Abstract
Purpose
Unilateral agenesis of the internal carotid artery (ICA) is a rare anatomical variant. We identified a case of unilateral ICA agenesis with interparaclinoid and contralateral carotid-ACA anastomoses.
Methods
A 65-year-old female with a long history of depressive episodes underwent MR imaging including MR angiography at National Hospital Organization Kyushu Medical Center. MR imaging was performed using a 3.0-T MR scanner to rule out vascular Parkinsonism, although drug-induced Parkinsonism was suspected from her medical history.
Results
The proximal left ICA was not visible on MR angiography, and an anterior communicating artery (ACoA) aneurysm was identified. The left middle cerebral artery was supplied from the right ICA via an interparaclinoid anastomosis. This interparaclinoid anastomosis showed no communication with the basilar, posterior communicating, or posterior cerebral arteries. A communicating artery connecting the interparaclinoid anastomosis and anterior cerebral artery (ACA) branched off from the presumed transition point between the interparaclinoid anastomosis and left ICA. Both right and left ophthalmic arteries (OAs) originated from the clinoid segment of the ICA. The communicating artery connecting the interparaclinoid anastomosis and ACA arose proximal to the left OA, and the communicating artery was identified as the carotid-ACA anastomosis.
Conclusion
Neuroradiologists, physicians, and neurosurgeons need to be aware of this extremely unusual anatomical variant to determine appropriate treatment strategies in cases of aneurysmal growth or anterior cranial base surgery.
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Introduction
Agenesis of the internal carotid artery (ICA) is usually found incidentally without clinical symptoms. An association between ICA agenesis and anterior communicating artery (ACoA) aneurysm has been reported [1, 7]. The increased incidence of cerebral aneurysm formation among patients with ICA agenesis and carotid-anterior cerebral artery (ACA) anastomosis may be due to the increased hemodynamic burden on the normal side and anastomosis, respectively. It is important to be familiar with an uncommon anatomical variation with ICA agenesis and carotid-ACA anastomosis to determine appropriate treatment strategies or monitor the growth of aneurysms. Herein, we report a case of unilateral ICA agenesis with interparaclinoid and contralateral carotid-ACA anastomoses.
Case report
A 65-year-old female with a long history of depressive episodes underwent MR imaging including MR angiography at National Hospital Organization Kyushu Medical Center. One month before this admission, she had noticed a gradual worsening of gait disturbance and difficulty moving her left arm. Routine laboratory testing showed all results within normal limits, except for slightly elevated serum levels of total cholesterol (264 mg/dL; reference range, 128–211 mg/dL) and C-reactive protein (0.72 mg/dL; reference range, 0–0.3 mg/dL). MR imaging was performed using a 3.0-T MR scanner (Ingenia; Philips Medical Systems, Best, the Netherlands) to rule out vascular Parkinsonism, although drug-induced Parkinsonism was suspected from her medical history. Scanning parameters for 3-dimensional time-of-flight MR angiography were: repetition time, 23.0 ms; echo time, 3.45 ms; flip angle, 18°; slice thickness, 1.0 mm; slice interval, 0.5 mm; matrix size, 364 × 267; field of view, 200 × 200 mm; number of excitations, 1. The proximal left internal carotid artery (ICA) was not visible on MR angiography (Fig. 1A–C), and an anterior communicating artery (ACoA) aneurysm 2 mm in diameter was identified. The left middle cerebral artery was supplied from the right ICA via an interparaclinoid anastomosis. This interparaclinoid anastomosis showed no communication with the basilar, posterior communicating, or posterior cerebral arteries. A communicating artery connecting the interparaclinoid anastomosis and anterior cerebral artery (ACA) branched off from the presumed transition point between the interparaclinoid anastomosis and left ICA. Both right and left ophthalmic arteries (OAs) originated from the clinoid segment of the ICA (Fig. 1C). The communicating artery connecting the interparaclinoid anastomosis and ACA arose proximal to the left OA, and the communicating artery was identified as the carotid-ACA anastomosis. Imaging follow-up was selected based on the small size of the ACoA aneurysm. Her symptoms have remained stable since the first visit to our hospital.
