This pilot study is to determine the safety and efficacy of oral sirolimus (blood trough level 6-10ng/ml) in patients with HHT that are experiencing moderate or severe epistaxis. The effect of oral sirolimus on epistaxis will be compared to baseline using the Patient-Reported Outcome of cumulative weekly nose Bleeding Duration (PRO-CB). The PRO-CB association with biomarker variability over the duration of the study will be investigated. In the pilot study subjects will be treated with 2mg of sirolimus once daily to obtain a trough level of 6-10ng/ml for 3 months.
The most common symptom of the hereditary hemorrhagic telangiectasia (HHT) disease is epistaxis. HHT is characterized by vascular (blood vessel) malformations, of the skin and mucus membranes of the nose (telangiectasia), gastrointestinal track, brain, lung and liver. HHT is an autosomal dominant disease which is found in approximately 1 in 5000 individuals. Epistaxis affects 90% of adults with HHT, negatively affects quality of life and often causes anemia. Recent topical therapeutics trials have been negative and surgical therapies are invasive and offer only temporary benefit at best. Currently there are no highly-effective or approved systemic therapies for HHT-related epistaxis, but this is an area of active research and development. There is considerable in developing and identifying therapies that target the abnormal biology ad mechanisms in HHT, including antiangiogenic therapies, such as bevacizumab. Bevacizumab, however, is associated with significant toxicity, costly and administered intravenously. Over the past few years, there has been considerable new evidence of the pathways involved in HHT disease and related potential therapeutic targets, including the mTOR pathway. Evidence suggests that HHT pathogenesis strongly relies on overactivated PI3K-Akt-mTOR and VEGFR2 pathways in endothelial cells. It was recently reported that the mTOR inhibitor, sirolimus, and the receptor tyrosine-kinase inhibitor, nintedanib, synergistically fully blocked, and also reversed, retinal AVMs, in the BMP9/10- immunoblocked neonatal mouse model of HHT. Subsequent unpublished preliminary data demonstrated that sirolimus was more effective than nintedanib at blocking anemia and bleeding in inducible ALK1 knockout HHT mice, and similarly effective to combined sirolimus-nintedanib. As such, sirolimus may provide therapeutic benefit for HHT patients. Human studies have shown "low-dose" sirolimus to be low risk and effective as a treatment for other vascular anomalies. There is an urgent need for effective therapies for HHT and the chronic bleeding associated with the disease. Preliminary cellular and animal model data have identified sirolimus as a potential new pathway-based therapy in HHT. In addition, sirolimus is an interesting agent, as it is given orally and is available for repurposing. Data from other vascular malformations syndromes suggest that it can be effective in a "low-dose" range, reducing risk of toxicity, but there is only one published case report of sirolimus use in an HHT patient. This phase II pilot study will provide safety data as the primary outcome, and secondarily, efficacy data, outcome measure data and biological exploratory data, to support the planning of a future randomized and placebo -controlled clinical trial of sirolimus for epistaxis in HHT patients. Sirolimus has been identified as a potential pathway-based therapy for HHT. Pre-clinical research has suggested that the pathogenesis of HHT is as a result of overactive mTOR and VEGFR2 pathway. Sirolimus has been found to work as an mTOR inhibitor to prevent the effects of overactive mTOR that results in arteriovenous malformations in a HHT. One clinical trial that used sirolimus to treat vascular anomalies, found that sirolimus was well tolerated and acted as an effective and safe treatment for most study participants. Considerable experience using sirolimus in post-transplant patients and growing experience using sirolimus in patients with vascular anomalies exist. This pilot study will assess the safety and effectiveness of repurpose oral sirolimus, for epistaxis in patients with HHT. It is hypothesized that oral sirolimus (blood trough level 6-10ng/ml) will be a safe and effective therapy for epistaxis in HHT patients.
Oral sirolimus provided with starting dose of 2mg once daily, adjusted to maintain drug blood levels of 6-10 ng/ml (3-month course)
St. Michael's Hospital
Toronto, Ontario, Canada
Electrolytes
Number of participants with clinically significant abnormal electrolytes. Electrolytes include, Sodium, potassium, chloride, total CO2
Time frame: 9 months
Hemoglobin
Number of participants with clinically significant abnormal Hemoglobin
Time frame: 9 months
Renal Function
Number of participants with clinically significant abnormal urea and creatinine
Time frame: 9 months
Liver Function
Number of participants with clinically significant abnormal AST, ALT, and total bilirubin.
Time frame: 9 months
Change in Ferritin Levels
Number of participants with clinically significant abnormal ferritin levels
Time frame: 9 months
Blood Glucose Level
Number of participants with clinically significant abnormal glucose
Time frame: 9 months
Lipid Assessment
Number of participants with clinically significant abnormal total cholesterol and triglycerides
Time frame: 9 months
Total Number of Adverse Events (AEs)
Adverse events were monitored throughout the entire 9-month study period, including the 3-month baseline, 3-month treatment, and 3-month follow-up phases. However, only adverse events that occurred during the 3-month treatment period (i.e., when participants were actively receiving study drug) are reported here. This outcome measure is reporting the total number of adverse events across all participants that occurred during the 3-month treatment period. Adverse events were collected through patient self-reporting, clinical assessments at scheduled visits, and laboratory safety monitoring.
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Study Type
INTERVENTIONAL
Allocation
NA
Purpose
TREATMENT
Masking
NONE
Enrollment
10
Time frame: 3 months
Total White Blood Cells
Number of participants with clinically significant abnormal total WBC
Time frame: 9 months
Red Blood Cells and Platelets
Number of participants with Clinically Significant RBCs and platelets
Time frame: 9 months
Change in Epistaxis Duration (PRO-CB)
Epistaxis was assessed using the Patient-Reported Outcome of Cumulative Weekly Nose Bleeding Duration (PRO-CB), collected via daily patient diary throughout the study (3-month baseline, 3-month treatment, and 3-month follow-up periods).
Time frame: 9 months
Exploratory Biomarker Analysis Related to Angiogenesis and Inflammation
Plasma samples were collected for future analysis of circulating biomarkers associated with angiogenesis and inflammation in HHT. The specific biomarker panel is to be finalized in collaboration with the HHT Study Team, and may include proteins such as ANG2, sICAM1, PIGF, TSP2, sVEGFR2, BMP9, IL-6, SDF1, sVCAM1, sVEGFR3, sCD73, sIL6R, TGF-β1, VEGF, sENG, OPN, TGF-β2, VEGF-C, GP130, PDGF-AA, sTGFβR3, VEGF-D, HGF, PDGF-BB, TIMP1, and sVEGFR1. Quantification methods (e.g., ELISA, multiplex immunoassay) and timepoints will be determined prior to analysiThis is an exploratory, post-treatment outcome measure and no data are yet available.s. This is an exploratory, post-treatment outcome measure and no data are yet available.
Time frame: 9 months
Change in Epistaxis Severity Score (ESS) at Treatment and Follow-up Periods Compared to Baseline
Epistaxis severity was measured using the Epistaxis Severity Score (ESS). ESS was administered at each clinic visit throughout the 9-month study period. However, only the ESS scores collected at Week 12 (end of baseline), Week 24 (end of treatment), and Week 36 (end of follow-up) were used for this outcome analysis. The ESS ranges from 0 to 10, with higher scores indicating more severe epistaxis.
Time frame: 9 months