OBJECTIVE: To review clinical application and research progress of different types of intelligent responsive hydrogels in repairing articular cartilage injury. METHODS: The animal experiments and clinical studies of different types of intelligent responsive hydrogels for repairing articular cartilage injury were summarized by reviewing relevant literature at home and abroad. RESULTS: The intrinsic regenerative capacity of articular cartilage following injury is limited. Intelligent responsive hydrogels, including those that are temperature-sensitive, light-sensitive, enzyme-responsive, pH-sensitive, and other stimuli-responsive hydrogels, can undergo phase transitions in response to specific stimuli, thereby achieving optimal functionality. These hydrogels can fill the injured cartilage area, promote the proliferation and differentiation of chondrocytes, and expedite the repair of the damaged site. With advancements in cartilage tissue engineering materials research, intelligent responsive hydrogels offer a novel approach and promising potential for the treatment of cartilage injuries. CONCLUSION Intelligent responsive hydrogel is a kind of flexible, controllable, efficient, and stable polymer, which has similar structure and functional properties to articular cartilage, and has become one of the important biomaterials for cartilage repair. However, there is still a lack of unified treatment standards and simple and efficient preparation technology.
Hydrogels/therapeutic use* ; Cartilage, Articular/injuries* ; Tissue Engineering/methods* ; Humans ; Animals ; Chondrocytes/cytology* ; Biocompatible Materials/chemistry* ; Tissue Scaffolds/chemistry*

With the rapid development of implant dentistry, increasing attention has been paid to the long-term stability and aesthetic outcomes of dental implants, among which sufficient volume and quality of soft and hard tissues are considered crucial contributing factors for successful treatment outcomes. Among the various available tissue regeneration strategies, plasmatrix, an autologous biomaterial derived from the patient ' s own peripheral blood, has demonstrated unique and significant clinical value in the regeneration and augmentation of both soft and hard tissues associated with dental implant therapy in recent years. This notable potential is primarily attributed to its rich content of multiple growth factors, viable cells, and a supportive fibrin scaffold, along with its excellent biocompatibility, tunable biodegradation profile, and a relatively simple and rapid preparation process that does not require complex laboratory equipment. As a result, its clinical applications have been continuously expanding across a wide range of indications. Based on a comprehensive review of the existing literature and current research evidence, this article provides an in-depth summary of the advancements in both basic science and clinical applications of plasmatrix in the context of implant dentistry. Particular attention is given to its classification from a materials science perspective, underlying molecular mechanisms, biological effects in promoting tissue regeneration, and its implementation under different clinical scenarios. Furthermore, the article discusses unresolved technical challenges and existing controversies, and outlines potential future directions for research and technological innovation, aiming to provide robust evidence-based guidance for clinical practice as well as a theoretical and methodological reference for future scientific investigations.
Humans ; Biocompatible Materials/therapeutic use* ; Dental Implants ; Tissue Scaffolds ; Fibrin/therapeutic use* ; Tissue Engineering/methods* ; Dental Implantation/methods* ; Dental Implantation, Endosseous/methods*

Collagen membrane has attracted much attention from researchers due to its excellent properties such as wide source, degradable absorption, and low immunogenicity. However, they are limited by poor mechanical stability and rapid degradation. To enhance their physicochemical properties and biological functions, researchers have developed various strategies, including cross-linking, incorporation of growth factors or drugs, combination with other biomaterials, optimization of composition and structure, and substitution with marine-derived collagen. These advances aim to expand the clinical applications of collagen membranes in oral medicine. With the urgent demand for high-performance biomaterials in oral medicine, summarizing recent progress on collagen membranes provides valuable insights into their mechanisms, clinical efficacy, and limitations, offering reference for optimized design and broader clinical use. Furthermore, further trends may include integrating advanced manufacturing technologies to develop personalized collagen membranes, which could significantly improve therapeutic outcomes in oral diseases.
Collagen/therapeutic use* ; Humans ; Biocompatible Materials/chemistry* ; Membranes, Artificial ; Oral Medicine/methods* ; Tissue Engineering/methods*

