Intra‐Operative Bioprinting of Hard, Soft, and Hard/Soft Composite Tissues for Craniomaxillofacial Reconstruction

Moncal, Kazim K.; Gudapati, Hemanth; Godzik, Kevin P.; Heo, Dong Nyoung; Kang, Young-Nam; Rizk, Elias; Ravnic, Dino J.; Wee, Hwabok; Pepley, David F.; Özbolat, Veli; Lewis, Gregory S.; Moore, Jason Z.; Driskell, Ryan R.; Samson, Thomas D.; Özbolat, İbrahim T.

doi:10.1002/adfm.202010858

Cited by 41 publications

(32 citation statements)

References 82 publications

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“…Additionally, owing to the design flexibility and anatomical accuracy, 3D bioprinting technology has been widely employed for the fabrication of both living cell-laden and acellular biomimetic constructs in tissue engineering [ 29 – 34 ]. In particular, some attempts have been performed by in situ bioprinting of tissue constructs at defect sites, which enables accurate filling of irregular-shaped defects and concurrence of in vivo integration with native tissues [ 35 – 40 ]. Thus, it is conceivable that the in situ bioprinting of the photosynthetic microalgae into wound sites would provide a self-adaptive platform with an autotrophic oxygen supply for versatile wound healing.…”

Section: Introductionmentioning

confidence: 99%

In Situ 3D Bioprinting Living Photosynthetic Scaffolds for Autotrophic Wound Healing

Wang

Yang

et al. 2022

Research

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Three-dimensional (3D) bioprinting has been extensively explored for tissue repair and regeneration, while the insufficient nutrient and oxygen availability in the printed constructs, as well as the lack of adaptive dimensions and shapes, compromises the overall therapeutic efficacy and limits their further application. Herein, inspired by the natural symbiotic relationship between salamanders and algae, we present novel living photosynthetic scaffolds by using an in situ microfluidic-assisted 3D bioprinting strategy for adapting irregular-shaped wounds and promoting their healing. As the oxygenic photosynthesis unicellular microalga (Chlorella pyrenoidosa) was incorporated during 3D printing, the generated scaffolds could produce sustainable oxygen under light illumination, which facilitated the cell proliferation, migration, and differentiation even in hypoxic conditions. Thus, when the living microalgae-laden scaffolds were directly printed into diabetic wounds, they could significantly accelerate the chronic wound closure by alleviating local hypoxia, increasing angiogenesis, and promoting extracellular matrix (ECM) synthesis. These results indicate that the in situ bioprinting of living photosynthetic microalgae offers an effective autotrophic biosystem for promoting wound healing, suggesting a promising therapeutic strategy for diverse tissue engineering applications.

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Section: Introductionmentioning

confidence: 99%

In Situ 3D Bioprinting Living Photosynthetic Scaffolds for Autotrophic Wound Healing

Wang

Yang

et al. 2022

Research

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“…Each offers its own set of advantageous and disadvantages, signifying that widespread clinical translation is not yet on the immediate horizon. However, research is progressing rapidly across a multitude of diverse applications, such as breast reconstruction ( 132 ), craniomaxillofacial injuries ( 133 ), and cardiovascular repair ( 134 ).…”

Section: Manufacturingmentioning

confidence: 99%

Regenerative Engineering: Current Applications and Future Perspectives

et al. 2021

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Many pathologies, congenital defects, and traumatic injuries are untreatable by conventional pharmacologic or surgical interventions. Regenerative engineering represents an ever-growing interdisciplinary field aimed at creating biological replacements for injured tissues and dysfunctional organs. The need for bioengineered replacement parts is ubiquitous among all surgical disciplines. However, to date, clinical translation has been limited to thin, small, and/or acellular structures. Development of thicker tissues continues to be limited by vascularization and other impediments. Nevertheless, currently available materials, methods, and technologies serve as robust platforms for more complex tissue fabrication in the future. This review article highlights the current methodologies, clinical achievements, tenacious barriers, and future perspectives of regenerative engineering.

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“…For instance, 2D MRI (magnetic resonance images) images of the craniomaxillofacial defects in rodents were converted into 3D models, which were then utilized for printing accurate structures. 18 Despite the rapid advancements in 3D printing in recent years, their clinical success is limited by the critical need to engineer means for the supply of oxygen and nutrients upon implantation. Diffusion alone can only supply cells in proximity of 100 to 200 μm from the nearest capillary in tissues.…”

Section: Introductionmentioning

confidence: 99%

“…There are specialized software to render clinical 2D images of the patient’s anatomy into 3D models, which can then be used as input files for printing. For instance, 2D MRI (magnetic resonance images) images of the craniomaxillofacial defects in rodents were converted into 3D models, which were then utilized for printing accurate structures …”

Section: Introductionmentioning

confidence: 99%

Strategies to Promote Vascularization in 3D Printed Tissue Scaffolds: Trends and Challenges

et al. 2022

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Three-dimensional (3D) printing techniques for scaffold fabrication have shown promising advancements in recent years owing to the ability of the latest high-performance printers to mimic the native tissue down to submicron scales. Nevertheless, host integration and performance of scaffolds in vivo have been severely limited owing to the lack of robust strategies to promote vascularization in 3D printed scaffolds. As a result, researchers over the past decade have been exploring strategies that can promote vascularization in 3D printed scaffolds toward enhancing scaffold functionality and ensuring host integration. Various emerging strategies to enhance vascularization in 3D printed scaffolds are discussed. These approaches include simple strategies such as the enhancement of vascular in-growth from the host upon implantation by scaffold modifications to complex approaches wherein scaffolds are fabricated with their own vasculature that can be directly anastomosed or microsurgically connected to the host vasculature, thereby ensuring optimal integration. The key differences among the techniques, their pros and cons, and the future opportunities for utilizing each technique are highlighted here. The Review concludes with the current limitations and future directions that can help 3D printing emerge as an effective biofabrication technique to realize tissues with physiologically relevant vasculatures to ultimately accelerate clinical translation.

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Intra‐Operative Bioprinting of Hard, Soft, and Hard/Soft Composite Tissues for Craniomaxillofacial Reconstruction

Cited by 41 publications

References 82 publications

In Situ 3D Bioprinting Living Photosynthetic Scaffolds for Autotrophic Wound Healing

In Situ 3D Bioprinting Living Photosynthetic Scaffolds for Autotrophic Wound Healing

Regenerative Engineering: Current Applications and Future Perspectives

Strategies to Promote Vascularization in 3D Printed Tissue Scaffolds: Trends and Challenges

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