سازوکارها و کاربردهای امیدوارکنندهی هیدروژلهای الهامگرفته از صدف
محورهای موضوعی : پليمرها درسامانه های اپتیکی و الکترونیکی، لیزری و انعطاف پذیراکبر میرزایی 1 , شهرزاد جوانشیر 2 , غزاله میرزایی 3
1 - دانشكده شيمي
2 - ندارد
3 - ندارد
کلید واژه: هیدروژل, دوپامین, الکترونیک انعطاف پذیر, شیمی الهام گرفته از صدف, کاتکول,
چکیده مقاله :
شیمی الهامگرفته از صدف، بهدلیل عملکردهای منحصربهفرد، بهعنوان ابزاری قدرتمند برای طراحی منطقی و سنتز هیدروژل های جدید ظاهر شده است. هیدروژلها شبکههای پلیمری سهبعدی متقاطع با محتوای آب زیاد هستند و بهدلیل شباهت های مکانیکی و شیمیایی با بافت های زیستی و همچنین وجود خواص مکانیکی، الکتریکی، در زمینههای متنوعی از مهندسی پزشکی ،رباتیک نرم، الکترونیک نرم و علوم محیطی کاربرد دارند. باوجود پیشرفت گسترده، هیدروژل های معمولی هنوز با مشکلات زیادی مانند نداشتن راهبردهای کلی برای برنامهریزی خواص شیمیایی/فیزیکی و دشواری در برآوردن برخی الزامات کاربردی خاص، به ویژه در محیط کاری متنوع و پیچیده، محدود هستند. بنابراین اصلاح و ساخت هیدروژل های جدید متناسب با هدف های مختلف می تواند مفید باشد که در این میان شیمی الهامگرفته از صدف مانند استفاده از دوپامین می تواند خواص منحصربهفردی به ژل ها ببخشد و کاربرد آنها را در زمینههای متعددی از جمله مهندسی زیستپزشکی، الکترونیک نرم، محرکها و حسگرهای پوشیدنی گسترده تر کند. هدف ما در این مقاله مروری بررسی هیدروژل های ساختهشده به کمک ترکیبات صدف و بررسی خواص آن ها است.
mussel-inspired chemistry has become a powerful tool for the rational design and synthesis of hydrogels with modified properties and applications due to their unique functionalities. Hydrogels are cross-linked three-dimensional polymer networks with high water content and flexible structure, and due to their mechanical and chemical similarities with biological tissues, as well as the existence of mechanical and electrical properties, they are used in various fields of medical engineering, soft robotics, Electronics and environmental science have many applications. Despite the extensive progress in this field, conventional hydrogels still face many problems, such as the lack of general strategies to program the chemical/physical properties and the difficulty in meeting some specific application requirements, especially in the diverse and complex working environment that limit their application. severely restricts. Therefore, the modification of hydrogels according to different purposes can lead to their more and better use in various industries. Adhesive hydrogels are gaining interest for biomedical applications due to their high adhesion, tunable structure, high water content, and biocompatibility. Meanwhile, the modification of normal hydrogels with the help of oyster-inspired chemistry, such as the use of dopamine and tannic acid, can give unique properties to the gels and their application in many fields, including biomedical engineering, electronics, stimuli and sensors. Wider wearable. Our aim in this review article is to investigate the hydrogel made with the help of mussel-inspired compounds.
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