A Bioprinted Bruch's Membrane for Modeling Smoke‐Induced Retinal Pigment Epithelium Degeneration via Hybrid Membrane Printing Technology

Kim, Jongmin; Kong, Jeong Sik; Kim, Hyeonji; Jo, Yong Hee; Cho, Dong‐Woo; Jang, Jinah

doi:10.1002/adhm.202200728

Cited by 12 publications

(6 citation statements)

References 40 publications

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“…Subsequently, they utilized a 3% gelatin bioink to bioprint retinal pigment epithelial cells on the top layer, producing a single-cell layer. In vitro experiments have demonstrated that this organoid bioink-printed blood-retinal barrier model displays functions related to barrier clearance, vision, and maintenance [137] (figures 12(A)-(C)). In another study, Kapil Bharti successfully utilized bioprinting to create a natural, three-dimensional oBRB tissue.…”

Section: Retinamentioning

confidence: 99%

Organoid bioinks: construction and application

Wang,

Song,

Wang

et al. 2024

Biofabrication

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Organoids have emerged as crucial platforms in tissue engineering and regenerative medicine but confront challenges in faithfully mimicking native tissue structures and functions. Bioprinting technologies offer a significant advancement, especially when combined with organoid bioinks-engineered formulations designed to encapsulate both the architectural and functional elements of specific tissues. This review provides a rigorous, focused examination of the evolution and impact of organoid bioprinting. It emphasizes the role of organoid bioinks that integrate key cellular components and microenvironmental cues to more accurately replicate native tissue complexity. Furthermore, this review anticipates a transformative landscape invigorated by the integration of artificial intelligence with bioprinting techniques. Such fusion promises to refine organoid bioink formulations and optimize bioprinting parameters, thus catalyzing unprecedented advancements in regenerative medicine. In summary, this review accentuates the pivotal role and transformative potential of organoid bioinks and bioprinting in advancing regenerative therapies, deepening our understanding of organ development, and clarifying disease mechanisms.

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Section: Retinamentioning

confidence: 99%

Organoid bioinks: construction and application

Wang,

Song,

Wang

et al. 2024

Biofabrication

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“…Three-dimensional bioprinted retinal tissue models can also be used to study external environmental factors on ocular health. Kim et al found that oxidative stress induced by cigarette smoke can disrupt RPE tight junction strength and blood–retinal barrier function [ 66 ]. This information can be used to further explore causative links between smoking and retinal degeneration.…”

Section: Retinal Applicationsmentioning

confidence: 99%

Towards Precision Ophthalmology: The Role of 3D Printing and Bioprinting in Oculoplastic Surgery, Retinal, Corneal, and Glaucoma Treatment

Wu,

Tabari,

Mazerolle

et al. 2024

Biomimetics

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In the forefront of ophthalmic innovation, biomimetic 3D printing and bioprinting technologies are redefining patient-specific therapeutic strategies. This critical review systematically evaluates their application spectrum, spanning oculoplastic reconstruction, retinal tissue engineering, corneal transplantation, and targeted glaucoma treatments. It highlights the intricacies of these technologies, including the fundamental principles, advanced materials, and bioinks that facilitate the replication of ocular tissue architecture. The synthesis of primary studies from 2014 to 2023 provides a rigorous analysis of their evolution and current clinical implications. This review is unique in its holistic approach, juxtaposing the scientific underpinnings with clinical realities, thereby delineating the advantages over conventional modalities, and identifying translational barriers. It elucidates persistent knowledge deficits and outlines future research directions. It ultimately accentuates the imperative for multidisciplinary collaboration to enhance the clinical integration of these biotechnologies, culminating in a paradigm shift towards individualized ophthalmic care.

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“…In vivo , transparency of the R5-CEC membranes was better maintained than acellular membranes, demonstrating that cell engineering and 3DP delivery of CECs led to better cell survival and function. Similarly, another group used 3DP to generate a multilayered structure consisting of a vitrified decellularized Bruch’s membrane (BM) layer with retinal pigment epithelial (RPE) cells encapsulated in a sacrificial gelatin layer on top . This structure functioned as a model of the outer blood–retinal barrier to assess the disease conditions on RPE cell function.…”

Section: Fabrication Strategiesmentioning

confidence: 99%

“…Similarly, another group used 3DP to generate a multilayered structure consisting of a vitrified decellularized Bruch's membrane (BM) layer with retinal pigment epithelial (RPE) cells encapsulated in a sacrificial gelatin layer on top. 110 This structure functioned as a model of the outer blood−retinal barrier to assess the disease conditions on RPE cell function. Bioprinting allowed functional monolayer formation of RPE cells on the basement membrane to accurately replicate native anatomy, and the effects of cigarette smoke extract on cell function were evaluated.…”

Section: T H I S C O N T E N T Imentioning

confidence: 99%

Fabrication Strategies for Engineered Thin Membranous Tissues

McLoughlin

McKenna

Fisher

2023

ACS Appl. Bio Mater.

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Thin membranous tissues (TMTs) are anatomical structures consisting of multiple stratified cell layers, each less than 100 μm in thickness. While these tissues are small in scale, they play critical roles in normal tissue function and healing. Examples of TMTs include the tympanic membrane, cornea, periosteum, and epidermis. Damage to these structures can be caused by trauma or congenital disabilities, resulting in hearing loss, blindness, dysfunctional bone development, and impaired wound repair, respectively. While autologous and allogeneic tissue sources for these membranes exist, they are significantly limited by availability and patient complications. Tissue engineering has therefore become a popular strategy for TMT replacement. However, due to their complex microscale architecture, TMTs are often difficult to replicate in a biomimetic manner. The critical challenge in TMT fabrication is balancing fine resolution with the ability to mimic complex target tissue anatomy. This Review reports existing TMT fabrication strategies, their resolution and material capabilities, cell and tissue response, and the advantages and disadvantages of each technique.

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A Bioprinted Bruch's Membrane for Modeling Smoke‐Induced Retinal Pigment Epithelium Degeneration via Hybrid Membrane Printing Technology

Cited by 12 publications

References 40 publications

Organoid bioinks: construction and application

Organoid bioinks: construction and application

Towards Precision Ophthalmology: The Role of 3D Printing and Bioprinting in Oculoplastic Surgery, Retinal, Corneal, and Glaucoma Treatment

Fabrication Strategies for Engineered Thin Membranous Tissues

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