1.Anti-tumor effect of metal ion-mediated natural small molecules carrier-free hydrogel combined with CDT/PDT.
Wen-Min PI ; Gen LI ; Xin-Ru TAN ; Zhi-Xia WANG ; Xiao-Yu LIN ; Hai-Ling QIU ; Fu-Hao CHU ; Bo WANG ; Peng-Long WANG
China Journal of Chinese Materia Medica 2025;50(7):1770-1780
Metal ion-promoted chemodynamic therapy(CDT) combined with photodynamic therapy(PDT) offers broad application prospects for enhancing anti-tumor effects. In this study, glycyrrhizic acid(GA), copper ions(Cu~(2+)), and norcantharidin(NCTD) were co-assembled to successfully prepare a natural small-molecule, carrier-free hydrogel(NCTD Gel) with excellent material properties. Under 808 nm laser irradiation, NCTD Gel responded to the tumor microenvironment(TME) and acted as an efficient Fenton reagent and photosensitizer, catalyzing the conversion of endogenous hydrogen peroxide(H_2O_2) within the tumor into oxygen(O_2), and hydroxyl radicals(·OH, type Ⅰ reactive oxygen species) and singlet oxygen(~1O_2, type Ⅱ reactive oxygen species), while depleting glutathione(GSH) to stabilize reactive oxygen species and alleviate tumor hypoxia. In vitro and in vivo experiments demonstrated that NCTD Gel exhibited significant CDT/PDT synergistic therapeutic effects. Further safety evaluation and metabolic testing confirmed its good biocompatibility and safety. This novel hydrogel is not only simple to prepare, safe, and cost-effective but also holds great potential for clinical transformation, providing insights and references for the research and development of metal ion-mediated hydrogel-based anti-tumor therapies.
Hydrogels/chemistry*
;
Animals
;
Photochemotherapy
;
Humans
;
Mice
;
Antineoplastic Agents/administration & dosage*
;
Photosensitizing Agents/chemistry*
;
Neoplasms/metabolism*
;
Female
;
Copper/chemistry*
;
Reactive Oxygen Species/metabolism*
;
Tumor Microenvironment/drug effects*
;
Cell Line, Tumor
;
Male
2.Research progress of bioactive scaffolds in repair and regeneration of osteoporotic bone defects.
Yuangang WU ; Kaibo SUN ; Yi ZENG ; Bin SHEN
Chinese Journal of Reparative and Reconstructive Surgery 2025;39(1):100-105
OBJECTIVE:
To summarize the research progress of bioactive scaffolds in the repair and regeneration of osteoporotic bone defects.
METHODS:
Recent literature on bioactive scaffolds for the repair of osteoporotic bone defects was reviewed to summarize various types of bioactive scaffolds and their associated repair methods.
RESULTS:
The application of bioactive scaffolds provides a new idea for the repair and regeneration of osteoporotic bone defects. For example, calcium phosphate ceramics scaffolds, hydrogel scaffolds, three-dimensional (3D)-printed biological scaffolds, metal scaffolds, as well as polymer material scaffolds and bone organoids, have all demonstrated good bone repair-promoting effects. However, in the pathological bone microenvironment of osteoporosis, the function of single-material scaffolds to promote bone regeneration is insufficient. Therefore, the design of bioactive scaffolds must consider multiple factors, including material biocompatibility, mechanical properties, bioactivity, bone conductivity, and osteogenic induction. Furthermore, physical and chemical surface modifications, along with advanced biotechnological approaches, can help to improve the osteogenic microenvironment and promote the differentiation of bone cells.
CONCLUSION
With advancements in technology, the synergistic application of 3D bioprinting, bone organoids technologies, and advanced biotechnologies holds promise for providing more efficient bioactive scaffolds for the repair and regeneration of osteoporotic bone defects.
Humans
;
Tissue Scaffolds/chemistry*
;
Bone Regeneration
;
Osteoporosis/therapy*
;
Tissue Engineering/methods*
;
Biocompatible Materials/chemistry*
;
Printing, Three-Dimensional
;
Calcium Phosphates/chemistry*
;
Osteogenesis
;
Ceramics
;
Cell Differentiation
;
Hydrogels
;
Bioprinting
;
Bone and Bones
3.Application and progress of intelligent responsive hydrogels in articular cartilage injury repair.
