Design of gelatin cryogel scaffolds with the ability to release simvastatin for potential bone tissue engineering applications.

Suzan Melis Yaman, Didem Demir, Nimet Bölgen
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Abstract

Tissue engineering aims to improve or restore damaged tissues by using scaffolds, cells and bioactive agents. In tissue engineering, one of the most important concepts is the scaffold because it has a key role in keeping up and promoting the growth of the cells. It is also desirable to be able to load these scaffolds with drugs that induce tissue regeneration/formation. Based on this, in our study, gelatin cryogel scaffolds were developed for potential bone tissue engineering applications and simvastatin loading and release studies were performed. Simvastatin is lipoliphic in nature and this form is called inactive simvastatin (SV). It is modified to be in hydrophilic form and converted to the active form (SVA). For our study's drug loading and release process, simvastatin was used in both inactive and active forms. The blank cryogels and drug-loaded cryogels were prepared at different glutaraldehyde concentrations (1, 2, and 3%). The effect of the crosslinking agent and the amount of drug loaded were discussed with morphological and physicochemical analysis. As the glutaraldehyde concentration increased gradually, the pores size of the cryogels decreased and the swelling ratio decreased. For the release profile of simvastatin in both forms, we can say that it depended on the form (lipophilic and hydrophilic) of the loaded simvastatin.

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设计具有释放辛伐他汀能力的明胶低温凝胶支架,用于潜在的骨组织工程应用。
组织工程旨在利用支架、细胞和生物活性剂改善或恢复受损组织。在组织工程中,最重要的概念之一是支架,因为它在维持和促进细胞生长方面起着关键作用。此外,最好还能在这些支架上添加能诱导组织再生/形成的药物。基于此,我们在研究中开发了明胶低温凝胶支架,用于潜在的骨组织工程应用,并进行了辛伐他汀的负载和释放研究。辛伐他汀本质上是脂联素,这种形式被称为非活性辛伐他汀(SV)。辛伐他汀经改性后呈亲水性,并转化为活性形式(SVA)。在我们研究的药物负载和释放过程中,辛伐他汀以非活性和活性两种形式被使用。在不同戊二醛浓度(1%、2% 和 3%)下制备了空白低温凝胶和药物负载低温凝胶。通过形态和理化分析讨论了交联剂和载药量的影响。随着戊二醛浓度的逐渐增加,低温凝胶的孔径减小,膨胀率降低。对于两种形式的辛伐他汀的释放曲线,我们可以说它取决于负载辛伐他汀的形式(亲脂性和亲水性)。
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