A multi-step procedure was developed to register magnetic resonance imaging (MRI) and histological data from the same sample in the light microscopy image space, with the ultimate goal of allowing quantitative comparisons of the two datasets. The fixed brain of an owl monkey was used to develop and test the procedure. In addition to the MRI and histological data, photographic images of the brain tissue block acquired during sectioning were assembled into a blockface volume to provide an intermediate step for the overall registration process. The MR volume was first registered to the blockface volume using a combination of linear and nonlinear registration, and two dimensional (2D) blockface sections were registered to corresponding myelin stained sections using a combination of linear and nonlinear registration. Before this 2D registration, two major types of tissue distortions were corrected: tissue tearing and independent movement of different parts of the brain, both introduced during histological processing of the sections. The correction procedure utilized a 2D method to close tissue tears and a multiple iterative closest point (ICP) algorithm to reposition separate pieces of tissue in the image. The accuracy of the overall MR to micrograph registration procedure was assessed by measuring the distance between registered landmarks chosen in the MR image space and the corresponding landmarks chosen in the micrograph space. The average error distance of the MR data registered to micrograph data was 0.324 ± 0.277 mm, only 8% larger than the width of the MRI voxel (0.3 mm).
Background:
We compared diagnostic ultrasound images of the plantar fascia with available patient histories for symptomatic patients previously diagnosed as having plantar fasciitis. Plantar fascia thickness and depth, the prevalence of perifascial hypoechoic lesions, and injury timelines in patients were reviewed.
Methods:
Images and histories for 126 symptomatic patients were collected from a patient database. We documented plantar fascia depth and thickness and the visualization of hypoechoic perifascial lesions. After image analysis, the obtained plantar fascia thickness measurements were compared with various patient attributes for possible relationships, including age, weight, and body mass index. In addition, plantar fascia thickness measurements were separated based on injury timeline as well as symptomatic/asymptomatic foot for patients with unilateral conditions to check for significant differences between subgroups. These were, in turn, compared with a control group of 71 individuals with no heel pain or diagnosis of plantar fasciitis.
Results:
Overall, mean ± SD symptomatic thickness (n = 148) was 6.53 ± 1.56 mm. Mean ± SD symptomatic depth (n = 136) was 13.36 ± 2.14 mm. For the control group, mean ± SD thickness was 3.20 ± 0.66 mm and depth was 10.30 ± 2.00 mm. Comparison of thickness based on injury timeline showed two significant differences: acute injuries (≤3 months) are significantly thicker than chronic injuries (>3 months), and only acute symptomatic thicknesses are significantly different from their asymptomatic thickness counterparts. Age, weight, and body mass index did not show significant correlations to thickness. Analysis of ultrasound images showed that 93% of symptomatic feet had hypoechoic lesions.
Conclusions:
Injury timeline and the presence of hypoechoic lesions may play important roles in patient discomfort, diagnosis, and treatment of plantar fasciitis.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.