Qingyu XU ; Baojian ZHANG ; Hongri LI ; Chengri LIU ; Shuhao BI ; Zhixiang YANG ; Yanqun LIU
Chinese Journal of Reparative and Reconstructive Surgery 2025;39(2):250-256
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*
4.Research progress of hydrogel-based growth factors for treatment of intervertebral disc degeneration.
Chinese Journal of Reparative and Reconstructive Surgery 2025;39(11):1491-1497
OBJECTIVE:
To summarize recent research progress in hydrogel-based growth factors for treatment of intervertebral disc degeneration (IDD).
METHODS:
The relevant literature on hydrogel-based growth factors for IDD treatment at home and abroad was extensively reviewed, and their advantages and therapeutic effects in repairing IDD were analyzed and summarized.
RESULTS:
Hydrogels exhibit high hydration, biocompatibility, and biodegradability, enabling targeted delivery and sustained release of growth factors such as growth differentiation factors and transforming growth factors. This facilitates enhanced efficacy in promoting cell proliferation, extracellular matrix synthesis, and reducing inflammatory responses. Consequently, hydrogels demonstrate broad application prospects in the repair of IDD.
CONCLUSION
Research on hydrogel-based growth factors for treating IDD demonstrates advantages such as avoiding disc damage caused by repeated injections and controlling growth factor release concentrations. However, drawbacks include the limited variety of loaded growth factors and the need to verify the long-term stability and biocompatibility of hydrogels. Therefore, further research is required on aspects such as the types of loaded growth factors and the long-term stability and biocompatibility of hydrogels to establish an experimental foundation for their clinical application.
Intervertebral Disc Degeneration/therapy*
;
Hydrogels/chemistry*
;
Humans
;
Intercellular Signaling Peptides and Proteins/administration & dosage*
;
Biocompatible Materials/chemistry*
;
Animals
;
Tissue Engineering/methods*
;
Cell Proliferation/drug effects*
;
Drug Delivery Systems
5.Application and advances of exosome-hydrogel system in wound healing.
Chinese Journal of Reparative and Reconstructive Surgery 2025;39(12):1615-1622
OBJECTIVE:
To review the recent advances in the application of exosome-hydrogel system for wound healing.
METHODS:
A wide range of recent domestic and international studies were reviewed to systematically outline the roles and mechanisms of exosomes, hydrogels, and their composite system in promoting wound repair.
RESULTS:
Wound healing is a complex and finely regulated process. Traditional therapies lack targeted regulation of key mechanisms such as inflammation control, angiogenesis, collagen remodeling, and re-epithelialization. The exosome-hydrogel system enhances wound repair through targeted modulation of these mechanisms and provides effective protection against bacterial infection, hypoxia, excessive oxidative stress, and hyperglycemic microenvironments.
CONCLUSION
The exosome-hydrogel system represents an emerging approach for chronic wound repair and skin regeneration, potentially overcoming the inherent limitations of traditional therapies. Nevertheless, the lack of standardized preparation methods and dosing protocols calls for further optimization.
Wound Healing
;
Humans
;
Hydrogels
;
Exosomes
;
Skin/injuries*
;
Animals
;
Re-Epithelialization
6.Current Research Status of Biomedical Hydrogel and Challenges and Opportunities in Clinical Translation.
Huan LIAN ; Li LIU ; Linnan KE
Chinese Journal of Medical Instrumentation 2025;49(5):520-526
As representatives of the third generation of biomedical materials, hydrogels exhibit revolutionary potential in tissue engineering, precision drug delivery, and smart medical devices due to their ability to construct bionic microenvironments. However, the clinical translation of hydrogels is still limited by multidimensional challenges, including biocompatibility, scalable production, and regulatory complexity. This paper systematically reviews the design innovations, functionalization strategies, and translational bottlenecks of hydrogel materials, integrates the latest technological trends, such as 4D printing and AI-driven design, and proposes a collaborative optimization pathway encompassing materials, technology, clinical applications, and policy. By introducing local Chinese innovation cases and monitoring scientific advancements, this study offers solutions that possess both academic significance and practical guidance for the clinical translation of hydrogels.
Hydrogels
;
Tissue Engineering
;
Translational Research, Biomedical
;
Biocompatible Materials
;
Humans
;
Drug Delivery Systems
7.Chitosan hydrogel loaded with human umbilical cord mesenchymal stem cell-derived exosomes promotes healing of chronic diabetic wounds in rats.
