Surgical anatomy of the medial collateral ligament and the posteromedial capsule of the knee.

The supporting structures on the medial side of the knee consist of a superficial fascial layer (I), a deep capsular layer (III) with the deep medial collateral ligament in it and in between the superficial collateral ligament (layer II). The attachment sites of the different ligaments and the functions of the various ligamentous structures are described and suggestions for surgical repair are given.

Effect of LVAD outflow conduit insertion angle on flow through the native aorta.

BACKGROUND AND AIM: The goal of this study was to evaluate the effect of surgical anastomosis configuration of the aortic outflow conduit (AOC) from a continuous flow left ventricular assist device (LVAD) on the flow fields in the aorta using CFD simulations. The geometry of the surgical integration of the LVAD is an important factor in the flow pattern that develops both in series (aortic valve closed, all flow through LVAD) and in parallel (heart pumping in addition to LVAD). METHODS: CFD models of the AOC junctions simulate geometry as cylindrical tubes that intersect at angles ranging from 30 degrees to 90 degrees. Velocity fields are computed over a range of cardiac output for both series and parallel flow. RESULTS: Our results demonstrate that the flow patterns are significantly affected by the angle of insertion of the AOC into the native aorta, both during series and parallel flow conditions. Zones of flow recirculation and high shear stress on the aortic wall can be observed at the highest angle, gradually decreasing in size until disappearing at the lowest angle of 30 degrees. The highest velocity and shear stress values were associated with series flow. CONCLUSIONS: The results suggest that connecting the LVAD outflow conduit to the proximal aorta at a shallower angle produces fewer secondary flow patterns in the native cardiovascular system.

Anatomical considerations for surgery of the anterolateral abdominal wall.

Closure of large incisional hernias with the Components Separation Method (CSM) could be explained by medial-caudal rotation of the internal and transverse oblique muscles around their centres of origin. In eight human cadavers, the CSM was performed, and translation of the rectus abdominis muscle was measured. Mean unilateral translation of the rectus abdominis in the lateral-medial direction measured 2.2, 3.7, and 3.5 cm. This was 2.7, 4.5, and 4.0 cm after release of the posterior rectus sheath. Mean translation in a caudal direction was 0.5 cm, but seven cadavers showed a mean translation of 1 cm of the uppermost measuring point in a cranial direction. The hypothesis that rotation of separate tissue layers of the abdominal wall largely accounts for the translation effect of the CSM must be rejected. Release of the external oblique muscle produces more benefit to abdominal wall closure than release of the posterior rectus sheath.

Mechanical influences on cells, tissues and organs - 'Mechanical Morphogenesis'.

Cells can sense changes in their mechanical environment and promote alterations and adaptations in tissue structure and function. Mechanical stimuli regulate such fundamental processes as cell division and differentiation and determine tissue form. The current editorial outlines the general scope of a subject area we have called 'mechanical morphogenesis'. We are promoting it as an area of special interest for future issues of the European Journal of Morphology. Clearly, mechanical loading is of pivotal importance to the development, function and repair of all tissues in the musculoskeletal system, including bone, ligament, tendon, skeletal muscle, intervertebral disc and meniscus. Bone in particular has attracted special interest and mechanical strain is central to both Wolff 's law and Frost's 'mechanostat' model of bone behaviour. But it is skeletal muscle that shows the most obvious and rapid response to altered load, with striated muscle fibres hypertrophing with strength-training programmes, and atrophing in the absence of adequate mechanical stimulation. Articular cartilage, together with tendons and ligaments is also responsive to changing exercise levels, and either abnormally high or low loads are detrimental. However, the influence of mechanical forces extends to many other organ systems, including the respiratory, cardiovascular, nervous and integumentary systems. The bronchial mucosa and the alveoli are subject to tensile and compressive loading during the volume changes that occur in respiration, and surface tension is also of paramount importance. The whole form of the cardiovascular system is driven by the haemodynamic influences of blood, and atherosclerosis has an underlying mechanical basis. The characteristic plaques tend to occur at sites of obvious mechanical significance - regions of arterial branching and curvature, where shear stress on the vessel wall may be low, but tensile stress high. Sensory perception by the nervous system has a well known mechanical basis and the cochlea is perhaps the most elaborate example of a site where sensory cells transduce mechanical forces and relay information to the brain. Mechanical force has also been proposed as a regulating factor in controlling axonal growth. Finally, the integumentary system has several structural adaptations that obviously relate to the influence of mechanical forces. The thickened layer of keratinised squames in the palms and soles is directly related to the high levels of shear at these locations.

