Three-dimensional (3D) printed scaffolds have recently emerged as an innovative treatment option for patients with critical-sized skin wounds. Current approaches to managing life-threatening wounds include skin grafting and application of commercially sourced skin substitutes. However, these approaches are not without several challenges. Limited donor tissue and donor site morbidity remain a concern for tissue grafting, while engineered skin substitutes fail to fully recapitulate the complex native environment required for wound healing. The implementation of 3D printed dermal scaffolds offers a potential solution for these shortcomings. Spatial control over scaffold structure, the ability to incorporate multiple materials and bioactive ingredients, enables the creation of conditions specifically optimized for wound healing. Three-dimensional bioprinting, a subset of 3D printing, allows for the replacement of lost cell populations and secreted active compounds that contribute to tissue repair and recovery. The replacement of damaged and lost cells delivers beneficial effects directly, or synergistically, supporting injured tissue to recover its native state. Despite encouraging results, the promise of 3D printed scaffolds has yet to be realized. Further improvements to current material formulations and scaffold designs are required to achieve the goal of clinical adoption. Herein, we provide an overview of 3D printing techniques and discuss several strategies for healing of full-thickness wounds by using 3D printed acellular scaffolds or bioprinted cellular scaffolds, aimed at translating this technology to the clinical management of skin lesions. We identify the challenges associated with designing and optimizing printed tissue replacements, and discuss the future perspectives of this emerging option for managing patients who present with critical-sized life-threatening cutaneous wounds. Impact statement Chronic wounds and burn injuries often present with the full-thickness loss of skin, threatening the life of the patient and generating significant socioeconomic burden for these patients, their treating clinicians, and the wider community in which these patients live. Effective clinical management that permits damaged skin tissue to repair and restore its native functional state reduces the strain on health care systems. Three-dimensional (3D) printed scaffolds have been proposed as a potential solution and could be instrumental in facilitating the recovery and healing process. In this review, we will summarize the current research approaches, technologies, and limitations of 3D printed scaffolds as an efficient and effective approach to managing cutaneous wound healing.
Keywords: 3D printing; full-thickness wounds; skin tissue scaffolds.