Treating Primary Aldosteronism-induced Hypertension via Microwave Ablation

Lead Research Organisation: University of Ulster

Abstract

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Technical Summary

In this tripartite US-Ireland R&D partnership program R01 research plan, we propose the development, optimization, and evaluation of a minimally-invasive microwave thermal therapy (MWT) system for definitive treatment of primary aldosteronism. Primary aldosteronism (PA) accounts for 5 - 12% of all hypertension and confers a higher risk for cardiovascular and cerebrovascular complications compared to age and blood pressure (BP) matched essential hypertension. Yet PA remains under-diagnosed and under-treated, largely due to the lack of definitive management options for the majority of affected individuals. The current definitive approach to unilateral PA is surgical adrenalectomy, while bilateral disease is managed medically; medical therapy is often poorly tolerated due to off target anti-androgen effects. Only ~30% of all individuals diagnosed with PA undergo surgery, and collateral resection of normal cortex limits the option of surgery to unilateral disease, given the inevitable risk for adrenocortical insufficiency with bilateral adrenalectomy. Therefore, the overall objective of this proposal is the development, optimization, and experimental evaluation of an image-guided approach for sub-ablative MWT of APAs, and for post-treatment assessment of adrenal function. First, we will employ a series of in vitro studies to determine the optimal range of thermal doses for rendering hyperfunctioning adrenal cells defunct, at sub-ablative thermal doses. We will then verify the ability to disrupt adrenal cell function at these thermal doses in an in vivo mouse tumor model, with thermal dose tracked via MRI temperature imaging. Next, we will develop a system employing microwave applicators with precise spatio-temporal control of microwave radiation to deliver MWT to hyperfunctioning adrenal cells. We will develop real-time techniques for identifying the targeted tissue from real-time imaging, informed by pre-procedural PET/CT imaging localizing the hyperfunctioning adrenal cells, in order to guide applicator placement and energy delivery. Finally, we will develop a non-iodinated contrast agent suitable for verifying adrenal cell function, immediately post MWT, thereby providing a means for assessing treatment outcome. The overall system will be evaluated in a large animal model. If successful, and translated to humans in future studies, this approach will, for the first time, extend definitive management of PA to individuals with unilateral and bilateral APAs. !

Publications

10 25 50