Branches Of External Carotid Artery: A Descriptive Study

Background: The common carotid artery (CCA) divides at the level of superior border of thyroid cartilage. Theexternal carotid artery (ECA) is one of the terminal branches of CCA. ECA gives three anterior branches, Superiorthyroid (STA), Lingual (LA) and Facial arteries (FA). Therefore the present study was carried out to describe thelevel of bifurcation of CCA, its relations with anatomical landmarks and the morphometry of anterior branchesof ECA in relation to bifurcation of CCA.Methods: The present study was carried on 30 sagittal head and neck sections. The level of bifurcation of CCAwas noted. The distances from CCA bifurcation to the superior border of thyroid cartilage (SBTC), angle ofmandible, ear lobule were measured. The ddistances of STA, LA & FA from CCA bifurcation were also measured.Results: In 16 (53.33%) cases the bifurcation of CCA was observed at the level of SBTC, 2 (6.67%)It was between SBTC and hyoid bone, in 5 (16.67%) below SBTC and in 6 (20%) at the level of hyoid bone. The meandistances from the bifurcation of CCA to the SBTC was 24 ± 0.95mm, to the angle of the mandible was 31 ± 0.86mmand to the ear lobule was 54.8 ± 0.96mm. The mean distances of STA, LA and FA from CCA bifurcation were 7.2 ± 0.2,12 ± 0.45 and 17.6 ± 0.48 cm respectively.Conclusion: The anatomical study of CCA is useful for angiographies, thyroid and head and neck surgeries. Incase of common trunks, stenosis or occlusion may cause severe ischemic consequences and prone toatherosclerosis.

Identification of cephalic vein in the deltopectoral groove and its surgical relevance.

Introduction: Identification and recognition of the cephalic vein (CV) in the deltopectoral triangle is of critical importance when considering emergency procedures. Therefore, the present cadaveric study was undertaken to identify the CV in the deltopectoral groove and its termination in the axillary vein with respect to the relevant anatomical landmarks. Material and methods: The length of the CV was taken from the lowest limit of the deltopectoral groove to its draining point into the axillary vein. The coracoid process (CP), first cost-chondral junction (CCJ) and the midclavicular point (MCP) were used as the landmarks and their distances from the drainage point of CV into the axillary vein were measured. Results: In all cadavers, the CV traversed the deltopectoral groove and terminated into the axillary vein. The mean length of the CV was 15.46 ± 1.57 cm. The distances of its drainage point from the sternoclavicular joint, midclavicular point, first costo-chondral junction and the coracoid process were 8.26 ± 0.99 cm, 3.51 ± 0.8 cm, 5.66 ± 0.71 cm and 5.16 ± 0.8 cm respectively. Conclusion: The present anatomical study describes the location of cephalic vein in relation to the anatomical landmarks which would be commonly used in the intervention procedures in this region.

Morphometric analysis of corpus callosum in relation to brain size in fetuses of South Indian population.

Background: The corpus callosum (CC) comprises axons connecting the cortices of the two cerebral hemispheres and is the principal white matter fiber bundle in the brain Morphological characteristics of fetal corpus callosum are of value from embryologic and diagnostic points of view. Knowledge of fetal callosal size is an essential prerequisite for the study of its changes during infancy and childhood. Methods: The study included twenty four formalin fixed fetuses ranging from 25 to 40 weeks obtained from department of Anatomy, Kasturba Medical College. The measurements taken were; frontal pole to occipital pole, anterior most point to posterior most point of CC, frontal pole of brain to anterior most point of CC, occipital pole of brain to posterior most point of CC, anterior edge of splenium to superior most point of superior colliculus and thickness of body of CC. Results: Spearman’s correlation test was used to determine the correlation between different parameters. A strong positive correlation was found between the length and gestational age (r=0.69), between thickness and gestational age (r=0.4) and between length and thickness of corpus callosum (r=0.5). Conclusions: Length and thickness of corpus callosum was found to increase proportionally to gestational age but it was not statistically significant. The growth of CC was proportional to the growth of brain. The precise anatomical knowledge regarding the morphology and growth of corpus callosum will provide baseline data for the diagnosis and assessment of progression of a disease affecting it.