OBJECTIVE: To review the research progress of natural biomaterial polyhydroxyalkanoate (PHA) in orthopedics. METHODS: The literature concerning PHA devices for bone defects, bone repair, and bone neoplasms, respectively, in recent years was extensively consulted. The three aspects of the advantages of PHA in bone repair, the preparation of PHA medical devices for bone repair and their application in orthopedics were discussed. RESULTS: Due to excellent biodegradability, biocompatibility, and potential osteoinduction, PHA is a kind of good bone repair material. In addition to the traditional PHA medical implants, the use of electrostatic spinning and three-dimensional printing can be designed to various functional PHA medical devices, in order to meet the orthopedic clinical demands, including the bone regeneration, minimally invasive bone tissue repair by injection, antibacterial bone repair, auxiliary establishment of three-dimensional bone tumor model, directed osteogenic differentiation of stem cells, etc. CONCLUSION At present, PHA is a hotspot of biomaterials for translational medicine in orthopedics. Although they have not completely applied in the clinic, the advantages of repair in bone defects have been gradually reflected in tissue engineering, showing an application prospect in orthopedics.
Orthopedics ; Osteogenesis ; Arthrodesis ; Anti-Bacterial Agents ; Biocompatible Materials ; Polyhydroxyalkanoates/therapeutic use*

Silk fibroin, a natural fibrin, is a suitable matrix biomaterial for wound repair due to its unique properties such as good biocompatibility, tunable biodegradation and mechanical properties, low host inflammatory response, low cost, ease of fabrication, etc. Silk fibroin can be used alone or in combination with other materials to construct various dressings including scaffolds, hydrogels, films, smart mats, and microneedles, which can meet the needs of different wound repair and regulate the wound repair process. Thus, the application research of silk fibroin in skin tissue engineering has increased dramatically. Compared with other natural materials, silk fibroin promotes tissue regeneration and wound repair by improving cell proliferation, migration, and differentiation behavior at different stages, showing unique advantages in different dimensions. Based on the development of silk fibroin wound repair materials in the recent years, this review focuses on the mechanism and application prospect of silk fibroin and its composite materials in wound repair.
Fibroins/metabolism* ; Biocompatible Materials/therapeutic use* ; Tissue Engineering ; Hydrogels ; Fibrin ; Tissue Scaffolds

Wound repair is a highly coordinated and mutually regulated complex process involving various kinds of cells, extracellular matrices and cytokines. A variety of growth factors play an important regulatory role in wound healing, and it is critical to achieve effective delivery and sustained function of growth factors. In recent years, the application of biomaterials in tissue engineering has shown great potential, and the effective delivery of growth factors by biomaterials has attracted increasing attention. Based on this, this paper introduces the mechanism of related growth factors in the process of wound healing, focusing on the recent progress of biomaterial delivery of growth factors to accelerate wound healing, in order to provide new enlightenment for clinical wound treatment.
Biocompatible Materials/metabolism* ; Extracellular Matrix/metabolism* ; Intercellular Signaling Peptides and Proteins/therapeutic use* ; Tissue Engineering ; Wound Healing

Inflatable penile prostheses are an important tool in the treatment of medically refractory erectile dysfunction. One of the major complications associated with these prostheses is infections, which ultimately require device explanation and placement of a new device. Over the past several decades, significant work has been done to reduce infection rates and optimize treatment strategies to reduce patient morbidity. This article reviews the current state of knowledge surrounding penile prosthesis infections, with attention to the evidence for methods to prevent infection and best practices for device reimplantation.
Anti-Bacterial Agents/therapeutic use* ; Anti-Infective Agents, Local/therapeutic use* ; Antibiotic Prophylaxis/methods* ; Bandages ; Carrier State/drug therapy* ; Chlorhexidine/therapeutic use* ; Coated Materials, Biocompatible ; Device Removal ; Diabetes Mellitus/epidemiology* ; Erectile Dysfunction/surgery* ; Gram-Negative Bacterial Infections/therapy* ; Hair Removal/methods* ; Humans ; Immunocompromised Host/immunology* ; Male ; Penile Implantation/methods* ; Penile Prosthesis ; Preoperative Care/methods* ; Prosthesis-Related Infections/therapy* ; Reoperation ; Risk Factors ; Spinal Cord Injuries/epidemiology* ; Staphylococcal Infections/therapy* ; Staphylococcus aureus ; Staphylococcus epidermidis ; Surgical Drapes ; Surgical Instruments ; Surgical Wound Infection/therapy*

BACKGROUNDRegenerative techniques help promote the formation of new attachment and bone filling in periodontal defects. However, the dimensions of intraosseous defects are a key determinant of periodontal regeneration outcomes. In this study, we evaluated the efficacy of use of anorganic bovine bone (ABB) graft in combination with collagen membrane (CM), to facilitate healing of noncontained (1-wall) and contained (3-wall) critical size periodontal defects.