Giving color to a new curriculum: bodypaint as a tool in medical education.

We describe a new method, bodypainting, to enhance courses in living anatomy. This novel approach was fully integrated in a course that comprised gross anatomy, living anatomy, and physical examination of the major abdominal and thoracic organs. We designed a course in which the students familiarized themselves with the surface markings and subsequently painted the full organ at the site of its projection on the body surface. Based on our first experiences, we conclude that the course is a successful and enjoyable means of teaching various aspects of anatomy in relation to physical examination. This was confirmed by an evaluation among the first groups of students.

Collateral ability of the circle of Willis in patients with unilateral internal carotid artery occlusion: border zone infarcts and clinical symptoms.

BACKGROUND AND PURPOSE: The circle of Willis is regarded as the major source of collateral flow in patients with severe carotid artery disease. The purpose of the present study was to assess whether the presence of border zone infarcts is related to the collateral ability of the circle of Willis in symptomatic (transient ischemic attack, minor stroke) and asymptomatic patients with unilateral occlusion of the internal carotid artery (ICA). METHODS: Fifty-one patients (35 symptomatic, 16 asymptomatic) and 53 control subjects were investigated. Patients had unilateral occlusion of the ICA and contralateral ICA stenosis between 0% and 69%. The directions of flow, on the side of the ICA occlusion, and the size of the component vessels in the circle of Willis were investigated with MR angiography. RESULTS: On average, 92% of the patients without border zone infarcts (n=26) had willisian collateral flow compared with 60% of patients with border zone infarcts (n=25; P<0.05). This increase in collateral flow was caused by the high prevalence of collateral flow via the posterior communicating artery in patients without border zone infarcts (50% versus 12%; P<0.05). No statistically significant relation was found between the pattern of collateral flow via the circle of Willis and the presence of clinical symptoms. Nevertheless, asymptomatic patients with ICA occlusion demonstrated an increased diameter of the anterior communicating artery (P<0.05). CONCLUSIONS: In patients with unilateral ICA occlusion, the presence of collateral flow via the posterior communicating artery in the circle of Willis is associated with a low prevalence of border zone infarcts. Asymptomatic patients with an ICA occlusion do not have an increased collateral function of the circle of Willis.

Flow quantification of the non-occlusive excimer laser-assisted EC-IC bypass.

BACKGROUND: For six years, we used the Excimer laser-assisted nonocclusive anastomosis technique for high-flow revascularization of the brain in patients with either nonclippable and noncoilable giant aneurysms of the internal carotid or basilar artery or progressive stroke associated with occlusive disease of the internal carotid artery. The aim of this study is to assess the blood flow capacity of this type of Extra-Intracranial bypass and its haemodynamic behaviour over time. METHODS: Twenty-six patients with a giant aneurysms and 8 patients with occlusive disease of the internal carotid artery were treated with the nonocclusive Excimer laser assisted EC-IC bypass. intra-operatively, direct measurements of flow in the EC-IC bypass were performed in all patients (Transonic Systems, Inc., Ithaca. NY). Postoperatively, follow up measurements of flow were performed with MR angiography in 14 patients with a giant aneurysm after occluding the internal carotid artery, and 7 patients with occlusive carotid disease. RESULTS: The mean flow in the laser assisted bypasses in the group of patients with a giant aneurysm was 158 ml/min after ligation or balloon occlusion of the ICA. The mean flow of the laser assisted bypass in the group of patients with ICA occlusive disease was 130 ml/min. A comparison with data on flow capacity of conventional EC IC bypasses is made. A demonstrated increase of flow in the bypass during follow up is discussed from a haemodynamic point of view. CONCLUSIONS: The results of this study demonstrate that the flow capacity of the nonoccluding excimer laser assisted bypass is much higher than the capacity of the conventional, more peripherally located conventional EC IC bypass, and should therefore be denoted as High-Flow EC IC bypass. Consequently, this type of bypass can be a powerful and safe tool in new revascularization strategies.

