Materials For Regeneration Research Articles

Dual-color fluorescent multi-component hybrid materials for copper ion detection, NADH regeneration and cell imaging

Gold nanoclusters (AuNCs) exhibit unique physical, chemical and photoelectric properties with various advantages. On the other hand, small organic fluorescent molecules show alternative specialized characteristics. To overcome their weaknesses and integrate strengths, we propose here a workable platform to fabricate protein-gold-dye multifunctional hybrid materials. Briefly, protein skeleton bovine serum albumin (BSA), AuNCs, and organic molecule dye Thioflavin T (ThT) are co-assembled mutually to form a dual-color fluorescent material BSA-AuNCs@ThT. This approach is simple, cost-effective, green and environmental friendly. To tackle their biological application, we coat BSA-AuNCs@ThT with cationic polyethyleneimine (PEI). The prepared BSA-AuNCs@ThT@PEI hybrid materials can be used to fluorescence imaging of microbial cells as well as HeLa cells. Due to the unique background of BSA-AuNCs@ThT@PEI, the hybrid materials work well in differentiate heavy metal ions such as Hg2+ and Cu2+ ions. Moreover, this system is also suitable to do the photocatalytic transformation and regeneration of coenzyme NADH. Therefore, we propose this platform to build new nano-dye hybrid materials for copper ion detection, NADH regeneration and cell imaging, or potentially other applications.

In Vivo Evaluation of Demineralized Bone Matrix with Cancellous Bone Putty Formed Using Hydroxyethyl Cellulose as an Allograft Material in a Canine Tibial Defect Model.

Demineralized bone matrix (DBM) is a widely used allograft material for bone repair, but its handling properties and retention at defect sites can be challenging. Hydroxyethyl cellulose (HEC) has shown promise as a biocompatible carrier for bone graft materials. This study aimed to evaluate the efficacy of DBM combined with cancellous bone putty formed using HEC as an allograft material for bone regeneration in a canine tibial defect model. Experiments were conducted using dogs with proximal tibial defects. Four groups were compared: empty (control group), DBM + HEC (DH), DBM + cancellous bone + HEC (DCH), and DBM + cancellous bone + calcium phosphate + HEC (DCCH). Radiographic, micro-computed tomography (CT), and histomorphometric evaluations were performed 4 and 8 weeks postoperatively to assess bone regeneration. The Empty group consistently exhibited the lowest levels of bone regeneration throughout the study period, indicating that DBM and cancellous bone with HEC significantly enhanced bone regeneration. At week 4, the DCCH group showed the fastest bone regeneration on radiography and micro-computed tomography. By week 8, the DCH group showed the highest area ratio of new bone among all experimental areas, followed by the DH and DCCH groups. This study demonstrated that HEC significantly enhances the handling, mechanical properties, and osteogenic potential of DBM and cancellous bone grafts, making it a promising carrier for clinical applications in canine allograft models. When mixed with allograft cancellous bone, which has high porosity and mechanical strength, it becomes a promising material offering a more effective and reliable option for bone repair and regeneration.

Biomimetic Microstructural Materials for Intervertebral Disk Degeneration Repair

The intervertebral disks (IVD) serve as shock absorbers in the spine. As the largest avascular tissue in the human body, it has a limited capacity for regeneration. To address this issue, various innovative biomimetic materials have been explored to facilitate IVD regeneration at both microscopic and macroscopic levels. Techniques such as electrostatic spinning and fiber‐winding machines have been employed to prepare biomimetic materials. In this review, the physiological structure of the IVD is described, and advanced studies on its microstructure are summarized. The techniques used in biomimetic biomaterial development are further investigated, and biomimetic materials that facilitate IVD regeneration are systematically explored. Specifically, this article provides a detailed description and summary of the key features of biomimetic materials, including the types of loads they can withstand and their regenerative effects. Finally, a prospective outlook for the development and application of biomimetic materials in IVD regeneration is presented.

