Alexis Gaudin, Solène Tessier, Léna Guyon, Ove A Peters
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Optimizing delivery of specialized pro-resolving mediators for oral inflammation via smart hydrogels and biomaterials.
Chronic oral inflammatory diseases such as pulpitis, periodontitis, and peri-implantitis pose significant clinical challenges, often resulting in irreversible tissue loss despite the application of current therapies. Specialized pro-resolving mediators (SPMs) offer a novel therapeutic paradigm by actively promoting the resolution of inflammation and tissue regeneration without compromising host defense. However, the clinical translation of SPMs is hindered by their rapid degradation, low bioavailability, and poor localization to inflamed tissues. Smart biomaterial-based delivery systems, particularly stimuli-responsive hydrogels, have emerged as promising platforms to overcome these barriers. These systems enable controlled, localized, and environment-triggered release of SPMs, enhancing their stability and therapeutic efficacy. Preclinical studies in models of oral inflammation demonstrate that hydrogel-mediated SPM delivery not only resolves inflammation but also preserves tissue structure and promotes regeneration. Future strategies will focus on optimizing dosing protocols, ensuring long-term bioactivity, and addressing regulatory and manufacturing challenges to enable clinical adoption. By enhancing the delivery and sustained bioactivity of SPMs, biomaterial-based strategies have the potential to fundamentally transform the management of oral inflammatory diseases and advance regenerative dental therapies.
期刊介绍:
Delivering therapeutics in a way that is right for the patient - safe, painless, reliable, targeted, efficient and cost effective - is the fundamental aim of scientists working in this area. Correspondingly, this evolving field has already yielded a diversity of delivery methods, including injectors, controlled release formulations, drug eluting implants and transdermal patches. Rapid technological advances and the desire to improve the efficacy and safety profile of existing medications by specific targeting to the site of action, combined with the drive to improve patient compliance, continue to fuel rapid research progress. Furthermore, the emergence of cell-based therapeutics and biopharmaceuticals such as proteins, peptides and nucleotides presents scientists with new and exciting challenges for the application of therapeutic delivery science and technology. Successful delivery strategies increasingly rely upon collaboration across a diversity of fields, including biology, chemistry, pharmacology, nanotechnology, physiology, materials science and engineering. Therapeutic Delivery recognizes the importance of this diverse research platform and encourages the publication of articles that reflect the highly interdisciplinary nature of the field. In a highly competitive industry, Therapeutic Delivery provides the busy researcher with a forum for the rapid publication of original research and critical reviews of all the latest relevant and significant developments, and focuses on how the technological, pharmacological, clinical and physiological aspects come together to successfully deliver modern therapeutics to patients. The journal delivers this essential information in concise, at-a-glance article formats that are readily accessible to the full spectrum of therapeutic delivery researchers.
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