Currently, there are no in vivo techniques for quantifying healing within fractures involving mainly trabecular bone. Methods for quantitatively assessing healing would aid the investigation of new treatment regimes, and might also be useful for predicting whether a patient may be undergoing delayed union. Using CT and automated image registration, we have developed an image processing technique for measuring changes in CT image intensity at fracture sites. The technique focuses on quantifying the formation of new mineralised tissue within fracture gaps, while ignoring loss of bone mineral due to disuse osteoporosis. Seven patients with fractures of the distal radius were examined for 12 weeks following fracture. To assess reproducibility of measurements of change in CT intensity at the fracture line, measurements were performed on two separate occasions, by each of two independent readers. Reproducibility was compared to rates of change over time, to determine detectable differences in individual progression. Scans were scored qualitatively for features of healing and scores compared to the quantitative measurements. The mean (SD) change in CT intensity was + 128 (65) Hounsfield Units (HU) over the 12 week follow‐up. Inter‐ and intra‐observer reproducibilities were both similar (±17 HU), 1/7 of the change seen during the study. In this small patient cohort, a significant increase in CT intensity was seen 2 weeks post‐fracture. Large early increases in CT intensity were associated with early visual appearance of sclerosis and blurring of the fracture line. In this preliminary, prospective study, we have developed a reproducible quantitative technique for measuring changes in CT intensity of trabecular bone at the fracture line in the distal radius. Further work is required to determine whether it can be used to identify, or monitor patients who are undergoing delayed fracture repair. The technique appears sensitive for measuring changes immediately post‐fracture, and could have a role in examining potential effects of new therapies in patient cohorts. © 2003 Orthopaedic Research Society. Published by Elsevier Ltd. All rights reserved.
[1]
Colin Studholme,et al.
An overlap invariant entropy measure of 3D medical image alignment
,
1999,
Pattern Recognit..
[2]
A. Valentin‐Opran,et al.
Clinical evaluation of rhBMP-2/ACS in orthopedic trauma: a progress report.
,
1999,
Orthopedics.
[3]
R F Kilcoyne,et al.
Acceleration of tibial fracture-healing by non-invasive, low-intensity pulsed ultrasound.
,
1994,
The Journal of bone and joint surgery. American volume.
[4]
T A Einhorn,et al.
The cell and molecular biology of fracture healing.
,
1998,
Clinical orthopaedics and related research.
[5]
J. Ryaby,et al.
Accelerated Healing of Distal Radial Fractures with the Use of Specific, Low-Intensity Ultrasound. A Multicenter, Prospective, Randomized, Double-Blind, Placebo-Controlled Study*
,
1997,
The Journal of bone and joint surgery. American volume.
[6]
S. Bulstra,et al.
Osteogenic activity of OP-1 bone morphogenetic protein (BMP-7) in a human fibular defect.
,
1999,
The Journal of bone and joint surgery. British volume.
[7]
A. Decherney,et al.
Reduced bone mass in reproductive-aged women with endometriosis.
,
1989,
The Journal of clinical endocrinology and metabolism.
[8]
Jay R Lieberman,et al.
The role of growth factors in the repair of bone. Biology and clinical applications.
,
2002,
The Journal of bone and joint surgery. American volume.