Towards Regenerative Material Design and Innovation: Overcoming Multi-Level Barriers

The ecological impacts of industrial products are often locked in at the material design stage, requiring transformative changes to practices, mindsets and systems from the beginning of the innovation journey. This paper critically explores how such transformative shifts are being shaped by the application of regenerative principles to material design and innovation practices in the realm of entrepreneurship. It is based on a qualitative interview study with 12 material innovation companies. The study aims to understand the novel innovation practices they are fostering to catalyse regenerative and/or circular approaches that can address global plastic pollution – a major contributor to global GHG emissions. The analysis identifies seven perceived innovation barriers that complicate the full adoption of regenerative principles, including advocating for new product categories, educating B2B customers about novel materials and inventing appropriate scaling approaches. Overcoming these barriers requires mindset-related and systemic transformations, linking this research to broader innovation management, sustainability transitions and regeneration debates. The article concludes by articulating key insights and managerial implications for innovation leaders who are keen to further regenerative transitions through material innovations within (and beyond) their own organisations.

The application prospects of 4D printing tissue engineering materials in oral bone regeneration

The application prospects of 4D printing tissue engineering materials in oral bone regeneration

Induced Kidney Progenitor Cells Provide a Rapid One-Pot Starting Material for Nephron Regeneration

Induced Kidney Progenitor Cells Provide a Rapid One-Pot Starting Material for Nephron Regeneration

Comprehensive characterization of natural polysaccharide-based hydrogels with gradient structure in concentration and stiffness

Gradient hydrogels are functionally graded biomaterials that over the last decades have garnered significant attention as valuable materials for tissue repair and regeneration. This study elucidates key factors crucially determining the character or pattern of a buoyancy-driven gradient in agarose hydrogels and also provides fundamental information regarding the complex interpretation of the formed gradient hydrogels obtained by the different characterization techniques, including rheology, UV-Vis spectroscopy, FCS, AFM, SEM. The employed techniques were successfully optimized to enhance the understanding of the gradient properties of these hydrogels. Demonstrated results showed that the agarose concentration gradient could be successfully controlled and tailored, which offers a valuable contribution to the design of gradient hydrogel. Moreover, a novel method for determining the average agarose concentration along the gradient axis is presented, improving the precision of gradient characterization. The integration of these approaches significantly enhances the comprehension of the internal structure and properties of gradient materials, contributing to advancements in their understanding and application.

Resistance to fracture of simulated immature teeth treated with intracanal medicaments and calcium silicate-based coronal barrier materials in endodontic regeneration

Resistance to fracture of simulated immature teeth treated with intracanal medicaments and calcium silicate-based coronal barrier materials in endodontic regeneration

Oxygen plasma-modified polycaprolactone nanofiber membrane activates the biological function in cell adhesion, proliferation, and migration through the phosphorylation of FAK and ERK1/2, enhancing bone regeneration

Bone defects present significant clinical challenges in orthopedics, orthodontics, and maxillofacial surgeries. Accelerated bone regeneration can be facilitated by incorporating mesenchymal stem cells, but limitations in cell survival and growth remain concerns for complete bone repair. Biomaterial-based membranes have been developed to form biocompatible, degradable, and mechanically stable barriers in guided bone regeneration processes. Polycaprolactone (PCL) is a biodegradable polymer widely used as a bone regenerative material because of its favorable mechanical properties. However, its inherent hydrophobicity limits cell adhesion and proliferation, which are necessary for effective bone regeneration. To address this, we fabricated cell-regulatory PCL nanofiber membranes using plasma treatment to enhance induced pluripotent stem cell-derived mesenchymal stem cells and osteoblast growth. The plasma treatment parameters (gas type, flow rate, power, and exposure time) were optimized to enhance PCL’s surface hydrophilicity and protein adsorption properties while maintaining its mechanical integrity. The optimized oxygen plasma-modified PCL membrane demonstrated notable improvements in cell viability, adhesion, and proliferation. In addition, there was improved migration, regulated by cell surface markers and signaling proteins, of the induced pluripotent stem cell-derived mesenchymal stem cells and osteoblasts. In vivo studies in a rat calvarial defect model showed that the plasma-modified PCL membrane dramatically improved new bone formation, facilitating bone regeneration. These findings highlight the potential of plasma treatment of PCL nanofibers to produce effective cell-regulatory membranes for bone defect reconstruction.

