl. Pharm. Sci. 2015;5(3):123-7.
    CrossRef
  65. Silva TH., Moreira-Silva J., Marques AL., Domingues A., Bayon Y., Reis RL. Marine origin collagens and its potential applications. drugs. 2014;12(12):5881-901.
    CrossRef
  66. Davoodi J, Wakarchuk WW, Surewicz WK, Carey PR. Scan‐rate dependence in protein calorimetry: The reversible transitions of Bacillus circulans xylanase and a disulfide‐bridge mutant. Protein science. 1998;7(7):1538-44.
    CrossRef
  67. Abbas AA, Shakir KA, Walsh MK. Functional properties of collagen extracted from catfish (Silurus triostegus) waste. 2022;11(5):633.
    CrossRef
  68. Nurubhasha R, Sampath Kumar NS, Thirumalasetti SK, Simhachalam G, Dirisala VR. Extraction and characterization of collagen from the skin of Pterygoplichthys pardalis and its potential application in food industries. 2019;28:1811-7
    CrossRef
  69. Cho JK., Jin YG., Rha SJ., Kim SJ., Hwang JH. Biochemical characteristics of four marine fish skins in Korea. Food Chem. 2014; 159:200-7.
    CrossRef
  70. Hayashi Y., Yamada S., Ikeda T., Yanagiguchi K. Fish Collagen and Tissue Repair. Marine Cosmeceuticals: Trends and Prospects. 2011; 11:133.
    CrossRef
  71. Hayashi Y., Yamada S., Guchi KY., Koyama Z., Ikeda T. Chitosan and fish collagen as biomaterials for regenerative medicine. Food Nutr. Res. 2012; 65:107-20.
    CrossRef
  72. Wang JH., Hung CH., Young TH. Proliferation and differentiation of neural stem cells on lysine–alanine sequential polymer substrates. Biomaterials. 2006;27(18):3441-50.
    CrossRef
  73. Nagai N., Nakayama Y., Zhou YM., Takamizawa K., Mori K., Munekata M. Development of salmon collagen vascular graft: mechanical and biological properties and preliminary implantation study. Journal of Biomedical Materials Research Part B: Applied Biomaterials: An Official Journal of The Society for Biomaterials, The Japanese Society for Biomaterials, and The Australian Society for Biomaterials and the Korean Society for Biomaterials. 2008;87(2):432-9.
    CrossRef
  74. Sugiura H., Yunoki S., Kondo E., Ikoma T., Tanaka J., Yasuda K. In vivo biological responses and bioresorption of tilapia scale collagen as a potential biomaterial. Biomater. Sci. Polym. Ed. 2009;20(10):1353-68.
    CrossRef
  75. Hayashi Y., Ikeda T., Yamada S., Koyama Z., Yanagiguchi K. The application of fish collagen to dental and hard tissue regenerative medicine. Seafood Processing By-Products: Trends and Applications. 2014;455-62.
    CrossRef
  76. Lin K., Zhang D., Macedo MH., Cui W., Sarmento B., Shen G. Advanced collagen‐based biomaterials for regenerative biomedicine. Funct. Mater. 2019;29(3):1804943.
    CrossRef
  77. Pankajakshan D., Voytik-Harbin SL., Nör JE., Bottino MC. Injectable highly tunable oligomeric collagen matrices for dental tissue regeneration. ACS Appl.Bio Mater. 2020;3(2):859-68.
    CrossRef
  78. Swatschek D., Schatton W., Müller WE., Kreuter J. Microparticles derived from marine sponge collagen (SCMPs): preparation, characterization and suitability for dermal delivery of all-trans retinol. J. Pharm. Biopharm. 2002;54(2):125-33.
    CrossRef
  79. Pallela R., Venkatesan J., Bhatnagar I., Shim Y., Kim S. Applications of marine collagen-based scaffolds in bone tissue engineering. Marine biomaterials: characterization, isolation and applications. 2013;519-28.