Xiaohui QIU ; Meng WANG ; Jiangjie TANG ; Jianda ZHOU ; Chen JIN
Journal of Southern Medical University 2025;45(10):2082-2091
OBJECTIVES:
To investigate the mechanism by which chitosan (CS) hydrogel loaded with human umbilical cord mesenchymal stem cell (HUVECs)-derived exosomes (hUCMSC-exos) (Exos@CS-Gel) improves diabetic wound healing.
METHODS:
hUCMSC-exos were extracted and Exos@CS-Gel was prepared. The effect of Exos@CS-Gel on proliferation and migration of HUVECs were evaluated using scratch wound assay and CCK-8 assay. Diabetic rat models with full-thickness skin wounds established by streptozotocin induction were randomized divided into 4 groups for treatment with Exos@CS-Gel (100 µg hUCMSC-exos dissolved in 100 µL 24% CS hydrogel), hUCMSC-exos (100 µg hUCMSC-exos dissolved in 100 µL PBS), CS hydrogel (100 µL 24% CS hydrogel), or PBS (control group). Wound healing and the therapeutic mechanisms were assessed using immunohistochemistry, HE staining, immunofluorescence, and qRT-PCR.
RESULTS:
In cultured HUVECs, Exos@CS-Gel treatment significantly promoted cell proliferation and migration. In the rat models of chronic diabetic wounds, the wound healing rate in Exos@CS-Gel group reached 92.7% on day 14, significantly higher than those in hUCMSC-exos group (9.12%), CS hydrogel group (16.28%), and control group (25.98%). Microvessel density and the expression levels of vascular endothelial growth factor and transforming growth factor β-1 were significantly increased in the Exos@CS-Gel group.
CONCLUSIONS
Exos@CS-Gel promotes survival capacity of hUCMSC-exos in vitro and accelerates diabetic wound healing in rats by promoting angiogenesis and cell proliferation.
Animals
;
Wound Healing
;
Humans
;
Chitosan
;
Exosomes
;
Mesenchymal Stem Cells/cytology*
;
Diabetes Mellitus, Experimental
;
Rats
;
Umbilical Cord/cytology*
;
Hydrogels
;
Human Umbilical Vein Endothelial Cells
;
Cell Proliferation
;
Rats, Sprague-Dawley
;
Male
8.Adhesive and injectable hydrogel microspheres for NRF2-mediated periodontal bone regeneration.
Yu WANG ; Shanshan JIN ; Yaru GUO ; Yilong LU ; Xuliang DENG
International Journal of Oral Science 2025;17(1):7-7
Regenerating periodontal bone defect surrounding periodontal tissue is crucial for orthodontic or dental implant treatment. The declined osteogenic ability of periodontal ligament stem cells (PDLSCs) induced by inflammation stimulus contributes to reduced capacity to regenerate periodontal bone, which brings about a huge challenge for treating periodontitis. Here, inspired by the adhesive property of mussels, we have created adhesive and mineralized hydrogel microspheres loaded with traditional compound cordycepin (MMS-CY). MMS-CY could adhere to the surface of alveolar bone, then promote the migration capacity of PDLSCs and thus recruit them to inflammatory periodontal tissues. Furthermore, MMS-CY rescued the impaired osteogenesis and ligament-forming capacity of PDLSCs, which were suppressed by the inflammation stimulus. Moreover, MMS-CY also displayed the excellent inhibitory effect on the osteoclastic activity. Mechanistically, MMS-CY inhibited the premature senescence induced by the inflammation stimulus through the nuclear factor erythroid 2-related factor (NRF2) pathway and reducing the DNA injury. Utilizing in vivo rat periodontitis model, MMS-CY was demonstrated to enhance the periodontal bone regeneration by improving osteogenesis and inhibiting the osteoclastic activity. Altogether, our study indicated that the multi-pronged approach is promising to promote the periodontal bone regeneration in periodontitis condition by reducing the inflammation-induced stem cell senescence and maintaining bone homeostasis.
Animals
;
Bone Regeneration/drug effects*
;
Rats
;
Periodontal Ligament/cytology*
;
Microspheres
;
NF-E2-Related Factor 2
;
Hydrogels
;
Periodontitis/therapy*
;
Osteogenesis/drug effects*
;
Disease Models, Animal
;
Stem Cells
;
Male
;
Rats, Sprague-Dawley
;
Humans
9.Expansion of functional human salivary acinar cell spheroids with reversible thermo-ionically crosslinked 3D hydrogels.
