Advances in Nanomedicine for Precision Insulin Delivery

Pharmaceuticals Pub Date : 2024-07-15 DOI:10.3390/ph17070945
A. Caturano, Roberto Nilo, Davide Nilo, Vincenzo Russo, Erica Santonastaso, R. Galiero, L. Rinaldi, Marcellino Monda, C. Sardu, Raffaele Marfella, F. C. Sasso
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Abstract

Diabetes mellitus, which comprises a group of metabolic disorders affecting carbohydrate metabolism, is characterized by improper glucose utilization and excessive production, leading to hyperglycemia. The global prevalence of diabetes is rising, with projections indicating it will affect 783.2 million people by 2045. Insulin treatment is crucial, especially for type 1 diabetes, due to the lack of β-cell function. Intensive insulin therapy, involving multiple daily injections or continuous subcutaneous insulin infusion, has proven effective in reducing microvascular complications but poses a higher risk of severe hypoglycemia. Recent advancements in insulin formulations and delivery methods, such as ultra-rapid-acting analogs and inhaled insulin, offer potential benefits in terms of reducing hypoglycemia and improving glycemic control. However, the traditional subcutaneous injection method has drawbacks, including patient compliance issues and associated complications. Nanomedicine presents innovative solutions to these challenges, offering promising avenues for overcoming current drug limitations, enhancing cellular uptake, and improving pharmacokinetics and pharmacodynamics. Various nanocarriers, including liposomes, chitosan, and PLGA, provide protection against enzymatic degradation, improving drug stability and controlled release. These nanocarriers offer unique advantages, ranging from enhanced bioavailability and sustained release to specific targeting capabilities. While oral insulin delivery is being explored for better patient adherence and cost-effectiveness, other nanomedicine-based methods also show promise in improving delivery efficiency and patient outcomes. Safety concerns, including potential toxicity and immunogenicity issues, must be addressed, with the FDA providing guidance for the safe development of nanotechnology-based products. Future directions in nanomedicine will focus on creating next-generation nanocarriers with precise targeting, real-time monitoring, and stimuli-responsive features to optimize diabetes treatment outcomes and patient safety. This review delves into the current state of nanomedicine for insulin delivery, examining various types of nanocarriers and their mechanisms of action, and discussing the challenges and future directions in developing safe and effective nanomedicine-based therapies for diabetes management.
纳米医学在胰岛素精准给药方面的进展
糖尿病是一组影响碳水化合物代谢的代谢紊乱疾病,其特点是葡萄糖利用不当和产生过多,从而导致高血糖。全球糖尿病发病率正在上升,预计到 2045 年将有 7.832 亿人患糖尿病。胰岛素治疗至关重要,尤其是对于缺乏β细胞功能的1型糖尿病患者。事实证明,每天多次注射或持续皮下注射胰岛素的强化胰岛素疗法可有效减少微血管并发症,但会带来较高的严重低血糖风险。胰岛素制剂和给药方法的最新进展,如超速作用类似物和吸入胰岛素,在减少低血糖和改善血糖控制方面提供了潜在的益处。然而,传统的皮下注射方法存在缺点,包括患者的依从性问题和相关并发症。纳米医学为应对这些挑战提供了创新的解决方案,为克服当前药物的局限性、提高细胞吸收率以及改善药代动力学和药效学提供了前景广阔的途径。包括脂质体、壳聚糖和聚乳酸(PLGA)在内的各种纳米载体可防止酶降解,提高药物的稳定性和控释性。这些纳米载体具有独特的优势,从提高生物利用度、持续释放到特定靶向能力,不一而足。目前正在探索口服胰岛素给药,以提高患者依从性和成本效益,其他基于纳米药物的方法也有望提高给药效率和患者疗效。必须解决安全问题,包括潜在的毒性和免疫原性问题,美国食品和药物管理局将为纳米技术产品的安全开发提供指导。纳米医学的未来发展方向将集中在创造具有精确靶向、实时监控和刺激响应功能的下一代纳米载体,以优化糖尿病治疗效果和患者安全。本综述深入探讨了用于胰岛素给药的纳米医学的现状,研究了各种类型的纳米载体及其作用机制,并讨论了开发安全有效的基于纳米医学的糖尿病治疗方法所面临的挑战和未来发展方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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