Silk-based nanocomposite hydrogel balances immune homeostasis via targeting mitochondria for diabetic wound healing

Patients with diabetes frequently experience impaired wound healing, a challenge commonly attributed to immune imbalance and oxidative stress; notably, these issues arise from mitochondrial dysfunction. In this study, we fabricate a naturally derived bioactive hydrogel by incorporating resveratrol-loaded mesoporous polydopamine nanoparticles into silk microfibers-reinforced methacrylated silk network (SS/MPDA@RES), which exhibits appropriate injectability, light-curable performance and mechanical strength. It effectively scavenges excessive ROS to protect mitochondria, restore ATP production and remodel redox homeostasis. More importantly, it promotes mitochondrial biogenesis, respiratory capacity and oxidative phosphorylation via the AMPK/SIRT1/PGC-1α signaling axis, thereby reprogramming macrophages to the anti-inflammatory phenotype. In vivo, SS/MPDA@RES hydrogel promotes wound healing in diabetic rats by modulating immunity, inhibiting early inflammation, and accelerating angiogenesis and collagen deposition. Targeting mitochondria to regulate immune and redox homeostasis provides a novel avenue for the design of future tissue regeneration materials, with SS/MPDA@RES emerging as a potential treatment strategy for diabetic wounds.

Effects of the matrix-bounded nanovesicles of high-hydrostatic pressure decellularized tissues on neural regeneration

ABSTRACT Decellularized tissues have been used as implantable materials for tissue regeneration because of their high biofunctionality. We have reported that high hydrostatic pressured (HHP) decellularized tissue developed in our laboratory exhibits good in vivo performance, but the details of the mechanism are still not known. Based on previous reports of bioactive factors called matrix bound nanovesicles (MBVs) within decellularized tissues, this study aims to investigate whether MBVs are also present in decellularized tissues prepared by HHP decellularization, which is different from the previously reported methods. In this study, we tried to extract bioactive factors from HHP decellularized brain and placenta, and evaluated their effects on nerves in vitro and in vivo, where its effects have been previously reported. The results confirmed that those factors can be extracted even if the decellularization method and tissue of origin differ, and that they have effects on a series of processes toward nerve regeneration, such as neurite outgrowth and nerve fiber repair.

Use of autologous dentin matrix in bone defects augmentation - a literature review.

A number of regenerative materials are currently used to regenerate or preserve the alveolar pro- cess. One of these is autogenous dentin matrix. With many valuable properties such as easy availability, simple preparation, low cost, low risk of disease transmission and no risk of triggering an immune response against the graft, autogenous dentin matrix appears to be a very good material of choice. The following article is intended to provide an overview of the use of autogenous dentin matrix.

Multi-crosslinked hydrogels composed of hyaluronic acid, silk fibroin and chitosan nanoparticles with capacity of bioactive molecule delivery and degradation tolerance for cartilage tissue engineering

Polymer hydrogels intended for cartilage repair applications need to be mechanically competent and degradation-endurable. Combining these essential properties jointly into the natural polymer hydrogels is an ongoing challenge. Here, a new type of multi-crosslinked composite hydrogel with enhanced mechanical and degradation-resistant properties has been developed using thiolated hyaluronic acid (THA), silk fibroin (SF), and thiolated chitosan (TCH) nanoparticles (NPs). In addition, kartogenin is loaded into TCH NPs, and meanwhile, platelet-derived growth factor-BB is incorporated into the gel matrix in combination with fucoidan for bestowing collaborative biofunctions upon the composite hydrogels. The optimally achieved THA/SF/TCH hydrogels exhibit strong, elastic, and tough characteristics and enhanced degradation tolerance. The THA/SF/TCH hydrogels also show a confirmative ability to stimulate the migration of bone marrow mesenchymal stem cells and induce their chondrogenic differentiation. These results suggest that these composite gels have promising potential as an injective material for endogenous articular cartilage repair and regeneration.