Flow redistribution in the major cerebral arteries after carotid endarterectomy: a study with transcranial Doppler scan.

PURPOSE: This open single-center prospective study aimed to determine the redistribution of blood flow within the circle of Willis and through collateral pathways after carotid endarterectomy. Blood flow velocity and flow direction in the major cerebral arteries were determined, both at rest and during CO(2) inhalation. METHODS: Carotid endarterectomy was performed in 148 patients with a 70% or greater diameter stenosis of the internal carotid artery while patients were under general anesthesia. Arteriotomy closure was done with a venous patch. Selective shunting was performed with an electroencephalogram. Baseline blood flow velocity of the basal cerebral arteries was measured by means of transcranial Doppler sonography preoperatively (within 1 week before surgery) and 3 months postoperatively. At the same times, cerebrovascular reactivity was calculated during CO(2) inhalation insonating both middle cerebral arteries. RESULTS: Baseline blood flow velocity in the ipsilateral middle cerebral artery hardly changed 3 months postoperatively, but there was a considerable redistribution of flow in the circle of Willis. This was characterized by a decrease in contribution from the contralateral hemisphere through the anterior communicating artery, reduced cerebropetal flow rates in the ophthalmic artery, and smaller contribution of the posterior collateral sources. The CO(2) reactivity on the side of surgery increased in all patients. In patients with a contralateral occlusion, CO(2) reactivity increased on both sides. The redistribution of flow was most pronounced in patients who needed intraoperative shunting and in patients with a contralateral internal carotid artery occlusion. CONCLUSION: After carotid endarterectomy, flow redistribution, as expressed by changes in blood flow velocity values, occurs in the circle of Willis. The contribution of collateral sources is diminished, and the CO(2) reactivity increases, both of which reflect improvement of the hemodynamic condition. The most improvement occurs in patients with contralateral occlusion.

Zinc sulphate-induced anosmia decreases the nerve fibre density in the anterior cerebral artery of the rat.

Detailed quantitative studies have demonstrated a topographical heterogeneity of nerve fibre densities in the cerebral arteries at the base of the brain as well as local changes in ageing and Alzheimer's patients. In this study, we test the hypothesis that local patterns of innervation are influenced by changes in flow fluctuations. This was investigated by inducing chronic anosmia and monitoring the nerve fibre density in the basal cerebral arteries in the adult rat. The olfactory epithelium was examined after staining with hematoxylin and eosin and showed a marked reduction of thickness in the anosmic group compared to the control group. The olfactory bulb was histochemically stained for succinate dehydrogenase (SDH) activity and showed a reduced staining in the anosmic group compared to the controls. Whole mount preparations of the basal cerebral arteries were immunostained for the general neural marker protein gene product (PGP) 9.5. The nerve fibre densities of the vessel walls were quantified by image analysis and expressed as area percentage and intercept density. This analysis showed a significant reduction in area percentage for the first part of the anterior cerebral artery, as well as for the second part of the anterior cerebral artery, and a significant reduction in intercept density for the second part of the anterior cerebral artery in the anosmic group. We conclude that peripherally induced anosmia decreases nerve fibre density in the anterior cerebral artery that may be due to a decreased metabolic activity in the rhinencephalon and, as a consequence, a reduction of flow fluctuations in the blood vessels supplying this area occurs.

