Bioprinted Amniotic Fluid-Derived Stem Cells Accelerate Healing of Large Skin Wounds

Skardal, Aleksander; Mack, David L.; Kapetanovic, Edi; Atala, Anthony; Jackson, John D.; Yoo, James J.; Söker, Shay

doi:10.5966/sctm.2012-0088

Cited by 561 publications

(428 citation statements)

References 28 publications

(36 reference statements)

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“…La limite actuelle de la bio-impression in situ est qu'elle ne peut être utilisée que pour des pertes tissulaires localisées en superficie comme la peau ou la calvaria. Cette approche a été utilisée avec des imprimantes jet d'encre pour imprimer des cellules souches issues du liquide amniotique pour le traitement de brûlures [35]. Notre groupe a utilisé une imprimante laser pour imprimer de l'hydroxyapatite dans des défauts de calvaria [25].…”

Section: Des Modèles D'organe Ou De Tissuunclassified

Impression 3D en médecine régénératrice et ingénierie tissulaire

et al. 2017

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Section: Des Modèles D'organe Ou De Tissuunclassified

Impression 3D en médecine régénératrice et ingénierie tissulaire

et al. 2017

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“…Histological analyses also revealed that the newly formed skin contained organized dermal collagen and a fully developed epidermis. The same research group used a similar procedure and bioprinting technique to print amniotic fluidderived stem cells (AFSC) and bone marrow-derived mesenchymal stem cells (MSC) suspended in a fibrinogencollagen gel into full-thickness skin wounds in mice [184]. The cell-biomaterial solution was dispensed to the skin wounds (2.0 9 2.0 cm 2 ) with uniform cell distribution.…”

Section: Printed Skin Constructs For Wound Healingmentioning

confidence: 99%

“…In situ skin printing is challenging as it requires the development of dedicated bioprinting devices, the integration with imaging systems to obtain data from the wound site, and the design of bioinks capable of instructing printed cells to perform Cell liver spheroids Extrusion Liver [185] their native functions. Binder et al [18,184] developed a device for the in situ skin printing composed of a cartridge delivery system containing a series of inkjet nozzles and a laser scanning system, both mounted on a portable XYZ plotting system. The data obtained from the laser was used to reconstruct a 3D model of the wound, which was subsequently employed to determine the skin area that was missing from the wound.…”

Section: Printed Skin Constructs For Wound Healingmentioning

confidence: 99%

“…2) [90,95], with potential to address the limitations of current clinical therapies, including the vascularization, regeneration of skin appendages and integration with the host tissue [52,149]. Bioprinting processes also enable the integration with medical imaging techniques (e.g., microcomputed tomography, magnetic resonance imaging) and path-planning devices, allowing the design of patient specific implants for direct printing either in vitro or in situ [184,200].…”

Section: Extrusion Bioprintingmentioning

confidence: 99%

“…Bioprinting provides a powerful tool to arrange cells, biomaterials and soluble factors within a 3D environment on a length scale comparable to the complex heterogeneity found in natural tissue (10-100 lm), enabling new perspectives as well as unmatched possibilities in the design of biomimetic substitutes for tissue regeneration [10,80,125]. In the context of skin tissue engineering, bioprinting has been explored for the fabrication of 3D constructs containing skin cells positioned in distinct layers to resemble the anatomy of native skin [117,184].…”

Section: Introductionmentioning

confidence: 99%

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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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3D Printed Scaffolds for Wound Healing and Tissue Regeneration

Tabriz

Douroumis

Boateng

2020

Therapeutic Dressings and Wound Healing Applications

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2.1 Background 2.2 Aetiology of Diabetic Foot Ulcers 2.3 Standard of Care for Treatment of Diabetic Foot Ulcers 2.4 Commonly Used Wound Dressings for Diabetic Foot Ulcers and Their Mechanism of Action 2.5 Absorbent and Superabsorbent Dressings 2.6 Alginates 2.7 Films 2.8 Foams 2.9 Honeys 2.10 Hydrogels 2.11 The Role of a Split Thickness Skin Graft in Diabetic Foot Ulcers 2.12 Negative Pressure Wound Therapy 2.13 Larval Therapy 2.14 Clinical Case Studies from Multidisciplinary Diabetic Foot Clinic 2.14.1 Neuropathic Wound 2.14.2 Ischaemic Wound 2.14.3 Neuro-Ischaemic Wound 2.14.4 Osteomyelitis 2.14.5 Charcot's Foot 2.14.6 Necrotising Fasciitis in a Patient with Diabetes 2.15 Summary Acknowledgements References

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Bioprinted Amniotic Fluid-Derived Stem Cells Accelerate Healing of Large Skin Wounds

Cited by 561 publications

References 28 publications

Impression 3D en médecine régénératrice et ingénierie tissulaire

Impression 3D en médecine régénératrice et ingénierie tissulaire

Advances in bioprinted cell-laden hydrogels for skin tissue engineering

3D Printed Scaffolds for Wound Healing and Tissue Regeneration

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