Application and progress of bionic scaffolds in nerve repair: a narrative review

Nerve injury can result in severe damage and potentially permanent disability, imposing substantial physical, psychological, and economic burdens on affected individuals and their families. Despite advances in surgical repair techniques, the functional recovery of nerves remains suboptimal. The current therapeutic approaches for nerve injury exhibit limited efficacy in restoring function, underscoring the imperative for the development of innovative treatment modalities. In recent years, bionics has emerged as a promising field in medicine, particularly in the treatment and rehabilitation of nerve injuries. We review the advances in the application of bionic technology within the realm of nerve injury treatment, encompassing bionic nerve scaffolds, nerve regeneration materials, and nerve modulation techniques. We delve into how these technologies may facilitate the repair and functional restoration of nerve tissues, as well as the challenges they encounter in clinical translation and their prospective directions for future development. Furthermore, we explore the convergence of bionic technology with existing therapeutic strategies and discuss the potential for interdisciplinary collaboration to catalyze innovation in nerve injury treatment. The integration of bionics with conventional methods may offer a synergistic approach, enhancing the efficacy of nerve repair and rehabilitation processes.

Injectable decellularized extracellular matrix hydrogel with cell-adaptable supramolecular network enhances cartilage regeneration by regulating inflammation and facilitating chondrogenesis

Osteoarthritis, characterized by progressive loss of cartilage, affects millions of people worldwide and clinically lacks effective treatments. Herein, we present an injectable, biodegradable supramolecular decellularized extracellular matrix (dECM) hydrogel, which can be injected into the joints and provide biomimetic microenvironments to drive cartilage regeneration. Benefiting from the cell-adaptable dynamic network and cartilage-specific compositions, the supramolecular dECM hydrogel not only enhances cell proliferation and migration, but also facilitates chondrogenesis. Furthermore, compared with the conventional dECM hydrogels, the supramolecular dECM hydrogel is instrumental in regulating inflammation, which consequently leads to a marked suppression of genes linked to cell death and cartilage degradation. In vivo analysis confirms that stem cells, when delivered via the supramolecular dECM hydrogel, remain viable for up to three months within the restored cartilage. The regenerated tissue exhibits hyaline-cartilage structure, good mechanical properties, and cartilage-specific extracellular matrix deposition that align closely with those of native cartilage. We envision that this supramolecular dECM hydrogel could serve as a valuable platform for cartilage regeneration and could strongly facilitate the clinical translation of dECM-based materials for tissue regeneration.

Facile engineering of interactive double network hydrogels for heart valve regeneration

Regenerative heart valve prostheses are essential for treating valvular heart disease, which requested interactive materials that can adapt to the tissue remodeling process. Such materials typically involves intricate designs with multiple active components, limiting their translational potential. This study introduces a facile method to engineer interactive materials for heart valve regeneration using 1,1’-thiocarbonyldiimidazole (TCDI) chemistry. TCDI crosslinking forms cleavable thiourea and thiocarbamate linkages which could gradually release H2S during degradation, therefore regulates the immune microenvironment and accelerates tissue remodeling. By employing this approach, a double network hydrogel was formed on decellularized heart valves (DHVs), showcasing robust anti-calcification and anti-thrombosis properties post fatigue testing. Post-implantation, the DHVs could adaptively degrade during recellularization, releasing H2S to further support tissue regeneration. Therefore, the comprehensive endothelial cell coverage and notable extracellular matrix remodeling could be clearly observed. This accessible and integrated strategy effectively overcomes various limitations of bioprosthetic valves, showing promise as an attractive approach for immune modulation of biomaterials.

