22 research outputs found

    Morphological characteristics of diffuse idiopathic skeletal hyperostosis in the cervical spine

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    <div><p>Objectives</p><p>Diffuse idiopathic skeletal hyperostosis (DISH) is characterized by anterior ossification of the spine and can lead to dysphagia and airway obstruction. The morphology of the newly formed bone in the cervical spine is different compared to the thoracic spine, possibly due to dissimilarities in local vascular anatomy. In this study the spatial relationship of the new bone with the arterial system, trachea and esophagus was analyzed and compared between subjects with and without DISH.</p><p>Methods</p><p>Cervical computed tomography (CT) scans were obtained from five patients with dysphagia and DISH and ten control subjects. The location of the vertebral and carotid arteries, surface area of the hyperostosis and distance between the vertebral body and the trachea and esophagus was assessed in the axial view.</p><p>Results</p><p>The surface area of the newly formed bone was located symmetrically anterior to the vertebral body. The ossifications were non-flowing in the sagittal view and no segmental vessels were observed. Substantial displacement of the trachea/esophagus was present in the group with DISH compared to the controls.</p><p>Conclusions</p><p>The hyperostosis at the cervical level was symmetrically distributed anterior to the vertebral bodies without a flowing pattern, in contrast to the asymmetrical flowing pattern typically found in the thoracic spine. The hypothesis that the vascular system acts as a natural barrier against new bone formation in DISH could be further supported with these findings. The significant ventral displacement of the trachea and esophagus may explain the mechanism of dysphagia and airway obstruction in DISH.</p></div

    Results of the four different types of measurements.

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    <p>The location of the major arteries in the cervical spine was in all cases and at all levels lateral to the parallel lateral lines for the DISH and control group as shown in (A). The median total surface area of the newly formed bone per cervical level was significantly larger at the anterior location compared to the lateral location (B). There was no statistical difference between the left and right side of the MAP line (C). The distance between the center of the vertebral body and the trachea/esophagus was significantly larger in the group with DISH compared to the control group (D). The asterisk represents a p-value ≤ 0.05 and the triple asterisk represents a p-value ≤ 0.001. The error bars represent the standard error. VB–Vertebral body.</p

    Graphical illustration of the planes used for the measurements.

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    <p>Measurements were performed at three levels in the C4, C5 and C6 vertebral bodies. The axial CT images were reconstructed to planes parallel to the endplate. (A) Sagittal CT image from a 69 year old male. The illustration (B) shows the three levels (C4, C5, C6) and three transverse locations at C5 (1, 2, 3) that were used for the measurements in the axial plane. The dashed line 1 shows the level adjacent to the cranial endplate, line 2 the mid-vertebral level and line 3 the level adjacent to the caudal endplate. The same approach (using the three lines for the transversal levels) was also used for the C4 and C6 vertebral body.</p

    Graphical illustration of the measurements on the CT images.

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    <p>In (A) the CT scan is shown of a control subject with corresponding illustration (B). The parallel lateral lines are presented in light blue and carotid and vertebral arteries in red. CT scan (C) represents a male subject with DISH (72 years old) and matches illustrations (D and E). The parallel lateral lines (light blue) and the midsagittal anteroposterior (MAP) line (dark blue) were used to compare the different surface areas of newly formed bone (light/dark grey). CT scan (F) shows a male subject with DISH (61 years old) and corresponds to illustrations (G and H). The green lines demonstrate the distances between the center of the vertebral body and the trachea and esophagus, respectively.</p

    Typical examples of newly formed bone due to DISH in the cervical and thoracic spine.

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    <p>(A) Plain lateral radiograph shows a 69 year old male with DISH in the cervical spine. A solid formation of new bone is extending over at least four vertebral bodies. (B) Computed tomography (CT) visualizes the thoracic spine of a 72 year old male in the sagittal view. The scan shows a flowing ossification of the anterolateral spine with bridging over more than four contiguous vertebral bodies. The intervertebral discs and apophyseal joints are relatively intact in both images. (C + D) The CT scans in axial view demonstrate the differences in position of the new bone formation depending on the region. (C) The CT scan of the cervical spine corresponds to the radiographic image (A) and demonstrates symmetrical hyperostosis (yellow) anterior to the vertebral body and possible displacement of the trachea. (D) The axial CT of the mid thoracic spine in a 58 year old male with DISH shows the newly formed bone on the right anterolateral side with the aorta clearly located on the left anterolateral side.</p

    Frequency of white matter lesions.

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    <p>Voxels with white matter lesion (WML) in at least 5 patients are projected on a 2 mm MNI-152 template (Z and Y coordinates are provided). Bar indicates the number of patients with WML for each voxel.</p

    Workflow of the radial symmetry transform.

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    <p>An example slice of a 3.0 T T2*-weighted image with a microbleed is shown in A. B shows a zoom-in of the microbleed shown in A. An intermediate step of the radial symmetry transform is shown in C, where each voxel contributes to some neighboring voxel. If multiple arrows point towards the same target voxel, this target voxel receives a high radial symmetry value. The output of the radial symmetry transform is shown in D, displaying a large value at the center voxel of the microbleed.</p

    Sensitivity of manual and semi-automated rating.

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    <p>Final sensitivities of the individual human raters, all raters combined, and the three chosen combinations of the radial symmetry transform. A total of 152 microbleeds was found (148 during visual rating +4 extra positives by the radial symmetry transform) in 38 participants (53%).</p

    Results of the radial symmetry transform after censoring potential microbleed locations per participant.

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    <p>Total number of detected true positives, extra positives, false positives, and total time required to censor the false positives in all participants. Median rating time required by rater 4, with the interquartile range (Q1 and Q3), is shown. In the visual ground truth rating, 148 microbleeds were found in the 72 participants.</p

    Results of linear regression models with indicators of cerebral small vessel disease as variables and Z-scores of executive functioning as outcome.

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    <p>The explained variance (R<sup>2</sup>) in executive functioning is given for each model with the corresponding p-value for the difference in explained variance (Δ R<sup>2</sup>) between the model and the previous model. Unstandardized coefficients (B) with corresponding 95% CIs are provided. LL: lacunar lesion. WML: white matter lesion. SLF: superior longitudinal fasciculus. ATR: anterior thalamic radiation. Presence of LLs (which corresponds with presence of LLs anywhere in the brain) was entered as a dichotomous variable; all other variables were entered as continuous variables.</p>a<p>These results suggest that LLs in the anterior thalamic radiation (B = −3.12) might have greater impact on executive functioning than LLs in the superior longitudinal fasciculus (B = −1.20).</p
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