Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT04280523 |
| Other study ID # |
191946 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
Phase 2
|
| First received |
|
| Last updated |
|
| Start date |
January 5, 2021 |
| Est. completion date |
December 31, 2023 |
Study information
| Verified date |
February 2024 |
| Source |
Vanderbilt University Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Pulmonary arterial hypertension (PAH) is a disease characterized by elevated pressures in the
blood vessels of the lungs that is not caused by another disease processes. More
specifically, it is defined by a mean pulmonary artery pressure > 25 mm Hg, a pulmonary
vascular resistance > 3 Wood Units (WU), and a normal pulmonary capillary wedge pressure in
the absence of other etiology of pulmonary hypertension. The underlying mechanism of the
disease in still unknown, but marked changes to the small arteries in the lungs have been
observed. These changes include thickening of vessel walls and clot formation -- making the
vessels less capable of gas exchange. Currently, PAH therapies focus on dilating the "good"
remaining vessels that haven't been altered by this disease process; however, this therapy
does not cure the disease. Survival remains low despite progress.
There is growing human and experimental evidence supporting the concept that estrogens and
estrogen receptors in the lungs are involved in the process that leads to PAH.
As mentioned above, no current therapies attack the cause of PAH; they only act to dilate
remaining "good" vessels which can reduce the burden of the disease, but not cure it. Thus,
there is a critical need for novel therapeutics, as recently highlighted by a National
Institute of Health workshop on pulmonary vascular diseases which called for the exploration
of novel therapeutic approaches. None of the current FDA-approved treatments for PAH target
estrogen or estrogen receptors.
Despite the evidence supporting the concept that estrogens and estrogen receptors in the
lungs contribute to PAH, no human studies investigate the estrogen level and the amount of
estrogen receptors within the lungs of patients with PAH and their potential associations
with current disease severity or 1 year outcomes including survival after 1 year, functional
status, etc. Investigators hypothesize that a subset of PAH patients will have higher levels
of estrogen and estrogen receptors in their lungs which would make them good candidates for
novel therapies that block estrogen in hopes of halting the disease process.
Description:
The strongest established risk factor for the progressively fatal disease pulmonary arterial
hypertension (PAH) is female sex (~3:1 female:male ratio). Investigators and others have
found higher circulating estrogen levels, and enhanced estrogen signaling, in PAH patients.
Evidence suggests that exuberant estrogen signaling causes a perturbation of mitochondrial
function and energy substrate utilization in both sexes. However, systemic estrogen level
elevation is not uniform among patients, and the affinity of the pulmonary vascular bed for
estrogens is unknown. In preliminary studies of prevalent PAH patients, estradiol (E2) levels
dropped across the pulmonary vasculature suggestive of E2 uptake by the lungs; those patients
with a high transpulmonary gradient (pre- minus post-capillary) had a higher mean pulmonary
artery pressure at diagnosis.
Investigators previously confirmed that urine 16α-hydroxyestrone (16αOHE1) is elevated at
least 2-fold in females and males with PAH, consistent with data from other groups that
estrogens are elevated in PAH. 16αOHE1 is an estrogen metabolite with high affinity for the
canonical estrogen receptors (ESRα and ESRβ) and thus an active estrogen. Investigators
published that in a transgenic mouse model of PAH, administration of 16αOHE1 significantly
increased PAH penetrance concomitant with features of oxidant stress including elevated
isoprostanes (IsoPs) and isofurans (IsoFs). Those animals also developed insulin resistance
and mitochondrial dysfunction, characteristics investigators have described during the
current PPG in humans with PAH. Concomitantly, through ESR signaling, 16αOHE1 reduced PPARγ
expression via reduction in PGC1α. By co-administering drugs to block extra-gonadal estrogen
synthesis and receptor signaling investigators were able to prevent or reverse the cellular
metabolic defects and pulmonary vascular phenotype in investigators' transgenic model system.
The capacity for enhanced estrogen signaling, represented by elevated blood E2 levels,
elevated urinary 16αOHE1, and specific genetic variants, is a characteristic of PAH patients
of both sexes in several studies. Experimental data from investigators' group and others
support the concept that estrogen antagonism may be beneficial for humans with PAH. However,
investigators recognize that not all subjects will benefit from estrogen antagonism, making a
'one size fits all' approach too narrow.
Investigators and others have shown that estrogens directly alter pulmonary vascular cell
homeostasis and gene expression, including reduction in BMPR2 expression and signaling via
ESR; and, experimental PAH models demonstrate increased expression of aromatase, an enzyme
which converts androgens to estrogens, in the lungs. But no human studies investigate the
direct contribution of the pulmonary circulation to estrogen avidity, ESR density, and
outcomes. Investigators propose to evaluate the influence of estrogens on the pulmonary
vasculature and cardiac function, using incident and prevalent PAH cases to reduce
confounding by disease course. Findings from this study should help determine patients most
likely to have a beneficial response to estrogen antagonism, supporting the overall project
goal to improve "precision medicine" approaches in PAH.
Investigators hypothesize that blood-based and radiologic markers of estrogen burden will
support the determination of a phenotype profile of subjects with PAH for whom estrogen
antagonism will be an effective therapeutic approach. In a cohort of PAH patients,
investigators will determine if transpulmonary (change pre- to post-pulmonary capillary bed)
E2 levels and/or lung ESR density associate with disease severity at cardiac catheterization,
functional capacity, time to clinical worsening, and oxidant stress.
Specific Aim 1: To test the hypothesis that among PAH patients, transpulmonary (TP) E2
gradient associates with a more severe hemodynamic profile and worse 1 year outcomes.
Specific Aim 2: To test the hypothesis that among PAH patients, higher lung ESR density
associates with a more severe hemodynamic profile and worse 1 year outcomes.
These studies may ultimately lead to novel discoveries in the transpulmonary gradient of sex
hormones, investigate a novel imaging approach in PAH, optimize the ability to precisely
determine the correct patient for sex hormone modification, and potentially support the
development of novel therapeutic targets in PAH. The data collected in this study will also
synergize with an ongoing NIH-supported clinical trial to investigate the use of sex hormone
modification as a therapeutic approach for PAH:
ClinicalTrials.gov Identifier: NCT03528902.