Evaluation by solid vascular casts of arterial geometric optimisation and the influence of ageing.

In the theoretical analysis of arterial networks the existence of geometric optimisation has long been suggested, although observational studies have not yet fully corroborated these theories. Since this could be due to experimental flaws, the aim of this study was to establish the validity of arterial geometric optimisation using a new experimental design and to assess the influence of ageing. Solid vascular casts of arterial mesenteric branching systems of 8-wk-old and adult dogs (beagles) were used to examine vascular diameters and branching angles, the latter in a manner that allowed optimisation of the line of view, thus minimising distortion errors due to a line of view not normal to the branching plane. Internal and external vessel diameters were found to be in accordance with the theoretical principle of minimum work (8-wk-old internal: r = 0.994; adult internal: r = 0.971; adult external: r = 0.985). Although branching angles were found to be in agreement with basic qualitative principles of arterial branching geometry, the measurements still showed a large amount of scatter and were generally smaller than expected on theoretical grounds, despite the newly designed measuring technique. These branching angles demonstrated small age-related differences. However, when biological cost was considered per bifurcation, surprisingly, guidance towards minimum lumen volume and pumping power with increase in age could clearly be demonstrated (P < 0.001). It is concluded that our findings support the existence of a degree of arterial geometric optimisation in favour of minimum lumen volume and pumping power, increasing with age. Future investigations should focus on the biofeedback mechanisms involved.

Circle of Willis collateral flow investigated by magnetic resonance angiography.

BACKGROUND AND PURPOSE: The circle of Willis (CW) is considered an important collateral pathway in maintaining adequate cerebral blood flow in patients with internal carotid artery (ICA) obstruction. We aimed to investigate the anatomic variation of the CW in patients with severe symptomatic carotid obstructive disease and to analyze diameter changes of its components in relation to varying grades of ICA obstruction and in relation to the presence or absence of (retrograde) collateral flow. METHODS: Seventy-five patients with minor disabling neurological deficits and with ICA stenoses or occlusions were categorized into 4 groups according to the severity of ICA obstruction. This patient population reflected a relatively favorable subgroup of cerebral infarction (considering their minor neurological deficits). All subjects underwent magnetic resonance angiography, including magnetic resonance angiography sensitive to flow direction. CW morphology and the size of its components were determined and compared with those values in control subjects (n=100). RESULTS: Compared with control subjects, patients demonstrated a significantly higher percentage of entirely complete CW configurations (55% versus 36%, P=0.02), complete anterior configurations (88% versus 68%, P=0.002), and complete posterior CW configurations (63% versus 47%, P=0.04). Patients with severe ICA stenosis did not show significantly increased CW vessel diameters. Patients with ICA occlusion demonstrated a high prevalence of collateral flow through the anterior CW and significantly increased diameters of the communicating channels. Patients with bilateral ICA occlusion relied on collateral flow via the posterior CW and demonstrated a bilateral increase in posterior communicating artery diameters (P<0.05). CONCLUSIONS: The anatomic and functional configuration of the CW reflects the degree of ICA obstruction.

Symposium on 'Adaptations of cells and tissues to mechanical stimuli' or 'Roux revisited' held during the Joint Meeting of the Anatomical Society of Great Britain and Ireland, the Anatomical Society of Southern Africa and the Nederlandse Anatomen Vereniging, April 15-18 1998, Rolduc, The Netherlands.

