<i>In Vivo</i> Assessment of Printed Microvasculature in a Bilayer Skin Graft to Treat Full-Thickness Wounds

Yanez, Maria; Rincon, Julio; Dones, Aracely; Maria, Carmelo De; Gonzales, Raoul; Boland, Thomas

doi:10.1089/ten.tea.2013.0561

Cited by 137 publications

(122 citation statements)

References 32 publications

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“…In one study Boland's group used it as a bioink constituent to investigate adhesion and proliferation of cells on collagen-coated cell repellant substrates [91]. Also, Boland's group fabricated a bilayer skin graft, which generated neoskin identical to native skin with microvessels [92]. In another study, fibrin-collagen bioink comprising one of the two cell types, AFSCs or mesenchymal stem cells (MSCs), was bioprinted into wound sites for treating surgical skin wounds [93].…”

Section: The Bioink Considerationmentioning

confidence: 99%

See 1 more Smart Citation

A comprehensive review on droplet-based bioprinting: Past, present and future

2016

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Droplet-based bioprinting (DBB) offers greater advantages due to its simplicity and agility with precise control on deposition of biologics including cells, growth factors, genes, drugs and biomaterials, and has been a prominent technology in the bioprinting community. Due to its immense versatility, DBB technology has been adopted by various application areas, including but not limited to, tissue engineering and regenerative medicine, transplantation and clinics, pharmaceutics and high-throughput screening, and cancer research. Despite the great benefits, the technology currently faces several challenges such as a narrow range of available bioink materials, bioprinting-induced cell damage at substantial levels, limited mechanical and structural integrity of bioprinted constructs, and restrictions on the size of constructs due to lack of vascularization and porosity. This paper presents a first-time review of DBB and comprehensively covers the existing DBB modalities including inkjet, electrohydrodynamic, acoustic, and micro-valve bioprinting. The recent notable studies are highlighted, the relevant bioink biomaterials and bioprinters are expounded, the application areas are presented, and the future prospects are provided to the reader.

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Section: The Bioink Considerationmentioning

confidence: 99%

“…It plays a significant role in wound healing and has been used to fabricate skin grafts [92,93]. Boland's group used fibrin to engineer micro-capillaries by bioprinting human dermal microvascular endothelial cells (HMVECs)-laden thrombin and Ca 2+ solution on a fibrinogen substrate [52].…”

Section: The Bioink Considerationmentioning

confidence: 99%

A comprehensive review on droplet-based bioprinting: Past, present and future

2016

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“…Bioprinting technologies are attractive to engineer a vascular tree within thick constructs by the precise layer by layer deposition of multiple cell types and ECMlike bioinks into prescribed spatial locations at high resolution [202]. Promising approaches to generate vascular networks have been reported using inkjet [34,209], laserassisted [203], and extrusion bioprinting [16,92,132]. In general, such approaches are based on four main strategies: (1) direct patterning vascular cells onto a receiving substrate [203], (2) continuous printing of polymeric bioink loaded with endothelial cells followed by polymer removal [96], (3) printing perfusable channels in a 3D construct for subsequent injection of a cell suspension into the empty channel [92], and (4) printing of multicellular spheroids [132].…”

Section: Printed Vascularized Skin Constructsmentioning

confidence: 99%

“…To address the need for vascularization in skin substitutes, Yanez et al [209] used the inkjet technology to fabricate capillary-like endothelial networks into a dermoepidermal skin graft consisting of neonatal human dermal fibroblasts (NHDFs) and neonatal human epidermal keratinocytes (NHEKs) embedded in a fibrin-collagen matrix. HMVEC were mixed with thrombin and inkjet printed on top of a manually plated layer of collagen-NHDF cells containing fibrinogen.…”

Section: Printed Vascularized Skin Constructsmentioning

confidence: 99%

Advances in bioprinted cell-laden hydrogels for skin tissue engineering

et al. 2017

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Bioprinting technologies are powerful additive biofabrication techniques to produce cellular constructs for skin tissue engineering owing to their unique ability to precisely pattern living and non-living materials in predefined spatial locations. This unique feature, combined with the computer controlled printing and medical imaging techniques, enable researchers and clinicians to generate patient specific constructs partly replicating the intricate compositional and architectural organization of the skin. Bioprinting has been used to automatically dispense hydrogels with skin cells located in prescribed sites that promote skin formation in vitro and in vivo. Current skin bioprinting approaches mostly rely on the sequential printing of fibroblasts and keratinocytes embedded within a homogeneous hydrogel. Although such approaches have already been translated to pre-clinical scenarios, they still present limitations in terms of fully replicating the cellular and extracellular matrix (ECM) heterogeneity in native skin. The success of bioprinting for skin repair strongly depends on the design of printable bioinks capable of supporting the function of printed cells and stimulating the production of new ECM components. To better mimic the human skin, novel developments in dedicated bioprinting technologies, in the design of bioinks, as well as in the printing of vascularised constructs are necessary. This paper presents an overview regarding the use of bioprinting for skin tissue engineering applications. The operating principles of bioprinting technologies are outlined along with requirements of printed skin constructs. Finally, preclinical results are summarized and future perspectives for the field are highlighted.

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“…[102] Skin tissues were engineered recently. [103,104] A US-based research institute generated skin tissue in vitro with comparable biological and morphological characteristics to the native human skin. [105] The tissue consisted of alternating layers of collagen, fibroblasts, and keratinocytes.…”

Section: Bioprinted Skinmentioning

confidence: 99%

3D Miniaturization of Human Organs for Drug Discovery

Park

Wetzel

Dréau

et al. 2017

Adv Healthcare Materials

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“Engineered human organs” hold promises for predicting the effectiveness and accuracy of drug responses while reducing cost, time, and failure rates in clinical trials. Multiorgan human models utilize many aspects of currently available technologies including self‐organized spherical 3D human organoids, microfabricated 3D human organ chips, and 3D bioprinted human organ constructs to mimic key structural and functional properties of human organs. They enable precise control of multicellular activities, extracellular matrix (ECM) compositions, spatial distributions of cells, architectural organizations of ECM, and environmental cues. Thus, engineered human organs can provide the microstructures and biological functions of target organs and advantageously substitute multiscaled drug‐testing platforms including the current in vitro molecular assays, cell platforms, and in vivo models. This review provides an overview of advanced innovative designs based on the three main technologies used for organ construction leading to single and multiorgan systems useable for drug development. Current technological challenges and future perspectives are also discussed.

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In Vivo Assessment of Printed Microvasculature in a Bilayer Skin Graft to Treat Full-Thickness Wounds

Cited by 137 publications

References 32 publications

A comprehensive review on droplet-based bioprinting: Past, present and future

A comprehensive review on droplet-based bioprinting: Past, present and future

Advances in bioprinted cell-laden hydrogels for skin tissue engineering

3D Miniaturization of Human Organs for Drug Discovery

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