Fan Wei, Zhang Wenting, Jia Yinnong, Brusnahan Susan K, Garrison Jered C
Department of Pharmaceutical Sciences, College of Pharmacy, ‡Center for Drug Delivery and Nanomedicine, ∥Department of Biochemistry and Molecular Biology, College of Medicine, and ⊥Eppley Cancer Center, University of Nebraska Medical Center , Omaha, Nebraska 985830, United States.
Mol Pharm. 2017 May 1;14(5):1405-1417. doi: 10.1021/acs.molpharmaceut.6b01038. Epub 2017 Mar 21.
N-(2-Hydroxypropyl)methacrylamide (HPMA) copolymers have been studied as an efficient carrier for drug delivery and tumor imaging. However, as with many macromolecular platforms, the substantial accumulation of HPMA copolymer by the mononuclear phagocyte system (MPS)-associated tissues, such as the blood, liver, and spleen, has inhibited its clinical translation. Our laboratory is pursuing approaches to improve the diagnostic and radiotherapeutic effectiveness of HPMA copolymers by reducing the nontarget accumulation. Specifically, we have been investigating the use of a cathepsin S (Cat S)-cleavable peptidic linkers to degrade multiblock HPMA copolymers to increase MPS-associated tissue clearance. In this study, we further our investigation into this area by exploring the impact of copolymer block size on the biological performance of Cat S-degradable HPMA copolymers. Using a variety of in vitro and in vivo techniques, including dual labeling of the copolymer and peptide components, we investigated the constructs using HPAC pancreatic ductal adenocarcinoma models. The smaller copolymer block size (S-CMP) demonstrated significantly faster Cat S cleavage kinetics relative to the larger system (L-CMP). Confocal microscopy demonstrated that both constructs could be much more efficiently internalized by human monocyte-differentiated macrophage (hMDM) compared to HPAC cells. In the biodistribution studies, the multiblock copolymers with a smaller block size exhibited faster clearance and lower nontarget retention while still achieving good tumor targeting and retention. Based on the radioisotopic ratios, fragmentation and clearance of the copolymer constructs were higher in the liver compared to the spleen and tumor. Overall, these results indicate that block size plays an important role in the biological performance of Cat S-degradable polymeric constructs.
N-(2-羟丙基)甲基丙烯酰胺(HPMA)共聚物已被研究作为一种有效的药物递送和肿瘤成像载体。然而,与许多大分子平台一样,HPMA共聚物在单核吞噬细胞系统(MPS)相关组织(如血液、肝脏和脾脏)中的大量积累阻碍了其临床应用。我们实验室正在寻求通过减少非靶向积累来提高HPMA共聚物的诊断和放射治疗效果的方法。具体来说,我们一直在研究使用组织蛋白酶S (Cat S)可裂解的肽接头来降解多嵌段HPMA共聚物,以增加MPS相关组织的清除率。在本研究中,我们通过探索共聚物嵌段大小对Cat S可降解HPMA共聚物生物学性能的影响,进一步深入研究了这一领域。我们使用多种体外和体内技术,包括对共聚物和肽成分进行双重标记,利用HPAC胰腺导管腺癌模型研究了这些构建体。与较大的系统(L-CMP)相比,较小的共聚物嵌段大小(S-CMP)显示出明显更快的Cat S裂解动力学。共聚焦显微镜显示,与HPAC细胞相比,两种构建体都能更有效地被人单核细胞分化的巨噬细胞(hMDM)内化。在生物分布研究中,嵌段尺寸较小的多嵌段共聚物表现出更快的清除率和更低的非靶向滞留率,同时仍能实现良好的肿瘤靶向性和滞留率。基于放射性同位素比率,共聚物构建体在肝脏中的碎片化和清除率高于脾脏和肿瘤。总体而言,这些结果表明嵌段大小在Cat S可降解聚合物构建体的生物学性能中起着重要作用。