Vanderbilt Clinical Trials

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Detailed Description

Lymphedema is a chronic, debilitating disease caused by lymphatic flow obstruction. Breast cancer-related lymphedema (BCRL) secondary to mastectomy and/or radiation therapy is a growing health concern, with a reported incidence as high as 94% in breast cancer survivors. Behavioral adjustments and aggressive therapeutic management can reduce long-term impairment and optimize quality of life. However, there is currently no standard clinical procedure for identifying patients at greatest BCRL risk and fundamental gaps exist in even our basic knowledge of how the lymphatic system responds to node dissection and subsequent therapy. Specialized imaging methods have demonstrated that reduced lymphatic flow velocity and lymphatic contractility impairment may signify greater BCRL risk, however these approaches frequently require radioactive tracers or exogenous contrast agents which alter the physiological environment and are primarily available only in specialized centers. As such, these methods are simply impractical for routine BCRL monitoring in humans or for reporting clinical trial endpoints. Recent work has demonstrated that spin labeling, a popular and noninvasive MRI method for measuring perfusion, can be adapted to measure lymphatic fluid flow to axillary lymph nodes. Furthermore chemical exchange saturation transfer (CEST) MRI, a popular method for measuring protein content and pH changes in brain, breast, and liver, can be translated to the lymphatic system to assess sensitive changes in interstitial protein accumulation, a hallmark of lymphedema progression. Recent work has provided motivation for these techniques by demonstrating, using commercially available equipment, that consistent changes in lymphatic properties are detectable in vivo under (i) conditions of cuff-induced lymph flow manipulation, and (ii) in affected vs. unaffected arms of BCRL patients. Here, these methods will be implemented in sequence with standard clinical and MRI measures of lymph structure to expand our understanding of lymph physiology in different stages of BCRL and in response to therapy. Hypothesis (1). Axillary lymph nodes and vessels, velocity of lymphatic fluid, and interstitial protein accumulation can be visualized in a reproducible manner using noninvasive MRI approaches that are frequently used to measure analogous metrics in brain, breast, and liver. Aim (1). Turbo-spin-echo, spin labeling, and CEST MRI will be applied to assess lymph collector volume, lymphatic flow velocity, and interstitial protein accumulation, respectively, together for the first time in healthy female volunteers. Intraclass and Spearman's rank correlation coefficients will be calculated to understand the reproducibility and age-dependence of these parameters in uncompromised lymphatic systems. Hypothesis (2). (2a) The MRI protocol applied in Aim (1) can be used to detect (i) increases in interstitial protein accumulation and (ii) reductions in lymphatic velocity in patients with mild and moderate BCRL, and (2b) these functional metrics will be more variable than limb volume measurements in patients in early BCRL disease stages and following common manual lymphatic drainage (MLD) therapy, thereby demonstrating the utility of these imaging biomarkers for identifying lymphatic dysfunction and monitoring therapy response. Aim (2). The Aim (1) protocol will be applied to patients in preclinical (Stage 0), mild (Stage I), and moderate (Stage II) BCRL together with volumetric limb measurements before and after MLD therapy. A Wilcoxon rank-sum test will be used to assess differences in parameters between patient volunteers in different BCRL stages as well as pre- and post-MLD therapy. These data will provide an exemplar for how the novel, internal imaging measurements of lymphatic function vary with disease severity and therapy administration. Hypothesis (3). In preclinical BCRL patients (Stage 0), reduced lymphatic velocity and increased interstitial protein accumulation correlates with elevated two-year BCRL progression risk. Aim (3). Stage 0 BCRL patients will undergo an identical MRI protocol as outlined in Aim (1) and follow-up disability metrics will be recorded up to two years post-therapy. A multi-parametric analysis will be used to test correlations between the hypothesized imaging biomarkers and BCRL progression, thereby demonstrating to what extent acute MRI may be used to stratify risk in patients at high risk for BCRL. This work will for the first time translate a noninvasive, multi-modal MRI protocol, which has demonstrated clinical potential in brain, liver, and breast applications, to the human lymphatic system to better characterize lymphatic dysfunction, therapy response, and BCRL risk in the growing breast cancer survivor population.