METHODSThe study began on March 2013, and was completed on May 2014. One-wall (7 mm × 4 mm) and 3-wall (5 mm × 4 mm) intrabony periodontal defects were surgically created bilaterally in the mandibular third premolars and first molars in eight beagles. The defects were treated with ABB in combination with CM (ABB + CM group) or open flap debridement (OFD group). The animals were euthanized at 8-week postsurgery for histological analysis. Two independent Student's t-tests (1-wall [ABB + CM] vs. 1-wall [OFD] and 3-wall [ABB + CM] vs. 3-wall [OFD]) were used to assess between-group differences.

RESULTSThe mean new bone height in both 1- and 3-wall intrabony defects in the ABB + CM group was significantly greater than that in the OFD group (1-wall: 4.99 ± 0.70 mm vs. 3.01 ± 0.37 mm, P < 0.05; 3-wall: 3.11 ± 0.59 mm vs. 2.08 ± 0.24 mm, P < 0.05). The mean new cementum in 1-wall intrabony defects in the ABB + CM group was significantly greater than that in their counterparts in the OFD group (5.08 ± 0.68 mm vs. 1.16 ± 0.38 mm; P < 0.05). Likewise, only the 1-wall intrabony defect model showed a significant difference with respect to junctional epithelium between ABB + CM and OFD groups (0.67 ± 0.23 mm vs. 1.12 ± 0.28 mm, P < 0.05).

CONCLUSIONSOne-wall intrabony defects treated with ABB and CM did not show less periodontal regeneration than that in 3-wall intrabony defect. The noncontained 1-wall intrabony defect might be a more discriminative defect model for further research into periodontal regeneration.

Alveolar Bone Loss ; surgery ; Animals ; Biocompatible Materials ; therapeutic use ; Bone Regeneration ; physiology ; Bone Substitutes ; therapeutic use ; Cattle ; Dogs ; Guided Tissue Regeneration, Periodontal ; methods ; Male ; Wound Healing ; physiology

Soft tissue filler injection has been a very common procedure worldwide since filler injection was first introduced for soft tissue augmentation. Currently, filler is used in various medical fields with satisfactory results, but the number of complications is increasing due to the increased use of filler. The complications after filler injection can occur at any time after the procedure, early and delayed, and they range from minor to severe. In this review, based on our experience and previously published other articles, we suggest a treatment algorithm to help wound healing and tissue regeneration and generate good aesthetic results with early treatment in response to the side effects of filler. Familiarity with the treatment of these rare complications is essential for achieving the best possible outcome.
Algorithms ; Biocompatible Materials/*therapeutic use ; Connective Tissue/*surgery ; Face/surgery ; Guided Tissue Regeneration/*methods ; Humans ; Hyaluronic Acid/administration & dosage ; Injections ; Skin Aging ; Surgery, Plastic/*methods ; Tissue Engineering/*methods ; Wound Healing

Soft tissue augmentation is a process of implanting tissues or materials to treat wrinkles or soft tissue defects in the body. Over the years, various materials have evolved to correct soft tissue defects, including a number of tissues and polymers. Autogenous dermis, autogenous fat, autogenous dermis-fat, allogenic dermis, synthetic implants, and fillers have been widely accepted for soft tissue augmentations. Tissue engineering technology has also been introduced and opened a new venue of opportunities in this field. In particular, a long-lasting filler consisting of hyaluronic acid filler and living human mesenchymal cells called "injectable tissue-engineered soft tissue" has been created and applied clinically, as this strategy has many advantages over conventional methods. Fibroblasts and adipose-derived stromal vascular fraction cells can be clinically used as injectable tissue-engineered soft tissue at present. In this review, information on the soft tissue augmentation method using the injectable tissue-engineered soft tissue is provided.
Adipocytes/transplantation ; Adipose Tissue/cytology ; Biocompatible Materials ; Connective Tissue/*surgery ; Dermatologic Surgical Procedures/*methods ; Face ; Fibroblasts/transplantation ; Humans ; Hyaluronic Acid/therapeutic use ; Injections, Intradermal ; Mesenchymal Stem Cell Transplantation/*methods ; Mesenchymal Stromal Cells ; Skin ; Skin Aging ; Tissue Engineering/*methods