Comparison of the biological properties between 3D-printed and decellularized tracheal grafts

Bioengineered tracheal graft with enhanced vascularization and mechanical stability for functional airway reconstruction

Tracheal reconstruction remains a formidable clinical challenge due to the complex structural, biomechanical, and physiological requirements of the airway. Traditional approaches, including autologous grafts, allografts, and synthetic prostheses, suffer from limitations such as donor site morbidity, immune rejection, and mechanical instability. Tissue-engineered tracheal grafts have emerged as a promising alternative, integrating advanced biomaterials, cellular therapies, and biofabrication techniques to create functional airway replacements. Synthetic polymers, such as polycaprolactone and polylactic acid, provide mechanical stability and tunable degradation properties, while extracellular matrix - derived biomaterials enhance biocompatibility and support cellular integration. Recent advances in stem cell biology, particularly the application of mesenchymal stem cells, induced pluripotent stem cells, and adipose-derived stem cells, have facilitated cartilage regeneration, epithelialization, and immune modulation within engineered constructs. However, achieving adequate vascularization remains a major bottleneck, necessitating the development of pre-vascularized scaffolds, growth factor delivery systems, and in vivo bioreactor strategies. Emerging technologies, including 3D bioprinting, electrospinning, and AI-driven scaffold design, are transforming the landscape of tracheal tissue engineering by enabling precise control over scaffold architecture, cellular distribution, and functional integration. Despite these advances, challenges such as mechanical failure, chronic inflammation, and regulatory hurdles must be addressed to ensure clinical translation. This review critically examines the latest advancements, persisting challenges, and future perspectives in artificial trachea engineering, providing a comprehensive roadmap for its development and clinical implementation.

Fiber-reinforced gelatin-based hydrogel biocomposite tubular scaffolds with programmable mechanical properties

Tissue-engineered tubular scaffolds (TETS) provide an effective repair solution for human tubular tissue loss and damage caused by congenital defects, disease, or mechanical trauma. However, there are still major challenges to developing TETS with excellent mechanical properties and biocompatibility for human tubular tissue repair. Gelatin-based hydrogels are suitable candidates for tissue-engineered scaffolds because they are hydrolyzed collagen products and have excellent biocompatibility and degradability. However, the mechanical properties of gelatin-based hydrogels are relatively poor and do not align well with the mechanical properties of human tubular tissues. Inspired by the extracellular matrix architecture of human tubular tissues, this study utilizes high-precision 3D printing to fabricate ultrafine fiber network tubular scaffolds (UFNTS) that mimic the arrangement of collagen fibers, which are then embedded in a cell-compatible gelatin-based hydrogel, resulting in the preparation of a fiber/hydrogel biocomposite tubular scaffold (BCTS) with tunable mechanical properties and a J-shaped stress-strain response. Finite element analysis was employed to predict the mechanical behavior of the UFNTS and BCTS. Experimental results indicate that by modifying the structural parameters of the UFNTS, the mechanical properties of the BCTS can be effectively tuned, achieving a programmable range of tensile modulus (0.2-4.35 MPa) and burst pressure (1580-7850 mmHg), which broadly covers the mechanical properties of most human tubular tissues. The design and fabrication of BCTS offer a new approach for the development of TETS while also providing a personalized strategy for such scaffolds in tissue engineering.

Decellularization techniques: unveiling the blueprint for tracheal tissue engineering

Certain congenital or acquired diseases and defects such as tracheo-oesophageal fistula, tracheomalacia, tracheal stenosis, airway ischemia, infections, and tumours can cause damage to the trachea. Treatments available do not offer any permanent solutions. Moreover, long-segment defects in the trachea have no available surgical treatments. Tissue engineering has gained popularity in current regenerative medicine as a promising approach to bridge this gap. Among the various tissue engineering techniques, decellularization is a widely used approach that removes the cellular and nuclear contents from the tissue while preserving the native extracellular matrix components. The decellularized scaffolds exhibit significantly lower immunogenicity and retain the essential biomechanical and proangiogenic properties of native tissue, creating a foundation for trachea regeneration. The present review provides an overview of trachea decellularization advancements, exploring how recellularization approaches can be optimized by using various stem cells and tissue-specific cells to restore the scaffold's structure and function. We examine critical factors such as mechanical properties, revascularization, and immunogenicity involved in the transplantation of tissue-engineered grafts.

Water-Induced Expanded Bilayer Vascular Graft with Good Hemocompatibility and Biocompatibility

Shape memory polymer (SMP) vascular grafts are promising interventional vascular grafts for cardiovascular disease (CAD) treatment; However, hemocompatibility and biocompatibility, which are the critical issues for the SMP vascular grafts, are not systematically concerned. Furthermore, the water-induced SMP grafts are more convenient and safer than the thermally induced ones in case of the bioapplication. Herein, in this work, the new water-induced expanded bilayer vascular graft with the inner layer of crosslinked poly(ε-caprolactone) (cPCL) and the outer layer of water-induced SMP of regenerated chitosan/polyvinyl alcohol (RCS/PVA) are prepared by hot pressing and programming approaches. The results show that the inner and outer layer surfaces of the prepared grafts are smooth, and they exhibit good interfacial interaction properties. The bilayer grafts show good mechanical properties and can be expanded in water with a diameter expansion of ≈30%. When compared with commercial expanded polytetrafluoroethylene (ePTFE), the bilayer graft shows better hemocompatibility (platelet adhesion, hemolysis rate, various clotting times, and plasma recalcification time (PRT)) and in vitro and in vivo biocompatibility, which thus is a promising material for the vascular graft.

Current Strategies for Tracheal Decellularization: A Systematic Review

The process of decellularization is crucial for producing a substitute for the absent tracheal segment, and the choice of agents and methods significantly influences the outcomes. This paper aims to systematically review the efficacy of diverse tracheal decellularization agents and methods using the PRISMA flowchart. Inclusion criteria encompassed experimental studies published between 2018 and 2023, written in English, and detailing outcomes related to histopathological anatomy, DNA quantification, ECM evaluation, and biomechanical characteristics. Exclusion criteria involved studies related to 3D printing, biomaterials, and partial decellularization. A comprehensive search on PubMed, NCBI, and ScienceDirect yielded 17 relevant literatures. The integration of various agents and methods has proven effective in the process of tracheal decellularization, highlighting the distinct advantages and drawbacks associated with each agent and method.