In 1895, well over 100 years ago, Willem Roux published his collected works on the developmental mechanics of organisms in 2 volumes. Volume 1 is largely dedicated to functional adaptation and is a condensation of his investigations into causes of the size and shape of organs and tissues, postulating the influence of functional demand, mediated by mechanical stimuli, on the shaping of organs and tissues. In this classic work he contributed to the understanding of the control of the structural development and organisation of blood vessels, muscles and bone. This work has been a source of inspiration for many investigators over the years. Well known examples are Wolff's law and Pauwel's theory on trajectories. Over the past 2 decades these hypotheses and concepts have been reappraised using 2 main approaches. Firstly, in muscles and tendons a qualitative approach with classical Newtonian mechanics combined with the anatomical configuration of these structures has been used to study the direction and the nature of the mechanical stresses in the tissues, be they compressive, tensile or shear. In bone and blood vessels these stresses are less accessible and often require computer modelling to calculate the mechanics at a cellular level. Secondly, molecular biology has demonstrated, both in tissue culture and in animal experiments, that mechanical stimuli can bring about cascades of messages in and between cells, but the experimental control of mechanical stresses in biological experiments is far from simple and limits the conclusions that can be derived. In order to approach a complete picture, the gap between these 2 approaches must be bridged. In this respect modern imaging techniques are helpful because they offer the possibility of studying the shape and change of shape over time in living organisms in greater detail.The Symposium was organised in such a way that for different tissues recent advances using different approaches could be presented, helping to identify future directions for this field of morphological research. Review articles based on 2 of the 6 contributions to the Symposium are published here. One has already appeared (Benjamin & Ralphs, J. Anat. 193, pp. 481-494).

The effect of rotational head and neck movements on the afferent cerebral blood flow.

OBJECTIVE: To determine the effect of lateral rotational head and neck movements on the afferent cerebral blood flow in healthy adult humans so as to increase our knowledge of the relationship between arterial resistance and blood flow in the afferent cerebral arteries and in the arterial segments of the circle of Willis. DESIGN: Prospective, experimental study. SETTING: Department of Radiology and Department of Functional Anatomy, Utrecht University, Utrecht, The Netherlands. SUBJECTS: Nine healthy adult male human volunteers aged between 24 and 52 years participated in this study with informed consent. MAIN OUTCOME MEASURES: The changes in the afferent cerebral blood flow between the neutral (face to the front) and the rotated head positions (turn to the right and turn to the left). The relationship between the changes in the afferent cerebral blood flow and the angle of the head rotation. RESULTS: There were no significant differences between the changes in the afferent cerebral blood flow of the neutral and of the rotated head positions (p = 0.930 and p = 0.508 for the right and left head turns respectively). The correlation coefficients between the changes in the afferent cerebral blood flow and the angle of head rotation which ranged between 44.5 degrees and 72 degrees for the right turn and between 45 degrees and 72 degrees for the left turn were also not statistically significant (p = 0.191 for the right turn and p = 0.570 for the left turn). CONCLUSION: The most likely explanation for these observations was that the changes in resistance in the afferent cerebral arteries of these healthy volunteers were too small to produce significant blood flow changes. Therefore, we conclude that normal physiological lateral rotational head and neck movements do not produce any significant blood flow changes in the afferent cerebral arteries of healthy adults.

Early atherosclerotic lesions spiraling through the femoral artery.

Atherosclerosis is common in the adductor hiatus region. The aim of this study was to evaluate atherosclerosis in relation to themorphological structure of the femoropopliteal region. Two anatomic features are thought to play an important role in the origin of these lesions: (1) curvature of the vessel, which may lead to unfavorable local hemodynamic factors that change during leg flexion; and (2) abrupt changes in stiffness of surrounding tissues of the vessel. The distal part of 23 postmortem femoral arteries were investigated. Cross sections were obtained every 1 mm over a length of 100 mm. For each cross section, lesion thickness was measured at 12 points along the circumference of the vessel. No apparent relation was found between surrounding structures of the femoral artery and location of atherosclerotic lesions. Three-dimensional reconstructions showed that atherosclerotic lesions were spiraling through the artery in 18 of 23 cases. Spiraling atherosclerotic lesions may be consistent with expected flow patterns in this part of the femoral artery.

Relation of arterial geometry to luminal narrowing and histologic markers for plaque vulnerability: the remodeling paradox.

