Application of collagen in bone regeneration

Journal of Orthopaedic Translation, Journal Year: 2025, Volume and Issue: 50, P. 129 - 143

Published: Jan. 1, 2025

At present, there is a significant population of individuals experiencing bone deficiencies caused by injuries, ailments affecting the bones, congenital abnormalities, and cancer. The management substantial defects global orthopedic challenge due to intricacies involved in promoting restoring growth fresh osseous tissue. Autografts are widely regarded as "gold standard" for repairing because their superior tissue acceptance ability control osteogenesis. However, patients undergoing autografts may encounter various challenges, including but not limited hernia, bleeding, nerve impairment, death. Therefore, researchers regenerative medicine striving find alternatives. Collagen most abundant protein human body, its triple helix structure gives it unique characteristics that contribute strength functionality tissues. commonly processed into forms such scaffolds, sponges, membranes, hydrogels, composite materials, compatibility with affinity water, minimal potential immune reactions, adaptability, transport nutrients or drugs. As an alternative material field regeneration, collagen becoming increasingly important. objective this review provide comprehensive analysis primary types sources collagen, processes synthesis degradation, well advancements made regeneration research applications. A investigation role undertaken, providing valuable points reference more profound comprehension applications field. concluding section provides overview prospective avenues research, underscoring promising future highlighting regeneration. Translational Potential Article. exploration diverse functions translational demonstrated review, these findings underscore treatment option clinical implications, thus paving way innovative efficacious therapeutic strategies domain.

Language: Английский

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Bone Regeneration: A Review of Current Treatment Strategies

Journal of Clinical Medicine, Journal Year: 2025, Volume and Issue: 14(6), P. 1838 - 1838

Published: March 8, 2025

Bone regeneration has emerged as a critical research and clinical advancement field, fueled by the growing demand for effective treatments in orthopedics oncology. Over past two decades, significant progress biomaterials surgical techniques led to development of novel solutions treating bone defects, surpassing use traditional autologous grafts. This review aims assess latest approaches regeneration, including autologous, allogenic, xenogenic grafts, naturally derived biomaterials, innovative synthetic substitutes such bioceramics, bioactive glasses, metals, polymers, composite materials, other specialized applications. A comprehensive literature search was conducted on PubMed, focusing studies published between 2019 2024, meta-analyses, reviews, systematic reviews. The evaluated range strategies, examining outcomes, materials used, techniques, effectiveness various defects. identified numerous studies, with inclusion criteria focused those exploring strategies. These provided valuable insights into biological outcomes different graft types. Results indicated that while advancements show promising potential, challenges remain optimizing therapeutic strategies across diverse patient populations settings. findings emphasize need an integrated approach combines scientific research, practice, technological innovation improve therapies. Further is required establish standardized protocols determine optimal application enhance quality care.

Language: Английский

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Recent Advancements in the Surface Modification of Additively Manufactured Metallic Bone Implants

Deleted Journal, Journal Year: 2025, Volume and Issue: unknown, P. 200195 - 200195

Published: Jan. 1, 2025

Language: Английский

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Metal‐Protein Hybrid Materials: Unlocking New Frontiers in Biomedical Applications

Advanced Healthcare Materials, Journal Year: 2025, Volume and Issue: unknown

Published: Jan. 7, 2025

Abstract Metal‐protein hybrid materials represent a novel class of functional that exhibit exceptional physicochemical properties and tunable structures, rendering them remarkable applications in diverse fields, including engineering, biocatalysis, biosensing, biomedicine. The design development multifunctional biocompatible metal‐protein have been the subject extensive research key aspiration for practical clinical settings. This review provides comprehensive analysis strategies, intrinsic properties, biomedical these materials, with specific emphasis on their potential cancer therapy, drug vaccine delivery, antibacterial treatments, tissue regeneration. Through rational design, stable can be synthesized using straightforward methods, enabling therapeutic, immunomodulatory, other desired functionalities. Finally, outlines existing limitations challenges associated evaluates translation, providing insights into implementation within applications.

Language: Английский

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Application and progress of 3D printed biomaterials in osteoporosis

Frontiers in Bioengineering and Biotechnology, Journal Year: 2025, Volume and Issue: 13

Published: Feb. 4, 2025

Osteoporosis results from a disruption in skeletal homeostasis caused by an imbalance between bone resorption and formation. Conventional treatments, such as pharmaceutical drugs hormone replacement therapy, often yield suboptimal are frequently associated with side effects. Recently, biomaterial-based approaches have gained attention promising alternatives for managing osteoporosis. This review summarizes the current advancements 3D-printed biomaterials designed osteoporosis treatment. The benefits of compared to traditional systemic drug therapies discussed. These materials can be broadly categorized based on their functionalities, including promoting osteogenesis, reducing inflammation, exhibiting antioxidant properties, inhibiting osteoclast activity. 3D printing has advantages speed, precision, personalization, etc. It is able satisfy requirements irregular geometry, differentiated composition, multilayered structure articular osteochondral scaffolds boundary layer structure. limitations existing critically analyzed future directions considered.

