In vivo biocompatibility evaluation of in situ-forming polyethylene glycol-collagen hydrogels in corneal defects

Chun, Yoon Hong; Park, Sun-Kyoung; Kim, Eun Jeong; Lee, Hyun Jong; Kim, Hyewon; Koh, Won‐Gun; Cunha, Geraldo Felicio; Myung, David; Na, Kyung‐Sun

doi:10.1038/s41598-021-03270-3

Cited by 15 publications

(14 citation statements)

References 41 publications

(55 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Researchers expanded on new technology to create various forms of scaffolds for different applications such as foam [ 216 ] via freeze-drying or organised lattices through electrospinning [ 217 , 218 ]. Some injectable materials, such as hydrogel, are preferred for their applications such as corneal or periodontal injection [ 219 , 220 ]. Scaffolds with collagen type I were also studied for drug delivery mechanisms including nanoparticles [ 221 , 222 , 223 ].…”

Section: Current Insights and Conclusionmentioning

confidence: 99%

A Comprehensive Review on Collagen Type I Development of Biomaterials for Tissue Engineering: From Biosynthesis to Bioscaffold

et al. 2022

View full text Add to dashboard Cite

Collagen is the most abundant structural protein found in humans and mammals, particularly in the extracellular matrix (ECM). Its primary function is to hold the body together. The collagen superfamily of proteins includes over 20 types that have been identified. Yet, collagen type I is the major component in many tissues and can be extracted as a natural biomaterial for various medical and biological purposes. Collagen has multiple advantageous characteristics, including varied sources, biocompatibility, sustainability, low immunogenicity, porosity, and biodegradability. As such, collagen-type-I-based bioscaffolds have been widely used in tissue engineering. Biomaterials based on collagen type I can also be modified to improve their functions, such as by crosslinking to strengthen the mechanical property or adding biochemical factors to enhance their biological activity. This review discusses the complexities of collagen type I structure, biosynthesis, sources for collagen derivatives, methods of isolation and purification, physicochemical characteristics, and the current development of collagen-type-I-based scaffolds in tissue engineering applications. The advancement of additional novel tissue engineered bioproducts with refined techniques and continuous biomaterial augmentation is facilitated by understanding the conventional design and application of biomaterials based on collagen type I.

show abstract

Section: Current Insights and Conclusionmentioning

confidence: 99%

A Comprehensive Review on Collagen Type I Development of Biomaterials for Tissue Engineering: From Biosynthesis to Bioscaffold

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Herein, we develop a novel dLM (decellularized liver extracellular matrix)-based bioink with gelatin as a rheology enhancer that is jointly crosslinked chemically by succinimidyl valerate-polyethylene glycol- succinimidyl valerate (x-PEG-x, x = succinimidyl valerate) ( Figure 1 ). PEG is an FDA-approved biomaterial that utilizes the typical functional group [ 38 ] (amines) in both dLM and gelatin to form a robust bioink (dLM-G-PEG, G = gelatin) via the cytocompatible gelation method. The 3D bioprinting is conducted under physiological conditions at 37 °C with HepG2 cells to develop a four-layer grid structure.…”

Section: Introductionmentioning

confidence: 99%

3D Bioprinting of Multi-Material Decellularized Liver Matrix Hydrogel at Physiological Temperatures

et al. 2022

View full text Add to dashboard Cite

Bioprinting is an acclaimed technique that allows the scaling of 3D architectures in an organized pattern but suffers from a scarcity of appropriate bioinks. Decellularized extracellular matrix (dECM) from xenogeneic species has garnered support as a biomaterial to promote tissue-specific regeneration and repair. The prospect of developing dECM-based 3D artificial tissue is impeded by its inherent low mechanical properties. In recent years, 3D bioprinting of dECM-based bioinks modified with additional scaffolds has advanced the development of load-bearing constructs. However, previous attempts using dECM were limited to low-temperature bioprinting, which is not favorable for a longer print duration with cells. Here, we report the development of a multi-material decellularized liver matrix (dLM) bioink reinforced with gelatin and polyethylene glycol to improve rheology, extrudability, and mechanical stability. This shear-thinning bioink facilitated extrusion-based bioprinting at 37 °C with HepG2 cells into a 3D grid structure with a further enhancement for long-term applications by enzymatic crosslinking with mushroom tyrosinase. The heavily crosslinked structure showed a 16-fold increase in viscosity (2.73 Pa s−1) and a 32-fold increase in storage modulus from the non-crosslinked dLM while retaining high cell viability (85–93%) and liver-specific functions. Our results show that the cytocompatible crosslinking of dLM bioink at physiological temperatures has promising applications for extended 3D-printing procedures.

show abstract

“…Erkoc et al replaced the photoinitiator Irgacure 2959 with less cytotoxic eosin Y and used visible light as photoinduction source in developing glioblastoma multiforme mimetic microenvironment . Recently, these gelatin-based bioadhesive hydrogels have been studied as tissue adhesives for keratectomy. , Also, collagen-like peptides poly(ethylene glycol) (CLP-PEG) is a widely studied option in tissue healing. The crosslinking is induced by riboflavin under the irradiation of UVA light.…”

Section: Discussionmentioning

confidence: 99%

“…Most of the adhesive hydrogels for corneal injuries were applied for keratectomy, partial-thickness stroma defects, and corneal incision wounds with or without suture reinforcement. − In general, punctured cornea injuries are difficult to treat, and there are not many therapeutic methods that can be used. There are few references on novel tissue adhesives for corneal perforation.…”

Section: Discussionmentioning

confidence: 99%

Novel Application of Photo-Crosslinked Urocanic-Acid-Modified Chitosan in Corneal Wounds

Lee

Hsieh

Chen

et al. 2022

ACS Biomater. Sci. Eng.

View full text Add to dashboard Cite

In the last few years, the use of tissue adhesives in corneal perforation has gained immense popularity in clinical practices. The present study aimed to devise a new application of urocanic-acid-modified chitosan (CS) with methylene blue (MB) as a photosensitizer for the development of a photocrosslinked tissue adhesive. In particular, the curing time was controlled with the aid of a 650 nm red diode. Under the same irradiation condition, the mechanical properties were tuned using the photosensitizer at different concentrations. In vitro tests revealed that the gel was ductile and biocompatible. The application of the gel to a perforated cornea model stopped the leakage of aqueous humor, immediately after the gel was photo-crosslinked. The blue appearance of the gel provided high precision when applied to corneal wounds. Importantly, the crosslinked gel became transparent within 24 h, owing to the dissipation of MB from tears, and the gel spontaneously sloughed off without artificial removal. Altogether, the study reported the development of a novel photo-crosslinkable urocanic-acid-modified CS gel that exhibited significant potential to be utilized in the healing of corneal perforation.

show abstract

In vivo biocompatibility evaluation of in situ-forming polyethylene glycol-collagen hydrogels in corneal defects

Cited by 15 publications

References 41 publications

A Comprehensive Review on Collagen Type I Development of Biomaterials for Tissue Engineering: From Biosynthesis to Bioscaffold

A Comprehensive Review on Collagen Type I Development of Biomaterials for Tissue Engineering: From Biosynthesis to Bioscaffold

3D Bioprinting of Multi-Material Decellularized Liver Matrix Hydrogel at Physiological Temperatures

Novel Application of Photo-Crosslinked Urocanic-Acid-Modified Chitosan in Corneal Wounds

Contact Info

Product

Resources

About