OBJECTIVE: To relate local arterial geometry with markers that are thought to be related to plaque rupture. BACKGROUND: Plaque rupture often occurs at sites with minor luminal stenosis and has retrospectively been characterized by colocalization of inflammatory cells. Recent studies have demonstrated that luminal narrowing is related with the mode of atherosclerotic arterial remodeling. METHODS: We obtained 1,521 cross section slices at regular intervals from 50 atherosclerotic femoral arteries. Per artery, the slices with the largest and smallest lumen area, vessel area and plaque area were selected for staining on the presence of macrophages (CD68), T-lymphocytes (CD45RO), smooth muscle cells (alpha-actin) and collagen. RESULTS: Inflammation of the cap or shoulder of the plaque was observed in 33% of all cross sections. Significantly more CD68 and CD45RO positive cells, more atheroma, less collagen and less alpha-actin positive staining was observed in cross sections with the largest plaque area and largest vessel area vs. cross sections with the smallest plaque area and smallest vessel area, respectively. No difference in the number of inflammatory cells was observed between cross sections with the largest and smallest lumen area. CONCLUSION: Intraindividually, pathohistologic markers previously reported to be related to plaque vulnerability were associated with a larger plaque area and vessel area. In addition, inflammation of the cap and shoulder of the plaque was a common finding in the atherosclerotic femoral artery.

A functional anatomic study of the relationship of the nasal cartilages and muscles to the nasal valve area.

The functioning of the nasal valve area is largely determined by the stability and the mobility of the lateral nasal wall. To gain insight into the kinematics of the lateral nasal wall, we studied the functional anatomy of the nasal muscles and the intercartilaginous and osseous-cartilaginous junctions. We performed gross and microscopic nasal dissection and serial sectioning in 15 human cadaveric noses. In addition, two noses were used for three-dimensional reconstruction of the nasal cartilages. We conclude that the lateral nasal wall can be seen as made up of three parts. At the level of the osseous-cartilaginous chain of bone, lateral nasal cartilage, and lateral crus, the lateral nasal wall is relatively stable, limited mobility being allowed by translation and rotation in the intercartilaginous joint and a coupled distortion of the cartilages. At the level of the hinge area the lateral nasal wall is supported by one or more accessory cartilages, embedded in soft tissue, and therefore much more compliant. The alar part of the nasalis muscle, which originates from the maxilla and inserts on these cartilages, may dilate the valve area by drawing this hinge area laterally. The third and most compliant part of the lateral nasal wall is the part that is not supported by cartilage, the ala. The dilatator naris muscle largely occupies the ala and is attached to the lateral crus; it opens the vestibule and nostril. The third nasal muscle that influences the lateral nasal wall is the transverse part of the nasalis muscle. It overlies the nose but is not attached to it. This muscle stabilizes the lateral nasal wall, in particular, the lateral nasal cartilage, the intercartilaginous junction, and the hinge area, by moving the nasal skin.

Collateral hemodynamics after middle cerebral artery occlusion in Wistar and Fischer-344 rats.

We investigated whether the difference in infarction volume after occlusion of a long proximal segment of the middle cerebral artery between Wistar and Fischer-344 rats, is caused by differences in collateral blood flow rate through leptomeningeal anastomoses. In view of the retrograde direction of collateral blood flow into the middle cerebral artery territory, we developed parasagittal laser-Doppler flowmetry. Using this method two laser-Doppler probes are placed on the cerebral cortex: probe 1 is placed near the anastomoses between the middle- and anterior cerebral artery, probe 2 is placed 2 mm further away from these anastomoses than probe 1. We found in both rat strains a comparable relation between the areas under the curve of the signal measured by both laser-Doppler probes for 2 h after middle cerebral artery occlusion. This relation is considered to be a measurement of the collateral blood flow rate into the middle cerebral artery territory through leptomeningeal anastomoses after middle cerebral artery occlusion. We conclude that collateral blood flow for the two strains were essentially similar for the initial 2 h after MCA occlusion. Although these collateral blood flows could have been different at a later time, it is unlikely that the interstrain difference in cerebral infarction volume between Wistar and Fischer-344 rats after proximal middle cerebral artery occlusion is caused by an apparent interstrain difference in the magnitude of collateral blood flow rate through leptomeningeal anastomoses. The parasagittal laser-Doppler flowmetry technique we developed for these experiments is currently successfully used in our laboratory to evaluate the efficacy of hemodynamically active pharmacotherapeutical agents in raising the collateral blood flow rate into the middle cerebral artery territory after middle cerebral artery occlusion.

