In the United States, about 50 million individuals suffer from tinnitus (perception of sound without overt acoustic stimulation), with circa 3 million people that are disabled and require treatment. Unfortunately, current treatment options for tinnitus are often ineffective and produce inconsistent and sometimes disappointing results. New and innovative approaches for diagnosis and treatment of tinnitus are urgently needed. Here, we introduce a novel concept for tinnitus research and abatement based on the hypothesis that over-expression of genes within brain regions with hyperactive neuronal activity associated with tinnitus can be identified and targeted using multifunctional capsid-based nanoparticles. The effort proposed here leverage a multifunctional capsid-based nanoparticle platform and represents the initial step toward our long-term goal to establish a nanoparticle-based platform to localize and treat tinnitus by attenuating hyperactive neural activity. We will i) evaluate whether nanoparticles can localize to specific targets in vitro and in vivo and ii) optimize the design for ideal localization within the brain and transport across the blood-brain-barrier (BBB) with negligible side effects. Here we seek to evaluate the feasibility of using nanoparticles for in vivo use and establish a solid foundation where future work will enable more in-depth studies using animal models of tinnitus.
Specific Aim 1. To establish targeting of specific proteins within the inferior colliculus (IC) using custom-fabricated nanoparticles. Nanoparticles (NPs) will be designed to target proteins demonstrated to be differentially expressed in areas with tinnitus related hyperactivity. Adult Sprague-Dawley rats will be used to evaluate targeting specificity of the NPs. NPs decorated with antibodies that bind receptors in active neurons and loaded with fluorophore will be used for visualization during histological assessment. Two approaches to validate the specificity of NP binding are used: 1. Western blotting will be used to establish that the NPs are capable of binding the protein-of-interest isolated from the IC. This assessment will include, exposure to i) NPs modified with the specific antibody, ii) NPs without the antibody and iii) antibody alone. 2. Microscopy will be used to verify NP binding to the protein of interest in native IC cells. NPs loaded with a fluorescent tag will be localized to quantify differences in NP distribution within and across i) specific subdivisions of the IC ii) other auditory brain regions, as well as, iii) non-auditory brain region.
Specific Aim 2. To optimize dose, localization, and transport of MRI detectable custom fabricated nanoparticles across the BBB. Adult Sprague-Dawley rats will be given a systemic injection of custom- designed NPs. They will be modified with a short peptide that facilitates BBB transport (through LPR-1). At multiple time points following injection, nanoparticles with a paramagnetic core and a conjugated fluorescent tag, will be localized: 1. with T1-weighted MRI and 2. cross-validated by fluorescence-based microscopy using frozen sections.
Tinnitus is the perception of sound (ringing, buzzing, hissing, etc.) in the absence of overt acoustic stimulation. In this project we seek to develop functional nanomaterials that can be guided to specific regions within the brain associated with tinnitus, and it represent a new approach that will advance tinnitus research and treatment options. This effort will evaluate the feasibility of this new approach and will provide the groundwork for future studies that seek to deliver therapeutic compounds that will reduce and/or eliminate the symptoms of this condition.
| Apawu, Aaron K; Curley, Stephanie M; Dixon, Angela R et al. (2018) MRI compatible MS2 nanoparticles designed to cross the blood-brain-barrier: providing a path towards tinnitus treatment. Nanomedicine 14:1999-2008 |
