Nelson Christopher E, Gupta Mukesh Kumar, Adolph Elizabeth J, Guelcher Scott A, Duvall Craig L
Department of Biomedical Engineering, Vanderbilt University , Nashville, Tennessee.
Department of Chemical and Biomolecular Engineering, Vanderbilt University , Nashville, Tennessee.
Adv Wound Care (New Rochelle). 2013 Apr;2(3):93-99. doi: 10.1089/wound.2011.0327.
Aberrant overexpression of proinflammatory molecules is believed to be a key mediator in the formation of chronic skin wounds, and the inhibition of these signals may be an effective therapeutic strategy to promote healing. Small interfering RNA (siRNA) can provide gene-specific silencing and may present a safe and effective route for knockdown of inflammatory or other target proteins in chronic skin wounds.
siRNA suffers from delivery barriers such as susceptibility to degradation, membrane impermeability, and transient activity. Therefore, a delivery strategy that stabilizes siRNA, provides intracellular (cytoplasmic) delivery, and produces temporally sustained activity is needed. The novel approach described combines pH-responsive, siRNA-loaded nanoparticles into a biodegradable polyurethane (PUR) scaffold and presents a promising platform for effective, local silencing of deleterious genes in nonhealing skin wounds.
The siRNA delivery barriers have been overcome using a nanoparticulate carrier that protects siRNA and responds to pH gradients in the endo-lysosomal pathway to mediate cytosolic delivery. Nanoparticle incorporation into a biodegradable PUR scaffold provides a means for controlling the delivery kinetics of siRNA-loaded carriers. Furthermore, the PUR is injectable, making it feasible for clinical use, and provides a porous tissue template for cell in-growth during tissue regeneration and remodeling. This local siRNA delivery platform can be tuned to optimize release kinetics for specific pathologies.
siRNA may provide a new class of biologic drugs that will outperform growth factor approaches, which have shown only moderate clinical success. The new platform presented here may provide clinicians with an improved option for wound care.
促炎分子的异常过表达被认为是慢性皮肤伤口形成的关键介质,抑制这些信号可能是促进愈合的有效治疗策略。小干扰RNA(siRNA)可实现基因特异性沉默,可能为慢性皮肤伤口中炎症或其他靶蛋白的敲低提供一种安全有效的途径。
siRNA存在递送障碍,如易降解、膜不透性和瞬时活性。因此,需要一种能稳定siRNA、实现细胞内(细胞质)递送并产生持续时间活性的递送策略。所描述的新方法将pH响应性、负载siRNA的纳米颗粒与可生物降解的聚氨酯(PUR)支架相结合,为非愈合性皮肤伤口中有害基因的有效局部沉默提供了一个有前景的平台。
使用纳米颗粒载体克服了siRNA递送障碍,该载体可保护siRNA并对内溶酶体途径中的pH梯度作出响应以介导细胞质递送。将纳米颗粒掺入可生物降解的PUR支架中为控制负载siRNA载体的递送动力学提供了一种方法。此外,PUR可注射,使其临床应用可行,并为组织再生和重塑过程中的细胞向内生长提供了多孔组织模板。这种局部siRNA递送平台可进行调整以优化针对特定病理情况的释放动力学。
siRNA可能提供一类新的生物药物,其性能将优于生长因子方法,而生长因子方法仅取得了中等程度的临床成功。这里介绍的新平台可能为临床医生提供更好的伤口护理选择。