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The Incidence and Outcomes of Metabolically Active Brown Adipose Tissue (aBAT) in Patients With Pheochromocytoma or Paraganglioma (PPGLs)

NCT06440122 · Status: RECRUITING · Type: OBSERVATIONAL · Enrollment: 100

Last updated 2024-06-03

No results posted yet for this study

Summary

White adipose tissue (WAT) and brown adipose tissue (BAT) form the main adipose tissue subtypes in humans and several animals. BAT, owing to its unique metabolic function, has been of increased focus and interest in metabolic research (1). BAT forms the major organ of non-shivering thermogenesis in the body, and is dependent on the large concentration of mitochondria and increased uncoupling protein-1 (UCP-1) activity present in this type of tissue (2). There are numerous triggers for the metabolic activation of BAT including cold temperature, low body mass index (BMI), adrenergic agonists, and elevated concentration of thyroid hormones (3).

BAT is found more abundantly in fetuses and infants, with significant regression into adulthood. The main areas where BAT can be found are the neck, mediastinum, axilla, retroperitoneum, and abdominal wall (4). Clinical research suggests that activation and thermogenesis in BAT are mediated by noradrenaline release from the sympathetic nervous system (5). With the increasing use of fluorodeoxyglucose positron emission tomography (18FDG-PET) imaging, there has been an increased detection rate of activated brown adipose tissue (aBAT); this may affect diagnoses and lead to false-positive reporting (6).

Phaeochromocytomas/paragangliomas (PPGLs) are chromaffin-cell-derived endocrine tumors that emerge from the adrenal medulla or extra-adrenal ganglia. High FDG accumulation has been commonly noted in aBAT in patients with catecholamine-producing tumours, with subsequent resolution of these findings after resection of the tumour (7). This finding is likely related to the increased glucose transport related to noradrenaline excess (4). BAT has traditionally been considered to mainly express β3-adrenoreceptors; however, in vitro studies have indicated that activated β2-adrenoreceptors may be the main driving force behind thermogenesis (8).

Studies reviewing PPGLs have shown an aBAT detection rate of 7.8% to 42.8% on FDG-PET imaging, correlating with elevated catecholamine levels but without clear correlation to germline mutations (9-12). In one study, this imaging finding was associated with a statistically significant reduction in overall survival (12). Standardisation for the 'standardised uptake value' (SUV) cut-offs for aBAT on FDG-PET are lacking, but these are often reported between 1.0 and 2.0 (13); in previous studies of PPGL, a cut-off value of \>1.5 has been employed (10, 12).

Research on the clinical implications of aBAT in patients with PPGL remains scarce. The main objectives of this study were to gain further insights into BAT activation rates in patients with PPGLs and how this may relate to patient demographics, biochemistry, radiological features, mutational status, and outcomes. The main hypotheses were that aBAT rates would be significantly linked to the severity of catecholamine excess and could be considered a poor prognostic feature.

Conditions

  • Pheochromocytoma
  • Paraganglioma

Interventions

DIAGNOSTIC_TEST

FDG-PET Scan

Positive for activated brown adipose tissue (SUVmax \>1.5) FDG-PET scan

Sponsors & Collaborators

  • King's College Hospital NHS Trust

    lead OTHER

Principal Investigators

  • Georgios Dimitriadis · King's College Hospital NHS Trust

Eligibility

Min Age
18 Years
Max Age
80 Years
Sex
ALL
Healthy Volunteers
No

Timeline & Regulatory

Start
2024-05-31
Primary Completion
2024-09-30
Completion
2024-12-31

Countries

  • United Kingdom

Study Locations

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Read the full study record

This page highlights key information. For complete eligibility criteria, study locations, investigator contacts, and the full protocol, visit the original record on ClinicalTrials.gov.

View NCT06440122 on ClinicalTrials.gov