The objective of this proposed study is to synthesize and validate multifunctional 3T (targeting, tracking, and treating) nanocells for repair of blood vessels damaged by acute renal ischemic- reperfusion injury. For this study, nanocells are defined as nano-sized drug-encapsulating polymersomes, structurally similar to biological cells. Clinical studies suggest that certain antibodies and cytokines that bind to endothelial cells can be used as drugs that induce vascular normalization and ultimately improve treatments of various acute, chronic and malignant diseases. It has been often proposed that such vascular normalization therapies can be significantly improved by combining these drugs with carriers capable of targeting and tracking to the target blood vessels. However, the development of such multifunctional drug carriers has been plagued by difficulties in independently controlling targeting, tracking and treatment functions. We hypothesize that the 3T function of nanocells can be independently tuned by (1) integrating into the nanocell via self- assembly process, a targeting module, a poly (glycerol) substituted with varying numbers of alkyl chains and leaky endothelium-targeting oligopeptides, and (2) further incorporating into the nanocell via in situ encapsulation, surface-engineered super paramagnetic iron oxide nanoparticles that enable tracking of the nanocell via magnetic resonance imaging (MRI). The resulting 3T nanocells will allow us to significantly improve the vascular normalization while monitoring 3T nanocells'therapeutic activity using MRI. We will accomplish our goals, first, by modifying and validating the nanocells with targeting modules via self-assembly [Aim 1];second, by encapsulating iron oxide nanoparticles in the nanocell created in the Aim 1 study and validating its tracking function [Aim 2];and finally incorporating drugs that normalize leaky blood vessels, specifically Angiopoietin 1, in the nanocells created in the Aim 2 study and evaluating its function to treat porcine renal arteries damaged by acute ischemia-reperfusion injury [Aim 3]. In this study, polymersomes of alkyl-substituted poly (2-hydroxy ethyl aspartamide) (PEHA) filled with biodegradable poly (ethylene glycol) nanogels will be used as nanocells. This proposed study will be implemented through an extensive interdisciplinary collaboration between a biomaterials group [Kong, University of Illinois (UI)];organic and polymer synthesis group [Zimmerman, UI];and bioimaging and vascular medicine group [Misra, Mayo Clinic]. The results of this proposed study are expected to significantly impact research in bioengineering and clinical strategies in medicine, because it will not only create an innovative strategy for assembling multifunctional drug carriers, but also validate its functionality to improve vascular normalization.

Public Health Relevance

The successful completion of this proposed study will create an innovative strategy for assembling a multifunctional drug carrier, 3T nanocell, which allows independent tuning of targeting, tracking and treating functions. Ultimately, this study will create a novel drug delivery system which will significantly improve the therapeutic efficacy of drugs that induce vascular normalization. Overall, this study will greatly contribute to improving peoples'quality of life who is suffering from a wide array of acute, chronic and malignant diseases related to leaky blood vessels.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
1R01HL109192-01
Application #
8161467
Study Section
Nanotechnology Study Section (NANO)
Program Officer
Danthi, Narasimhan
Project Start
2011-08-01
Project End
2016-04-30
Budget Start
2011-08-01
Budget End
2012-04-30
Support Year
1
Fiscal Year
2011
Total Cost
$401,828
Indirect Cost
Name
University of Illinois Urbana-Champaign
Department
Engineering (All Types)
Type
Schools of Arts and Sciences
DUNS #
041544081
City
Champaign
State
IL
Country
United States
Zip Code
61820
Seo, Yongbeom; Leong, Jiayu; Park, Jun Dong et al. (2018) Diatom Microbubbler for Active Biofilm Removal in Confined Spaces. ACS Appl Mater Interfaces 10:35685-35692
Leong, Jiayu; Seo, Yongbeom; Chu, Sang-Hyon et al. (2018) Pore Diameter of Mesoporous Silica Modulates Oxidation of H2O2-Sensing Chromophore in a Porous Matrix. Langmuir 34:11242-11252
Seo, Yongbeom; Leong, Jiayu; Teo, Jye Yng et al. (2017) Active Antioxidizing Particles for On-Demand Pressure-Driven Molecular Release. ACS Appl Mater Interfaces 9:35642-35650
Raman, Ritu; Grant, Lauren; Seo, Yongbeom et al. (2017) Damage, Healing, and Remodeling in Optogenetic Skeletal Muscle Bioactuators. Adv Healthc Mater 6:
Clay, Nicholas E; Whittenberg, Joseph J; Leong, Jiayu et al. (2017) Chemical and mechanical modulation of polymeric micelle assembly. Nanoscale 9:5194-5204
Liang, Youyun; Clay, Nicholas Edwin; Sullivan, Kathryn M et al. (2017) Enzyme-Induced Matrix Softening Regulates Hepatocarcinoma Cancer Cell Phenotypes. Macromol Biosci 17:
Lee, Min Kyung; Park, Jooyeon; Wang, Xuefeng et al. (2016) Rupture force of cell adhesion ligand tethers modulates biological activities of a cell-laden hydrogel. Chem Commun (Camb) 52:4757-60
Schmidt, John; Lee, Min Kyung; Ko, Eunkyung et al. (2016) Alginate Sulfates Mitigate Binding Kinetics of Proangiogenic Growth Factors with Receptors toward Revascularization. Mol Pharm 13:2148-54
Smith, Cartney E; Ernenwein, Dawn; Shkumatov, Artem et al. (2015) Hydrophilic packaging of iron oxide nanoclusters for highly sensitive imaging. Biomaterials 69:184-90
Chen, Jinrong; Clay, Nicholas; Kong, Hyunjoon (2015) Non-Spherical Particles for Targeted Drug Delivery. Chem Eng Sci 125:20-24

Showing the most recent 10 out of 29 publications