dc.description.abstract |
Over the past decade, faster CT scan, thinner collimation, and the
development of multi detector computed tomography (MDCT), coupled with
the increasing capability of computers to process large amounts of data in
short periods of time, have lead to an expansion in the ability to create
diagnostically useful two-dimensional (2D) and three-dimensional (3D)
images within the thoracic inlet. Applications within the thorax include, but
are not limited to, evaluation of systemic vasculature, and the trachea, and
delineation of thoracic inlet disease. Multiplanar (MPR) images increased
understanding of thoracic inlet anatomy. Because there are strengths and
weaknesses to all the reconstruction algorithms, the utility of any given
technique is dependent on the clinical question to be answered. For instance,
although maximum intensity projection imaging (MIP) is helpful in the
evaluation of blood vessels, it is of little value in the diagnosis of enlarged
lymph nodes.
The importance of this study comes from the importance of thoracic inlet
because it is a common area to obtain venous access for renal dialysis, or CT
guided biopsy and has many structures with variations in appearance which
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mimic pathological changes. It is important to have a clear understanding of
the anatomy of the thoracic inlet structures and their relationship to each
others to avoid accidently arterial puncture or nerve damage in CT guided
biopsy or misinterpretation of normal structures e.g non opacity blood vessel
as enlarged lymph nodes. Computed tomography is an excellent method to
delineate the anatomy of thoracic inlet structures. Variations in the anatomy
of the thoracic inlet structures and their correlation to the x-ray findings.
This study aims to objectively evaluate the variations in the anatomy of
thoracic inlet structures, the structures sizes, appearance and their relations to
each others. A total of 328 patients were evaluated using MDCT imaging.
The measurements and identifications of thoracic inlet structures were done
at five levels, 7th cervical vertebra, 1st, 2nd, 3rd, and 4th thoracic vertebra. The
average size of main thoracic inlet structures, trachea, esophagus, internal
jugular vein IJV, common carotid artery CCA subclavian artery and neural
canal was measured. The percentages of identifying small vessels, lymph
nodes, thyroid gland, thyroid isthmus, thymus gland, neck muscles, thoracic
duct, right lymphatic duct and nerve were recorded and analyzed. The study
showed differences in sizes of some of thoracic inlet anatomical structures,
between males and females group. In bilateral structures e.g the right internal
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jugular vein (RIJV) was more often larger than the left internal jugular vein (IJV).
With reference to the common carotid arteries (CCA), 78.5% of the IJV were
found in the lateral position, 20.5% anteriorly 1.0 % posteriorly. There were
significant differences in appearance of identified structures at different levels. The
appearance of lymph nodes, was more in tumor patients (36%) followed infection
patients (9%). Thymus remnant was more identified in yang patients, (76.6%) in
age group 30to 40 years, (65. 5 %) in age group, 41 to 50 years, and only (10.5 %)
in group above 50 years. |
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