Creation of Porous, Perfusable Microtubular Networks for Improved Cell Viability in Volumetric Hydrogels.

The creation of large, volumetric tissue-engineered constructs has long been hindered due to the lack of effective vascularization strategies. Recently, 3D printing has emerged as a viable approach to creating vascular structures; however, its application is limited. Here, we present a simple and controllable technique to produce porous, free-standing, perfusable tubular networks from sacrificial templates of polyelectrolyte complex and coatings of salt-containing citrate-based elastomer poly(1,8-octanediol-co-citrate) (POC). As demonstrated, fully perfusable and interconnected POC tubular networks with channel diameters ranging from 100 to 400 µm were created. Incorporating NaCl particulates into the POC coating enabled the formation of micropores (∼19 µm in diameter) in the tubular wall upon particulate leaching to increase the cross-wall fluid transport. Casting and cross-linking gelatin methacrylate (GelMA) suspended with human osteoblasts over the free-standing porous POC tubular networks led to the fabrication of 3D cell-encapsulated constructs. Compared to the constructs without POC tubular networks, those with either solid or porous wall tubular networks exhibited a significant increase in cell viability and proliferation along with healthy cell morphology, particularly those with porous networks. Taken together, the sacrificial template-assisted approach is effective to fabricate tubular networks with controllable channel diameter and patency, which can be easily incorporated into cell-encapsulated hydrogels or used as tissue-engineering scaffolds to improve cell viability.

Biomimetic Extracellular Matrix Nanofibers Electrospun with Calreticulin Promote Synergistic Activity for Tissue Regeneration.

In recognition of the potential of calreticulin (CRT) protein in enhancing the rate and quality of wound healing in excisional animal wound models, this study was to incorporate CRT via polyblend electrospinning into polycaprolactone (PCL)/type 1 collagen (Col1) nanofibers (NFs; 334 ± 75 nm diameter) as biomimetic extracellular matrices to provide a novel mode of delivery and protection of CRT with enhanced synergistic activities for tissue regeneration. Release kinetic studies using fluoresceinated CRT (CRT-FITC) polyblend NFs showed a burst release within 4 h reaching a plateau at 72 h, with further intervals of release upon incubation with fresh phosphate buffered saline for up to 8 weeks. By measuring fluorescence during the first 4 h of release, CRT-FITC-containing NFs were shown to protect CRT from proteolytic digestion (e.g., by subtilisin) compared to CRT-FITC in solution. CRT incorporated into NFs (CRT-NFs) also showed retention of biological activities and potency for stimulating proliferation and migration of human keratinocytes and fibroblasts. Fibroblasts seeded on CRT-NFs, after 2 days, showed increased amounts of fibronectin, TGF-ß1, and integrin ß1 in cell lysates by immunoblotting. Compared to NFs without CRT, CRT-NFs supported cell responses consistent with greater cell polarization and increased laminin-5 deposition of keratinocytes and a more motile phenotype of fibroblasts, as suggested by vinculin-capping F-actin fibers nonuniformly located throughout the cell body and the secretion of phosphorylated focal adhesion kinase-enriched migrasomes. Altogether, CRT electrospun into PCL/Col1 NFs retained its structural integrity and biological functions while having additional benefits of customizable loading, protection of CRT from proteolytic degradation, and sustained release of CRT from NFs, coupled with innate physicochemical cues of biomimetic PCL/Col1 NFs. Such synergistic activities have potential for healing recalcitrant wounds such as diabetic foot ulcers.

A Comprehensive Assessment on the Pivotal Role of Hydrogels in Scaffold-Based Bioprinting.

The past a few decades have seen exponential growth in the field of regenerative medicine. What began as extirpative (complete tissue or organ removal), with little regard to the effects of tissue loss and/or disfigurement, has evolved towards fabricating engineered tissues using personalized living cells (e.g., stem cells), and customizing a matrix or structural organization to support and guide tissue development. Biofabrication, largely accomplished through three-dimensional (3D) printing technology, provides precise, controlled, and layered assemblies of cells and biomaterials, emulating the heterogenous microenvironment of the in vivo tissue architecture. This review provides a concise framework for the bio-manufacturing process and addresses the contributions of hydrogels to biological modeling. The versatility of hydrogels in bioprinting is detailed along with an extensive elaboration of their physical, mechanical, and biological properties, as well as their assets and limitations in bioprinting. The scope of various hydrogels in tissue formation has been discussed through the case studies of biofabricated 3D constructs in order to provide the readers with a glimpse into the barrier-breaking accomplishments of biomedical sciences. In the end, the restraints of bioprinting itself are discussed, accompanied with the identification of available engineering strategies to overcome them.