Language: Английский

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Implantable Zinc Ion Battery and Osteogenesis-Immunoregulation Bifunction of Its Catabolite

ACS Nano, Journal Year: 2024, Volume and Issue: 18(32), P. 21246 - 21257

Published: July 31, 2024

Biocompatible batteries can power implantable electronic devices and have broad applications in medicine. However, the controlled degradation of batteries, impact battery catabolites on surrounding tissues, wireless charging designs are often overlooked. Here, we designed an zinc ion (ZIB) using a gelatin/polycaprolactone-based composite gel electrolyte. The prepared ZIBs deliver high specific capacity 244.0 mA h g–1 (0.5C) long cycling stability 300 cycles (4C). were completely degraded within 8 weeks rats 30 days phosphate-buffered saline lipase solution, demonstrating good biocompatibility degradability. induced macrophage M2 polarization exhibited anti-inflammatory properties, with mRNA levels markers Arg-1 CD206 up-regulated 15.8-fold 13.4-fold, respectively, compared to blank control group. Meanwhile, expressions two typical osteogenic markers, osteopontin osteocalcin, by 3.6-fold 5.6-fold, that promoted differentiation bone marrow mesenchymal stem cells. Additionally, energy transmission module was 3D printing technology realize real-time ZIB rats. is promising source for medical also serves as functional material accelerate repair.

Language: Английский

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Revolutionising orthopaedic implants—a comprehensive review on metal 3D printing with materials, design strategies, manufacturing technologies, and post-process machining advancements

The International Journal of Advanced Manufacturing Technology, Journal Year: 2024, Volume and Issue: 134(3-4), P. 1043 - 1076

Published: Aug. 8, 2024

Abstract This paper conceptualises an understanding of advanced manufacturing methods to develop 3D-printed metallic orthopaedic implants, including a brief discussion on post-process machining. The significance Metallic Additive Manufacturing (MAM) and its practicality for industrial applications is discussed through juxtaposition with conventional casting machining approach. Different alloys suitable MAM techniques are thoroughly reviewed determine optimum operating conditions. Although can produce near-net shape parts, post-processing unavoidable requirement improve surface quality dimensional accuracy. A comparative study presented, highlighting the importance in terms cost savings performance. materials evaluated aiming overcome problems associated existing implants. consequence bone-implant mechanical mismatch leading stress shielding inadequate corrosion properties obstructing biodegradability explored detail. effect additive parameters mechanical, corrosion, biocompatibility analysed. Evidence MAM’s advantages over approaches, such as use functionally graded lattices patient-specific customised designs, also presented. Finally, future studies, two-way approach conceptualised material selection process control progressions implant development using MAM. Graphical

Language: Английский

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Recent development and applications of electrodeposition biocoatings on medical titanium for bone repair

Journal of Materials Chemistry B, Journal Year: 2024, Volume and Issue: 12(39), P. 9863 - 9893

Published: Jan. 1, 2024

Schematic diagram of the device, mechanism and biomedical application electrodeposition for preparation bioactive coatings on surface titanium implants bone repair.

Language: Английский

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NIR-driven GOx-like nanozyme-modified injectable thermoresponsive hydrogel for antibacterial therapy and bone regeneration in periodontitis

Chemical Engineering Journal, Journal Year: 2025, Volume and Issue: unknown, P. 160108 - 160108

Published: Feb. 1, 2025

Language: Английский

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Probiotics and nanoparticle-mediated nutrient delivery in the management of transfusion-supported diseases

Frontiers in Cellular and Infection Microbiology, Journal Year: 2025, Volume and Issue: 15

Published: April 11, 2025

Bone marrow is vital for hematopoiesis, producing blood cells essential oxygen transport, immune defense, and clotting. However, disorders like leukemia, lymphoma, aplastic anemia, myelodysplastic syndromes can severely disrupt its function, leading to life-threatening complications. Traditional treatments, including chemotherapy stem cell transplants, have significantly improved patient outcomes but are often associated with severe side effects limitations, necessitating the exploration of safer, more targeted therapeutic strategies. Nanotechnology has emerged as a promising approach addressing these challenges, particularly in delivery nutraceuticals—bioactive compounds derived from food sources potential benefits. Despite their promise, nutraceuticals face clinical limitations due poor bioavailability, instability, inefficient target sites. Nanoparticles offer viable solution by enhancing stability, absorption, transport bone while minimizing systemic effects. This study explores range disorders, conventional treatment modalities, nanoparticles enhance nutraceutical-based therapies. By improving efficacy, could revolutionize disease management, providing patients effective less invasive options. These advancements represent significant step toward safer efficient approaches, ultimately prognosis overall health.

Language: Английский

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