Although nanoparticles have been found to be effective in delivery to more traditional vascularized organs and tissues, there are different challenges for nanoparticle transport in tissues that lack a vascular system to assist in penetration into the tissue. Here we propose a systematic approach to the design of nanomaterials systems that are capable of deep penetration and delivery of agents into avascular tissues. The proposed work will focus on establishing sets of materials design concepts to enhance transport into and through these tissues based on size, charge density and presentation, targeting and dynamic materials chemistries. In the Aim 1, we will develop two promising families of multivalent drug nanocarriers with modular design, each presenting unique advantages for tissue penetration. The transport of these nanocarriers will then be examined as a function of size and charge using ex vivo tissue models to rapidly screen libraries of nanocarriers and identify optimal size/charge characteristics for tissues of interest. We will examine transport in three unique avascular tissue types: cartilage, meniscus and cornea to understand similarities or differences in design requirements and optimal transport characteristics for a range of avascular tissue types. Further translation of this Aim is anticipated to provide fundamental knowledge regarding how to address other similar barrier tissues in the context of drug delivery. Treatment of cartilage to address conditions such as osteoarthritis presents a particularly important medical challenge, and is the disease focus for the later Aims of these studies; however, successful demonstration of this system in the first Aim will be applicable to other tissues and conditions, including delivery to the cornea and joint meniscus. To enable a more tissue-responsive delivery approach, both pH responsive and enzyme degradable linkers will be examined in Aim 2 for the conjugation of therapeutics, with the focus on conjugation of IGF-1, a growth factor that can facilitate cartilage regeneration in early stage osteoarthritis. Optimized versions of the nanocarriers will be studied in an established in vivo using an early surgical trauma rat model to evaluate the efficacy of IGF-1 treatments with the nondegradable, hydrolytic, and protease-activated degradable linkers and determine in vivo real-time pharmacokinetics versus free IGF-1. Cartilage treatment studies will be carried out in this model for IGF-1 delivery. Finally, an additional aspect of this study will be the design of nanoconjugates that release drug selectively to regions of tissue matched to the different nanocarrier transport properties determined in earlier Aims, including degree of penetration and residence time within the tissue. Combination treatments for small molecule drugs including dexamethasone and TLR4 inhibitors will be conjugated to carriers optimal for each drug, in combination with the top IGF-1 formulation. We will evaluate the therapeutic effects of the combinations in a cytokine-challenged ex vivo cartilage tissue model by measuring inflammatory markers, matrix deposition and maintenance, and kinetics of cartilage repair. 1

Public Health Relevance

Multivalent Nano-conjugates for Targeted Penetration of and Delivery to Dense Extracellular Matrices For tissues such as cartilage, cornea, meniscus and tendon, that do not have blood vessels to help drug molecules get deep into the tissue for effective treatment, it can be challenging to deliver biologic drugs and other important drugs due to a dense and strongly charged tissue matrix that is difficult to penetrate. In the proposed work, very highly controlled nanoparticles of unusually small size and controlled charge are designed to penetrate into these tissues and deliver drugs in a manner that is responsive to the condition of the tissue. The nanoparticles will first be tested on several different tissue types, and then biologic drugs and combinations with anti-inflammatory drugs that can aid in regeneration of cartilage will be conjugated to the particles for delivery to cartilage to treat and aid in repair of early stage osteoarthritis in a highly controlled and effective manner.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB026344-02
Application #
9783820
Study Section
Biomaterials and Biointerfaces Study Section (BMBI)
Program Officer
Russell, Luisa Marie
Project Start
2018-09-15
Project End
2022-05-31
Budget Start
2019-06-01
Budget End
2020-05-31
Support Year
2
Fiscal Year
2019
Total Cost
Indirect Cost
Name
Massachusetts Institute of Technology
Department
Engineering (All Types)
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
001425594
City
Cambridge
State
MA
Country
United States
Zip Code
02142