Discussion
Unilateral agenesis of the ICA is a rare anatomical variant [2, 5, 8, 9]. The absence of one or both ICAs may be entirely asymptomatic under normal conditions, due to the presence of collateral vessels [7]. The primitive ICA originates from the dorsal aorta and the third aortic arch at the 4- to 5-mm embryonic stage [3], and is completely formed by about gestational week 6 [3, 7]. Agenesis of the ICA is therefore most likely to result from atresia or involution of the third aortic arches and the distal portion of the dorsal aorta in this period. The carotid canal develops in association with the ICA. Thus, if the embryonic primordium of the ICA fails to develop before embryonic week 3–5, the ICA and the carotid canal cannot develop [7]. ICA agenesis has been classified into six types (A–F) by Lie [5]. Among these, Lie’s type D represents intercavernous or trans-sellar anastomosis [6, 9]. The interparaclinoid anastomosis in the present case resembles but differs from anatomical variants reported by Uchino et al. [9] or the Lie’s type D. Compared with the case reported by Uchino et al. [9], neither the right ICA nor the interparaclinoid anastomosis showed any communication with the basilar, posterior communicating, or posterior cerebral arteries. In addition, the interparaclinoid anastomosis in our case was well developed. Schematic illustrations indicate the difference between Lie’s type D (Fig. 1D) and our case (Fig. 1E). According to a proposal by Lasjaunias, the ICA constitutes seven segments: cervical, ascending intrapetrous, horizontal intrapetrous, ascending foramen lacerum, horizontal intra-cavernous, clinoid, and termination [4]. Each segment is located between embryonic arteries [4]. The present patient showed an interparaclinoid anastomosis that would originate more distally from the ICA than the Lie’s type D. The anatomical variant, in this case, should be distinguished from any previously reported types from Lie’s classification.
We also observed the communicating artery connecting the interparaclinoid anastomosis and ACA originating from a presumed transition point between the interparaclinoid anastomosis and the left ICA. The communicating artery in the patient was determined as carotid-ACA anastomosis. We believe carotid-ACA anastomosis is a more appropriate term than the infraoptic course of the ACA because some subjects with carotid-ACA anastomosis show a normally positioned A1 segment of the ACA [10]. The left OA in our case arose from the left ICA distal to the communicating artery. According to the hypothesis of Lasjaunias, each segment of the ICA is located between embryonic arteries and can thus potentially cause communicating arteries [4]. The carotid-ACA anastomosis in this case thus probably branched off from the junction of the cavernous-clinoid segment.
An association between ICA agenesis and ACoA aneurysm has been reported [1, 7]. The carotid-ACA anastomosis is another risk factor underlying aneurysmal formation [10]. The increased incidence of cerebral aneurysm formation among patients with ICA agenesis and carotid-ACA anastomosis may be due to the increased hemodynamic burden on the normal side and anastomosis, respectively. Increased regional blood flow along with congenital defects of the vessel wall and systemic hypertension are important factors in the development of intracranial aneurysms [7]. We will therefore continue careful and regular monitoring of this patient.
Conclusion
We identified a case of unilateral ICA agenesis with interparaclinoid and contralateral carotid-ACA anastomoses. Neuroradiologists, physicians, and neurosurgeons need to be aware of this anatomical variant, which should be distinguished from any previously reported variations.
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Yamashita, K., Yasaka, M., Uchino, A. et al. Unilateral agenesis of internal carotid artery with interparaclinoid and contralateral carotid-anterior cerebral artery anastomoses diagnosed by magnetic resonance angiography: a case report. Surg Radiol Anat 44, 289–292 (2022). https://doi.org/10.1007/s00276-021-02844-0
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DOI: https://doi.org/10.1007/s00276-021-02844-0