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Osteopathic Medicine and Primary Care
Published in: Osteopathic Medicine and Primary Care 1/2009

Open Access 01-12-2009 | Research

Assessment of calvarial structure motion by MRI

Authors: William T Crow, Hollis H King, Rita M Patterson, Vincent Giuliano

Published in: Osteopathic Medicine and Primary Care | Issue 1/2009

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Abstract

Background

Practitioners of manual medicine/manual therapy (MM/MT) who utilize techniques thought to have some impact upon and move the solid structures of the human head have been criticized for lack of evidence of cranial bone motion. The present study utilized magnetic resonance imagery (MRI) technology to address the question of whether or not inherent (non-operator initiated) calvarial structure motion can be assessed.

Methods

Subjects: Twenty healthcare professionals, (physicians, nurses, medical students, pharmacists) between the ages of 24 and 52 were recruited. Seven females (ages 25-47, mean age 36.7) and 13 males (ages 25-53, mean age 31.2) volunteered. Technology: MRI scans were acquired at 450 ms per slice, in a 1.5 Tesla Signa Excite HD closed MRI system. The same scan prescription was repeated serially every 45 seconds to obtain eight serial slices for each subject. Image analysis was accomplished using ImageJ software (ImageJ 1.33 u National Institutes of Health, USA). Data from all eight images for each of the 20 subjects were analyzed to determine the two images with the largest differences in the parameters measured.

Results

Difference values for the measures of area, width, height, major axis, and feret were statistically different whereas the measures for perimeter and minor axis were not. However, only the difference values for area were both statistically different (p < 0.003) and exceeded the resolution threshold of 0.898 mm/pixel.

Discussion

The statistically significant difference value for area is suggestive of inherent motion in calvarial structures, and adds to the body of evidence supportive of biomechanically measurable calvarial structure motion in general. That the total intracranial area appeared to expand and recede was consistent with theory and prior studies suggestive of calvarial structure motion due to intracranial fluid volume changes.

Conclusion

The use of MRI technology was able to demonstrate calvarial structure motion at a level exceeding the resolution threshold, and provides a means for further research on phenomena related to the cranial concept. It may be just a matter of time until increased resolution of MRI technology and image analysis provide the ability to examine more detailed areas of specific cranial bone motion.
Appendix
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Metadata
Title
Assessment of calvarial structure motion by MRI
Authors
William T Crow
Hollis H King
Rita M Patterson
Vincent Giuliano
Publication date
01-12-2009
Publisher
BioMed Central
Published in
Osteopathic Medicine and Primary Care / Issue 1/2009
Electronic ISSN: 1750-4732
DOI
https://doi.org/10.1186/1750-4732-3-8

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