Rat middle cerebral artery occlusion by an intraluminal thread compromises collateral blood flow.

We compared in Wistar rats collateral blood flow through leptomeningeal anastomoses after middle cerebral artery occlusion using craniotomy ('extravasal occlusion'), which results in a small volume of cerebral infarction, and after intraluminal thread occlusion ('intravasal occlusion'), which produces a large volume of cerebral infarction. Simultaneous laser-Doppler flowmetry with two probes placed on the cerebral cortex was used to measure and compare collateral blood flow. Extravasal occlusion caused a cortical blood flow reduction along a gradient in lateral direction, whereas blood flow reduction after intravasal occlusion was more uniformly distributed. It is concluded that permanent intravasal occlusion compromises collateral blood flow and therefore may not be a suitable model for measuring the ability of pharmacotherapeutic agents, if any, to improve collateral blood flow acutely after middle cerebral artery occlusion. The two models can be useful for testing drugs on parenchymal neuroprotective properties. Thereby, the intraluminal technique is preferred because of the possibility to study reperfusion damage when transient occlusion is applied.

Localizing role of hemodynamics in atherosclerosis in several human vertebrobasilar junction geometries.

Atherosclerosis is a common finding in the vertebrobasilar junction and in the basilar artery. Several theories try to link the process of atherogenesis with the forces exerted by the flowing blood. An attractive relation has been found between the locations in vessels at which atherosclerotic plaques are often present and the locations in models where complicated flow patterns exist. Most of the studies provided data on bifurcations. Finding a similar relation in an arterial confluence would certainly add to the credibility of the (causal) relationship between hemodynamics and atherosclerosis. Further support can be provided if variations of the geometry result in changes of the location of the atherosclerotic lesions, corresponding to the changes of the flow force distribution. In our previous numerical and experimental work, the influence of geometric and hemodynamic parameters, such as asymmetrical inflow, confluence angle, and blunting of the apex, on the flow in vertebrobasilar junction models has been investigated in detail. Recirculation areas and distribution of the wall shear stress have been computed. In this anatomic study, the effect of modulation of these geometric and hemodynamic parameters on the flow pattern is compared with the size and location of plaques in human vertebrobasilar junctions and basilar arteries. In addition, a comparison is made between the preferential areas of atherosclerotic plaques in junctions and bifurcations to demonstrate the localizing role of hemodynamics in atherogenesis. The apex of the vertebrobasilar junction and the lateral walls of the basilar artery appeared to be prone to atherosclerosis. In 43 of 85 vertebrobasilar junctions, a plaque was found at the apex. Furthermore, the summed plaque thickness at both lateral walls differs significantly (paired t test, P=.03) from that at the walls facing the pons and the skull base. In contrast, several authors found that the lateral walls of the mother vessel and the apex in bifurcations are often spared. Modulation of the various parameters in the models changed the size of the regions with low wall shear stress and/or recirculation areas dramatically. A comparable effect was found in the occurrence of plaques in the human vertebrobasilar junction; eg, for an atherosclerotic plaque at the apex, a predicted probability larger than 0.5 was computed for blunted apexes and for sharp-edged apexes with a confluence angle exceeding 90 degrees. Apparently, two geometric risk factors for an atherosclerotic plaque at the apex can be distinguished: a blunted apex and a large confluence angle.