3D-printed tissue repair patch combining mechanical support and magnetism for controlled skeletal muscle regeneration

Study of conductive nerve conduits for anti-inflammatory and antioxidant effects

Replacing autologous nerve grafts with nerve conduits is the prevailing direction for the treatment of peripheral nerves, though the repair of hollow nerve conduits remains unsatisfactory. In this study, cysteinylated zein (l-Zein) was prepared through a disulfide exchange reaction between the disulfide bonds of cysteine (Cys) and those of zein (Zein). Subsequently, electrospinning was utilized to fabricate hollow nerve conduits loaded with berberine (BBR) by means of hydrogen bonding and physical encapsulation. Hydrogels were prepared by ionic cross-linking of Zein with pectin (Pec), and were subsequently loaded with melatonin (MT) and graphene oxide (GO) through physical adsorption and encapsulation. A hydrogel was then injected into a hollow catheter to form a hydrogel composite nerve conduit (l-ZBZPGM). The hydrogels exhibited a continuous porous network structure with pore size distribution between 100 and 200 μm. Most of the hydrogels exhibited porosity exceeding 70% and the compressive modulus was 0.42 ± 0.025 MPa. A hydrogel exhibited a residual mass ratio of 35.15% ± 1.87% at the end of the 30 d degradation period, achieved peak release on day 18 with a release rate of 83.31% ± 3.64%, and had an electrical conductivity of 1.23 ± 0.482 × 10-3 S cm-1, meeting the requirements for nerve repair. The lack of cytotoxicity and the anti-inflammatory and antioxidant properties of l-ZBZPGM were demonstrated using RSC96 cells and Raw264.7 cells. Additionally, through electrical stimulation experiments, it was proven that the addition of GO can promote the proliferation of nerve cells. The biological materials used in this study are of simple composition, and their degradation products may have a minimal impact on the microenvironment. The findings suggested that l-ZBZPGM was more conductive to peripheral nerve regeneration.

Constructing a 3D co-culture in vitro synovial tissue model for rheumatoid arthritis research

The development and exploration of highly effective drugs for rheumatoid arthritis remains an urgent necessity. However, current disease research models are no longer sufficient to meet the rapid development of high-throughput drug screening. In this study, bacterial cellulose simulating the structure of extracellular matrix was used as a 3D culture platform, and THP-1-derived M1 macrophages, representing the inflammatory component, human umbilical vein endothelial cells (HUVECs), simulating the vascular component, and rheumatoid arthritis fibroblast-like synoviocytes (RA-FLSs), embodying the synovial pathology, were co-cultured to simulate the pathological microenvironment in RA synovial tissues, and synovial organoids were constructed. Under three-dimensional (3D) culture conditions, there was a notable upregulation of fatty acid-binding protein 4 (FABP4) in polarized macrophages, and an enhancement of pathological phenotypes in HUVECs and RA-FLSs, mediated through the PI3K/AKT signaling pathway, including cell proliferation, migration, invasion and vascularization. Compared to planar cultures and 2D co-cultures, 3D synovial organoids not only exhibit a broader range of transcriptomic features characteristic of rheumatoid arthritis but also demonstrate increased drug resistance, likely due to the more complex and physiologically relevant cell-cell and cell-matrix interactions present in 3D environments. This model offers a promising path for personalized treatment, accelerating precision medicine in rheumatology.

3D Nanofiber-Assisted Embedded Extrusion Bioprinting for Oriented Cardiac Tissue Fabrication

Three-dimensional (3D) bioprinting technology stands out as a promising tissue manufacturing process to control the geometry precisely with cell-loaded bioinks. However, the isotropic culture environment within the bioink and the lack of topographical cues impede the formation of oriented cardiac tissue. To overcome this limitation, we present a novel method named 3D nanofiber-assisted embedded bioprinting (3D-NFEP) to fabricate cardiac tissue with an oriented morphology. Aligned 3D nanofiber scaffolds were fabricated by divergence electrospinning, which provided structural support for printing of the low-viscosity bioink and structural induction to cardiomyocytes. Cells adhered to the aligned fibers after hydrogel degradation, and a high degree of cell alignment was observed. This technology was also demonstrated as a feasible solution for multilayer cell printing. Therefore, 3D-NFEP was demonstrated as a promising method for bioprinting oriented cardiac tissue with low-viscosity bioink and is expected to be applied for structured and cardiac tissue engineering.

3D Printing of Polysaccharide-Based Hydrogel Scaffolds for Tissue Engineering Applications: A Review

In tissue engineering, 3D printing represents a versatile technology employing inks to construct three-dimensional living structures, mimicking natural biological systems. This technology efficiently translates digital blueprints into highly reproducible 3D objects. Recent advances have expanded 3D printing applications, allowing for the fabrication of diverse anatomical components, including engineered functional tissues and organs. The development of printable inks, which incorporate macromolecules, enzymes, cells, and growth factors, is advancing with the aim of restoring damaged tissues and organs. Polysaccharides, recognized for their intrinsic resemblance to components of the extracellular matrix have garnered significant attention in the field of tissue engineering. This review explores diverse 3D printing techniques, outlining distinctive features that should characterize scaffolds used as ideal matrices in tissue engineering. A detailed investigation into the properties and roles of polysaccharides in tissue engineering is highlighted. The review also culminates in a profound exploration of 3D polysaccharide-based hydrogel applications, focusing on recent breakthroughs in regenerating different tissues such as skin, bone, cartilage, heart, nerve, vasculature, and skeletal muscle. It further addresses challenges and prospective directions in 3D printing hydrogels based on polysaccharides, paving the way for innovative research to fabricate functional tissues, enhancing patient care, and improving quality of life.

Advances in electrospinning and 3D bioprinting strategies to enhance functional regeneration of skeletal muscle tissue

Skeletal muscles are essential for body movement, and the loss of motor function due to volumetric muscle loss (VML) limits the mobility of patients. Current therapeutic approaches are insufficient to offer complete functional recovery of muscle damages. Tissue engineering provides viable ways to fabricate scaffolds to regenerate damaged tissues. Hence, tissue engineering options are explored to address existing challenges in the treatment options for muscle regeneration. Electrospinning is a widely employed fabrication technique to make muscle mimetic nanofibrous scaffolds for tissue regeneration. 3D bioprinting has also been utilized to fabricate muscle-like tissues in recent times. This review discusses the anatomy of skeletal muscle, defects, the healing process, and various treatment options for VML. Further, the advanced strategies in electrospinning of natural and synthetic polymers are discussed, along with the recent developments in the fabrication of hybrid scaffolds. Current approaches in 3D bioprinting of skeletal muscle tissues are outlined with special emphasis on the combination of electrospinning and 3D bioprinting towards the development of fully functional muscle constructs. Finally, the current challenges and future perspectives of these convergence techniques are discussed.