Jose G MUNGUIA-LOPEZ ; Sangeeth PILLAI ; Yuli ZHANG ; Amatzia GANTZ ; Dimitria B CAMASAO ; Showan N NAZHAT ; Joseph M KINSELLA ; Simon D TRAN
International Journal of Oral Science 2025;17(1):39-39
Xerostomia (dry mouth) is frequently experienced by patients treated with radiotherapy for head and neck cancers or with Sjögren's syndrome, with no permanent cure existing for this debilitating condition. To this end, in vitro platforms are needed to test therapies directed at salivary (fluid-secreting) cells. However, since these are highly differentiated secretory cells, the maintenance of their differentiated state while expanding in numbers is challenging. In this study, the efficiency of three reversible thermo-ionically crosslinked gels: (1) alginate-gelatin (AG), (2) collagen-containing AG (AGC), and (3) hyaluronic acid-containing AG (AGHA), to recapitulate a native-like environment for human salivary gland (SG) cell expansion and 3D spheroid formation was compared. Although all gels were of mechanical properties comparable to human SG tissue (~11 kPa) and promoted the formation of 3D spheroids, AGHA gels produced larger (>100 cells/spheroid), viable (>93%), proliferative, and well-organized 3D SG spheroids while spatially and temporally maintaining the high expression of key SG proteins (aquaporin-5, NKCC1, ZO-1, α-amylase) for 14 days in culture. Moreover, the spheroids responded to agonist-induced stimulation by increasing α-amylase secretory granules. Here, we propose alternative low-cost, reproducible, and reversible AG-based 3D hydrogels that allow the facile and rapid retrieval of intact, highly viable 3D-SG spheroids.
Humans
;
Hydrogels/chemistry*
;
Acinar Cells/cytology*
;
Spheroids, Cellular/cytology*
;
Salivary Glands/cytology*
;
Gelatin/chemistry*
;
Collagen/chemistry*
;
Alginates/chemistry*
;
Cell Culture Techniques/methods*
;
Hyaluronic Acid/chemistry*
;
Cell Proliferation
;
Cell Survival
;
Cells, Cultured
10.An injectable bioceramics-containing composite hydrogel promoting innervation for pulp-dentin complex repair.
Xingyu TAO ; Hongjian ZHANG ; Peng MEI ; Jinzhou HUANG ; Bing FANG ; Zhiguang HUAN ; Chengtie WU
International Journal of Oral Science 2025;17(1):66-66
Dental pulp-dentin complex defects remain a major unresolved problem in oral medicines. Clinical therapeutic methods including root canal therapy and vital pulp therapy are both considered as conservative strategies, which are incapable of repairing the pulp-dentin complex defects. Although biomaterial-based strategies show remarkable progress in antibacterial, anti-inflammatory, and pulp regeneration, the important modulatory effects of nerves within pulp cavity have been greatly overlooked, making it challenging to achieve functional pulp-dentin complex regeneration. In this study, we propose an injectable bioceramics-containing composite hydrogel in combination of Li-Ca-Si (LCS) bioceramics and gelatin methacrylate matrix with photo-crosslinking properties. Due to the sustained release of bioactive Li, Ca and Si ions from LCS, the composite hydrogels possess multiple functions of promoting the neurogenic differentiation of Schwann cells, odontogenic differentiation of dental pulp stem cells, and neurogenesis-odontogenesis couples in vitro. In addition, the in vivo results showed that LCS-containing composite hydrogel can significantly promote the pulp-dentin complex repair. More importantly, LCS bioceramics-containing composite hydrogel can induce the growth of nerve fibers, leading to the re-innervation of pulp tissues. Taken together, the study suggests that LCS bioceramics can induce the innervation of pulp-dentin complex repair, offering a referable strategy of designing multifunctional filling materials for functional periodontal tissue regeneration.
Dental Pulp/drug effects*
;
Hydrogels/pharmacology*
;
Animals
;
Ceramics/pharmacology*
;
Dentin/drug effects*
;
Biocompatible Materials/pharmacology*
;
Rats
;
Gelatin
;
Regeneration/drug effects*
;
Cell Differentiation/drug effects*
;
Injections
;
Humans
;
Odontogenesis/drug effects*

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