  80. Kim SK., Ngo DH., Vo TS., Ryu B. Industry perspectives of marine-derived proteins as biomaterials. Marine biomaterials: characterization, isolation and applications. 2013;737-46.
  81. Calejo MT., Almeida AJ., Fernandes AI. Exploring a new jellyfish collagen in the production of microparticles for protein delivery. Microencapsul. 2012;29(6):520-31.
    CrossRef
  82. Nicklas M., Schatton W., Heinemann S., Hanke T., Kreuter J. Enteric coating derived from marine sponge collagen. Drug Dev. Ind. Pharm. 2009;35(11):1384-8.
    CrossRef
  83. Nicklas M., Schatton W., Heinemann S., Hanke T., Kreuter J. Preparation and characterization of marine sponge collagen nanoparticles and employment for the transdermal delivery of 17β-estradiol-hemihydrate. Drug Dev. Ind. Pharm. 2009;35(9):1035-42.
    CrossRef
  84. Nguyen CT., Vu MQ., Phan TT., Vu TQ., Vo QA., Bach GL., Thai H. Novel pH-sensitive hydrogel beads based on carrageenan and fish scale collagen for allopurinol drug delivery. Polym. 2020; 28:1795-810.
    CrossRef
  85. Wang JK., Yeo KP., Chun YY., Tan TT., Tan NS., Angeli V., Choong C. Fish scale-derived collagen patch promotes growth of blood and lymphatic vessels in vivo. Acta Biomater. 2017; 63:246-60.
    CrossRef
  86. Patra JK., Das G., Fraceto LF., Campos EV., Rodriguez-Torres MD., Acosta-Torres LS., Diaz-Torres LA., Grillo R., Swamy MK., Sharma S., Habtemariam S. Nano based drug delivery systems: recent developments and future prospects. nanobiotechnology. 2018; 16:1-33.
    CrossRef
  87. Shahrousvand M., Tabar FA., Shahrousvand E., Babaei A., Hasani-Sadrabadi MM., Sadeghi GM., Jafari H., Salimi A. High aspect ratio phospho-calcified rock candy-like cellulose nanowhiskers of wastepaper applicable in osteogenic differentiation of hMSCs. Polym. 2017; 175:293-302.
    CrossRef
  88. Nie L., Deng Y., Li P., Hou R., Shavandi A., Yang S. Hydroxyethyl chitosan-reinforced polyvinyl alcohol/biphasic calcium phosphate hydrogels for bone regeneration. Acs Omega. 2020;5(19):10948-57.
    CrossRef
  89. Nie L., Wu Q., Long H., Hu K., Li P., Wang C., Sun M., Dong J., Wei X., Suo J., Hua D. Development of chitosan/gelatin hydrogels incorporation of biphasic calcium phosphate nanoparticles for bone tissue engineering. Biomater. Sci. Polym. Ed. 2019;30(17):1636-57.
    CrossRef
  90. Shavandi A., Bekhit AE., Ali MA., Sun Z. Bio-mimetic composite scaffold from mussel shells, squid pen and crab chitosan for bone tissue engineering. J. Biol. Macromol. 2015; 80:445-54.
    CrossRef
  91. Shavandi A., Bekhit AE., Sun Z., Ali MA. Bio-scaffolds produced from irradiated squid pen and crab chitosan with hydroxyapatite/β-tricalcium phosphate for bone-tissue engineering. J. Biol. Macromol. 2016; 93:1446-56.
    CrossRef
  92. Hoyer B., Bernhardt A., Heinemann S., Stachel I., Meyer M., Gelinsky M. Biomimetically mineralized salmon collagen scaffolds for application in bone tissue engineering. Biomacromolecules. 2012;13(4):1059-66.
    CrossRef
  93. Mredha MT., Kitamura N., Nonoyama T., Wada S., Goto K., Zhang X., Nakajima T., Kurokawa T., Takagi Y., Yasuda K., Gong JP. Anisotropic tough double network hydrogel from fish collagen and its spontaneous in vivo bonding to bone. Biomaterials. 2017; 132:85-95.
