Trials / Completed

CompletedNCT03534934

CT-Based Modeling of Bone Micro-Architecture and Fracture-Risk in COPD

Status: Completed
Phase: N/A
Study type: Interventional
Enrollment: 560 (actual)

Sponsor: Punam K Saha · Academic / Other
Sex: All
Age: 45 Years – 90 Years
Healthy volunteers: Accepted

Summary

The goal of this translational study is to establish a newly emerging CT-based tool for the characterization of changes in bone micro-architecture and assessment of their implications for fracture-risk in a population of COPD patients at risk for osteoporosis. The tool will be suitable and generalizable across emerging CT scanners from different vendors, and it will provide a more structurally-based assessment of osteoporosis and bone loss than is provided by simple bone density measures. The study will characterize the impact of different COPD-related factors on bone structure, and their implications for fracture-risk, leading to the development of a COPD-specific model for assessment of fracture-risk that will utilize patient-specific demographic, clinical and radiographic data, and CT BMD at the spine, as well as bone structural measures at the hip and/or ankle.

Detailed description

This translational study seeks to establish a Chronic Obstructive Pulmonary Disease (COPD)-specific fracture prediction model using the investigators unique computed tomography (CT)-based assessment of peripheral bone micro-architecture. Osteoporosis, a common comorbidity among patients with COPD, accelerates morbidity and mortality. The basis for this comorbidity is poorly understood, thus the need for characterizing the link between COPD-related factors and bone micro-architecture and their association to fracture-risk. Multiple COPD-related factors are associated with osteoporosis. Different COPD-related causes of bone loss may non-uniformly impact cortical and trabecular bone structures with varying mechanical consequences, reflective of divergent COPD-associated fracture-risk in individuals with similar bone mineral density (BMD). Little is known about this linkage, and the study goal is to fill this knowledge gap using a clinically suitable emerging CT-based tool for characterization of bone micro-architecture at peripheral sites. Specifically, this study will-(1) establish the generalizability of the investigators bone micro-architecture assessment applied to emerging low dose / high resolution CT scanners from different vendors; (2) assess its potential as compared to dual energy x-ray absorptiometry (DXA) to explain prevalent fractures and predict incident fractures among patients with COPD; (3) quantify the impact of different COPD-related factors on bone structures and their implications for fracture-risk; (4) identify COPD subtypes with rapid bone structural degeneration; and (5) develop a COPD-specific model for assessment of fracture-risk using patient-specific data. The study will take advantage of-(1) existing COPD patient cohorts with lung characterization at the University of Iowa (UI) and Columbia University (CU) representing a wide demographic range; (2) access to emerging CT scanners at both sites; and (3) unique image processing methodologies for quantifying three-dimensional bone structural metrics. The study will recruit 550 smokers with and without COPD from the UI and CU cohorts of the COPDGene and SPIROMICS studies. Smokers without COPD will comprise the control group for the study. At baseline and 3-year follow-up visits, the study team will collect-(1) data related to risk factors; (2) a lateral spine CT scout scan to assess vertebral fractures; (3) high resolution CT scans of the hip and ankle for computation of bone structural metrics; (4) whole-body, spine and hip DXA scans for evaluation of bone mineral density and body composition; and (5) DXA vertebral fracture assessment. This study will establish an emerging CT-based scanner-independent generalizable tool to assess bone response to different therapeutic interventions aimed at slowing or reversing bone loss, and possibly restoring bone structure, potentially leading to more patient-specific interventions. Also, this study seeks to explain the relationships among various COPD-related factors, bone structural changes and their implications for fracture-risk. Finally, a COPD-specific model for assessment of fracture-risk will be developed that will utilize patient-specific demographic, clinical and radiographic data, and CT BMD at the spine, as well as bone structural measures at the hip and/or ankle.

Conditions

Interventions

Type	Name	Description
DIAGNOSTIC_TEST	Vital signs	Heart rate, respirations, blood pressure, temperature, oxygen saturation arterial oxygen saturation (SaO2), height and weight
DIAGNOSTIC_TEST	Urine Pregnancy Test	Urine pregnancy test done on woman of childbearing potential.
OTHER	Questionnaires	Subject Questionnaire Calcium Intake Questionnaire Home and Work Activities Survey
DIAGNOSTIC_TEST	Blood Test	Blood test for vitamin D level, Hemoglobin A1c, and creatinine level
DIAGNOSTIC_TEST	Duel-energy X-ray absorptiometry scan	Bone density measurement
DIAGNOSTIC_TEST	Multi-detector computed tomography	Hip and ankle CT scan
DIAGNOSTIC_TEST	Dual-energy X-ray absorptiometry scan	Vertebral fracture assessment

Timeline

Start date: 2019-02-26
Primary completion: 2025-03-19
Completion: 2025-03-19
First posted: 2018-05-23
Last updated: 2026-01-28

Locations

2 sites across 1 country: United States

Regulatory

FDA-regulated device study

Source: ClinicalTrials.gov record NCT03534934. Inclusion in this directory is not an endorsement.