Spatiotemporally Programmed Release of Aptamer Tethered Dual Angiogenic Growth Factors

Deepti Rana, Jeroen Rouwkema
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Abstract

In tissue extracellular matrix (ECM), multiple growth factors (GFs) are sequestered through affinity interactions and released as needed by proteases, establishing spatial morphogen gradients in a time-controlled manner to guide cell behavior. Inspired by these ECM characteristics, we developed an intelligent biomaterial platform that spatially controls the combined bioavailability of multiple angiogenic GFs, specifically vascular endothelial growth factor (VEGF) and platelet-derived growth factor (PDGF-BB). Utilizing aptamer affinity interactions and complementary sequences within a GelMA matrix, our platform achieves on-demand, triggered release of individual GFs which can be programmed in temporally-controlled, repeatable cycles. The platform features stable incorporation of dual aptamers specific for both GFs, functional aptamer-CS molecular recognition in a 3D microenvironment with long-term stability of at least 15 days at physiological temperature, and spatially localized sequestration of individual GFs. Additionally, the system allows differential amounts of GFs to be released from the same hydrogels at different time-points, mimicking dynamic GF presentation in a 3D matrix similar to the native ECM. This flexible control over individual GF release kinetics opens new possibilities for dynamic GF presentation, with adjustable release profiles to meet the spatiotemporal needs of growing engineered tissue.
时空程序化释放系链双血管生成生长因子
在组织细胞外基质(ECM)中,多种生长因子(GFs)通过亲和性相互作用被封存,并在蛋白酶的作用下按需释放,从而以时间可控的方式建立空间形态发生梯度,引导细胞行为。受这些 ECM 特性的启发,我们开发了一种智能生物材料平台,它能在空间上控制多种血管生成 GFs(特别是血管内皮生长因子(VEGF)和血小板衍生生长因子(PDGF-BB))的综合生物利用率。我们的平台利用 GelMA 基质中的适配体亲和力相互作用和互补序列,实现了按需触发释放单个 GFs,并可按时间控制的可重复周期进行编程。该平台的特点包括:稳定地加入两种 GF 的特异性双适配体、在三维微环境中实现功能性适配体-CS 分子识别(在生理温度下至少可保持 15 天的长期稳定性)以及对单个 GF 进行空间定位封存。此外,该系统还能在不同时间点从同一水凝胶中释放不同数量的 GF,模拟 GF 在类似于原生 ECM 的三维基质中的动态呈现。这种对单个 GF 释放动力学的灵活控制为动态 GF 呈现开辟了新的可能性,可调节的释放曲线可满足生长中的工程组织的时空需求。
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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