    CrossRef
  94. Terada M., Izumi K., Ohnuki H., Saito T., Kato H., Yamamoto M., Kawano Y., Nozawa‐Inoue K., Kashiwazaki H., Ikoma T., Tanaka J. Construction and characterization of a tissue‐engineered oral mucosa equivalent based on a chitosan‐fish scale collagen composite. Biomed. Mater. Res. B. 2012;100(7):1792-802.
    CrossRef
  95. Hu Z., Yang P., Zhou C., Li S., Hong P. Marine collagen peptides from the skin of Nile Tilapia (Oreochromis niloticus): Characterization and wound healing evaluation. drugs. 2017;15(4):102.
    CrossRef
  96. Shalaby M., Agwa M., Saeed H., Khedr SM., Morsy O., El-Demellawy MA. Fish scale collagen preparation, characterization and its application in wound healing. Polym. 2020; 28:166-78.
    CrossRef
  97. Stoica AE., Chircov C., Grumezescu AM. Hydrogel dressings for the treatment of burn wounds: an up-to-date overview. Materials. 2020;13(12):2853.
    CrossRef
  98. Elbialy ZI., Atiba A., Abdelnaby A., Al-Hawary II., Elsheshtawy A., El-Serehy HA, Abdel-Daim MM., Fadl SE., Assar DH. Collagen extract obtained from Nile tilapia (Oreochromis niloticus L.) skin accelerates wound healing in rat model via up regulating VEGF, bFGF, and α-SMA genes expression. BMC Vet. Res. 2020; 16:1-1.
    CrossRef
  99. Pathan IB., Munde SJ., Shelke S., Ambekar W., Mallikarjuna Setty C. Curcumin loaded fish scale collagen-HPMC nanogel for wound healing application: Ex-vivo and In-vivo evaluation. J. Polym. Mater. Polym. Biomater. 2019;68(4):165-74.
    CrossRef
  100. Arvanitoyannis IS., Kassaveti A. Fish industry waste: treatments, environmental impacts, current and potential uses. J. Food Sci. Technol. 2008;43(4):726-45.
    CrossRef
  101. Boran G., Regenstein JM. Fish gelatin. Advances in food and nutrition research. 2010; 60:119-43.
    CrossRef
  102. Hwang JH., Chung JR., Yoo EK., Rha SJ., Lee SW., Jeong SH., Kim HW., Han KH., Kim SJ., Park BJ. Cosmetic composition useful for moisturizing skin, comprises collagen separated from fish skin. 2013; KR2013066342-A; KR1339423-B1.
  103. Hyun CH., Joo HH., Hee KJ., Yoo SJ., Su JY., Dae HL., Hye MP. Preparing collagen useful in cosmetic composition, involves hydrolyzing fish by-products using enzyme. Korea Patent KR2013094989-A. 2013;27.
  104. Zhang J., Duan R., Ye C., Konno K. Isolation and characterization of collagens from scale of silver carp (Hypophthalmichthys molitrix). Food Biochem. 2010;34(6):1343-54.
    CrossRef
  105. Kozłowicz K., Nazarewicz S., Góral D., Krawczuk A., Domin M. Lyophilized protein structures as an alternative biodegradable material for food packaging. 2019;11(24):7002.
    CrossRef
  106. Wang Z., Hu S., Wang H. Scale-up preparation and characterization of collagen/sodium alginate blend films. Food Qual. 2017;2017.
    CrossRef
  107. Goyal N., Rastogi D., Jassal M., Agrawal AK. Chitosan as a potential stabilizing agent for titania nanoparticle dispersions for preparation of multifunctional cotton fabric. Polym. 2016; 154:167-75.
    CrossRef
  108. Demitri C., Moscatello A., Giuri A., Raucci MG., Esposito Corcione C. Preparation and characterization of eg-chitosan nanocomposites via direct exfoliation: A green methodology. Polymers. 2015;7(12):2584-94.
    CrossRef
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