Your search keyword '"Colin G. Miller"' showing total 2 results

1. Thioredoxin reductase 1 regulates hepatic inflammation and macrophage activation during acute cholestatic liver injury

Author

Colin T. Shearn, Aimee L. Anderson, Colin G. Miller, Reed C. Noyd, Michael W. Devereaux, Nata Balasubramaniyan, David J. Orlicky, Edward E. Schmidt, and Ronald J. Sokol

Subjects

Hepatology

Published

2023

2. Development of a Clinical Workflow Tool to Enhance the Detection of Vertebral Fractures

Author

Cornelis van Kuijk, Joel Krasnow, Colin G. Miller, Takouhi Ozanian, Curtis W. Hayes, Ken Abrams, Alan Brett, Jon E Block, Radiology and nuclear medicine, and CCA - Clinical Therapy Development

Subjects

medicine.medical_specialty, Accuracy and precision, Radiography, Osteoporosis, Scoliosis, Lumbar vertebrae, Sensitivity and Specificity, Thoracic Vertebrae, Decision Support Techniques, Pattern Recognition, Automated, Workflow, Artificial Intelligence, Predictive Value of Tests, Image Processing, Computer-Assisted, medicine, Humans, Computer Simulation, Orthopedics and Sports Medicine, Observer Variation, Orthodontics, Lumbar Vertebrae, Models, Statistical, business.industry, medicine.disease, Surgery, Vertebra, medicine.anatomical_structure, Thoracic vertebrae, Spinal Fractures, Neurology (clinical), business, Software, Vertebral column

Abstract

STUDY DESIGN: Image analysis model development.OBJECTIVE: The objective of this study was to develop a novel clinical workflow tool that uses model-based shape recognition technology to allow efficient, semiautomated detailed annotation of each vertebra between T4 and L4 on plain lateral radiographs.SUMMARY OF BACKGROUND DATA: Identification of prevalent vertebral fractures, especially when not symptomatic, has been problematic despite their importance. There is a recognized need to increase the opportunities to detect vertebral fractures so that clinically beneficial therapeutic interventions can be initiated.METHODS: Radiographs obtained from 165 subjects in the Canadian Multicenter Osteoporosis Study (CaMos) were used to construct a vertebral shape model of the vertebral column from T4 to L4 using a statistical learning technique, as well as to estimate the accuracy and precision of this automated software tool for vertebral shape analysis. Radiographs showing scoliosis greater than 15 degrees were excluded.RESULTS: Vertebral contours defined by 95 points per vertebra, represented by 79,895 points in total, were assessed on 841 individual vertebrae. The mean absolute accuracy error calculated over each vertebra in each test image was 1.06 +/- 1.2 mm. This value corresponded to an average 3.4% of vertebral height. The mean precision error, reflecting interobserver variability, per vertebra of the resulting annotations was 0.61 +/- 0.73 mm. This value corresponded to an average 2.3% of vertebral height. Accuracy and precision error estimates did not differ notably by vertebral level.CONCLUSION: The results of the current study indicate that statistical modeling can provide a robust tool for the accurate and precise semiautomated annotation of vertebral body shape from T4 to L4 in patients who do not have scoliosis greater than 15 degrees . This method may prove useful as a clinical workflow tool to aid the physician in vertebral fracture assessment and might contribute to decision-making about pharmacologic treatment of osteoporosis.

Published

2009