Abalone shells bioenhanced carboxymethyl chitosan/collagen/PLGA bionic hybrid scaffolds achieving biomineralization and osteogenesis for bone regeneration

Inspired by the formation of natural abalone shells (AS) similar to calcium salt deposition in human orthodontics, AS is used as an emulsifier in the scaffold to solve the problem of coexistence of natural and synthetic polymers and promote new bone formation. In this study, AS-stabilized and reinforced carboxymethyl chitosan/collagen/PLGA porous bionic composite scaffolds (AS/CMCS/Col/PLGA) were fabricated through the emulsion polymerization and bionic hybrid technology. As the addition of AS increased from 0.75 to 3.0 wt%, homogeneous distribution of flower-like particles could be observed on the inner surface of the scaffold, and its mechanical properties were improved. Particularly, 3.0 wt% AS-doped scaffolds (S3 and C + S3) exhibited excellent inorganic mineral deposition and osteoblast proliferation and differentiation abilities in vitro. In a SD rat calvarial defect model, they effectively promoted new bone formation in the defect and accelerated expression of osteogenic-angiogenic related proteins (COLI, OCN, VEGF). By virtue of its combined merits including good mechanical properties, inducing mineralization crystallization and facilitating osteogenesis, the 3.0 wt% AS-doped scaffold promises to be employed as a novel bone repair material for bone tissue regeneration.

Regenerative therapies for lumbar degenerative disc diseases: a literature review.

This review aimed to summarize the recent advances and challenges in the field of regenerative therapies for lumbar disc degeneration. The current first-line treatment options for symptomatic lumbar disc degeneration cannot modify the disease process or restore the normal structure, composition, and biomechanical function of the degenerated discs. Cell-based therapies tailored to facilitate intervertebral disc (IVD) regeneration have been developed to restore the IVD extracellular matrix or mitigate inflammatory conditions. Human clinical trials on Mesenchymal Stem Cells (MSCs) have reported promising outcomes exhibited by MSCs in reducing pain and improving function. Nucleus pulposus (NP) cells possess unique regenerative capacities. Biomaterials aimed at NP replacement in IVD regeneration, comprising synthetic and biological materials, aim to restore disc height and segmental stability without compromising the annulus fibrosus. Similarly, composite IVD replacements that combine various biomaterial strategies to mimic the native disc structure, including organized annulus fibrosus and NP components, have shown promise. Furthermore, preclinical studies on regenerative medicine therapies that utilize cells, biomaterials, growth factors, platelet-rich plasma (PRP), and biological agents have demonstrated their promise in repairing degenerated lumbar discs. However, these therapies are associated with significant limitations and challenges that hinder their clinical translation. Thus, further studies must be conducted to address these challenges.

Biomimetic Scaffolds of Calcium-Based Materials for Bone Regeneration.

Calcium-based materials, such as calcium carbonate, calcium phosphate, and calcium silicate, have attracted significant attention in biomedical research, owing to their unique physicochemical properties and versatile applications. The distinctive characteristics of these materials, including their inherent biocompatibility and tunable structures, hold significant promise for applications in bone regeneration and tissue engineering. This review explores the biomedical applications of calcium-containing materials, particularly for bone regeneration. Their remarkable biocompatibility, tunable nanostructures, and multifaceted functionalities make them pivotal for advancing regenerative medicine, drug delivery system, and biomimetic scaffold applications. The evolving landscape of biomedical research continues to uncover new possibilities, positioning calcium-based materials as key contributors to the next generation of innovative biomaterial scaffolds.

Hydrogel Use in Osteonecrosis of the Femoral Head.

Osteonecrosis of the femoral head (ONFH) is a vascular disease of unknown etiology and can be categorized mainly into two types: non-traumatic and traumatic ONFH. Thus, understanding osteogenic-angiogenic coupling is of prime importance in finding a solution for the treatment of ONFH. Hydrogels are biomaterials that are similar to the extracellular matrix (ECM). As they are able to mimic real tissue, they meet one of the most important rules in tissue engineering. In ONFH studies, hydrogels have recently become popular because of their ability to retain water and their adjustable properties, injectability, and mimicry of natural ECM. Because bone regeneration and graft materials are very broad areas of research and ONFH is a complex situation including bone and vascular systems, and there is no settled treatment strategy for ONFH worldwide, in this review paper, we followed a top-down approach by reviewing (1) bone and bone grafting, (2) hydrogels, (3) vascular systems, and (4) ONFH and hydrogel use in ONFH with studies in the literature which show promising results in limited clinical studies. The aim of this review paper is to provide the reader with general information on every aspect of ONFH and to focus on the hydrogel used in ONFH.