Abstract
Background
Treating complex middle cerebral artery (MCA) trifurcation aneurysms requires a delicate balance between achieving aneurysm obliteration and preserving vascular integrity. Various cerebral revascularization techniques, including bypass, and clip reconstruction are considered individually or in combination.
Methods
This case report outlines a successful repair of a ruptured neck and base of MCA trifurcation aneurysm using a suturing-clip reconstruction technique. Temporary aneurysm trapping was implemented, with maintained elevated blood pressure to ensure collateral perfusion during repair of ruptured base and neck of MCA aneurysm.
Conclusion
The suturing-clip reconstruction exhibited long-term radiological stability, emerging as a valuable alternative for managing challenging MCA trifurcation aneurysms.
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Relevant surgical anatomy
The MCA, a vital component of the cerebral vasculature, comprises distinct segments including M1, M2, M3, and M4. The conversion of M1 into several branches (M2) creates intricate hemodynamic conditions, potentially contributing to aneurysm formation [5]. The dynamic blood flow and shear forces exerted on the arterial wall in this region may precipitate the development of aneurysms, particularly at the M1-M2 junction [2]. Notably, the vicinity of MCA aneurysms often involves perforators originating from the aneurysm base or near the aneurysm neck on the parent artery. This anatomical complexity, for example, a trifurcation of MCA, adds a layer of intricacy to surgical clipping [3]. In the event of an aneurysm rupture, subarachnoid hemorrhage (SAH) and hematoma formation with a swollen brain further amplify the surgical challenge. Surgical management options, including surgical clipping, endovascular coiling, clip reconstruction, or aneurysm trapping with bypass procedures, aim to isolate the aneurysm from normal circulation. The choice between these interventions is often made after careful consideration of the specific anatomical and clinical features of the MCA aneurysm [4, 6, 7].
Description of the technique
Preoperative assessment
A 49-year-old female patient presented with a sudden and severe headache, and upon admission, she exhibited a GCS of 11 (WFNS Grade IV). Immediate imaging diagnostics, including Computed Tomography (CT) and CT angiography (CTA), revealed a Fischer grade III SAH. Multiple aneurysms were evident on digital subtraction angiography (DSA). The left MCA trifurcation aneurysm was identified as the probable source of the SAH. Due to a seizure and reduced GCS of 8, the patient was intubated and external ventricular drainage (EVD) was placed immediately. Given the complexity of the MCA trifurcation aneurysm, an interdisciplinary decision favored surgical repair (Fig. 1).
Surgical procedure
The patient was positioned supine with the head rotated 60° to the right, elevated above heart level, and secured with a Mayfield holder. A left-sided pterional skin incision and standard pterional craniotomy were performed [9]. Dura was opened in curvilinear fashion. Microscopic dissection along the sphenoid ridge and opening of the optic cistern provided access.
For proximal control, dissection along the internal carotid artery (ICA) revealed the terminal of the ICA and the M1 branch of the MCA. The Sylvian fissure was widely opened to expose the M1 trunk and all M2 branches. Intraoperative, an aneurysm re-rupture occurred. Proximal and distal clipping of all M2 branches isolated the aneurysm, and blood pressure was elevated to improve collateral circulation.
Due to the extent of the ruptured area over the trifurcation base, direct clipping without compromising the parent artery was unfeasible. Consideration was given to M2-M2 side-to-side anastomosis and clip reconstruction. To mitigate the risk of ischemia in case of bypass failure, an interrupted suturing of the ruptured base was performed using 10–0 Nylon sutures. The aneurysm was then clip-reconstructed.
Upon releasing the distal clips, the suture line extending into the trifurcation was monitored. Subsequently, the proximal clip was released, and the patency of M2 vessels and stability of the sutured trifurcation area was ensured and no leakage occurred from the suture site. Doppler examination and indocyanine green (ICG) angiography confirmed optimal blood flow in all M2 branches and the absence of aneurysm perfusion. The sutured site was further secured with Tachosil, a muscle patch, and fibrin glue. Standard closure procedures for the dura, muscle, and scalp were carried out. This comprehensive approach ensured the successful repair of the ruptured MCA trifurcation aneurysm while minimizing the risk of ischemia and achieving excellent vascular and aneurysm perfusion outcomes (video. 1; Fig. 2).
Indications
This report details a successful repair of the ruptured base of an MCA trifurcation aneurysm using a combined suture and clipping technique. The success of the procedure hinges on several key factors, including the early establishment of proximal control, careful maneuvering to ensure a wide opening of the Sylvian fissure while protecting perforators, and achieving thorough aneurysm obliteration while preserving the parent vessel. This approach serves as a viable option, particularly in scenarios with time constraints and the potential for extended ischemia. Moreover, this technique can be applied if the bypass suturing expertise are lacking to rescue such complex situations.
Limitations
-
1.
Surgeon expertise
Skill requirement
The technique demands a high level of surgical skill, particularly deep suturing. Novice surgeons may face challenges in mastering this intricate skill, potentially affecting the procedure’s success.
Anatomical familiarity
In-depth knowledge of complex anatomical structures is essential. Lack of experience may lead to encounter difficulties navigating the intricate vascular anatomy, increasing the risk of complications.
Emotional preparedness
Strong emotional resilience is imperative for managing emergencies during the procedure, emotional preparedness particularly to remain composed in unexpected critical scenarios, potentially impacting decision-making and patient outcomes.
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2.
Equipment Demands
Microscope requirements
The technique relies on a high-resolution microscope, necessitating excellent optics and features like an intraoperative assessment with ICG functionality. Facilities lacking such advanced microscopes may face limitations in implementing the technique effectively.
Microsurgical instruments
The use of specialized microsurgical instruments is essential to perform deep suturing. Availability and accessibility to these instruments may pose a challenge in some settings, restricting the widespread application of the technique.
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3.
Team cooperation
Anesthesia and nursing support
Successful execution of the technique relies on a well-coordinated and cooperative team. Swift responses from anesthetists and nurses are crucial in managing unforeseen scenarios. In environments where teamwork is not optimal, the technique’s feasibility may be compromised, potentially impacting patient safety.
How to avoid complications
To mitigate potential complications, our surgical approach involves a strategic combination of techniques. Temporary clipping, maintained for approximately 25 min along with induced hypertension to 160 mmHg, is employed to safeguard against ischemia, preserving collateral circulation during the procedure [8]. Intraoperative measures include meticulous observation of the anastomosis site and real-time confirmation using ICG to ensure the obliteration of aneurysm perfusion, reducing the risk of leakage. Furthermore, a vigilant long-term follow-up plan is implemented to monitor the vulnerable artery site, minimizing the potential for aneurysm recurrence and enabling timely intervention if required. These multifaceted strategies collectively aim to enhance the safety and success of the surgical procedure while addressing the key complications of ischemia and postoperative bleeding or aneurysm recurrence (Fig. 3).
Specific information for the patients
For patients considering this technique, it is vital to understand that while it effectively eliminates the aneurysm, it does not address the preexisting SAH. The ultimate outcome is significantly influenced by the severity of the SAH. Regular health check-ups, timely detection of intracranial aneurysms, and proactive monitoring to predict the risk of rupture are crucial for overall management [1]. Additionally, patients should be aware that the suture site on the artery wall is a vulnerable area with short-term leakage and long-term recurrence risks. Perioperative monitoring and diligent long-term follow-up are indispensable to ensure early detection and prompt intervention if needed, contributing to the success and safety of the procedure over time.
Data availability
All data and materials used in this study are available upon reasonable request. Please contact Sajjad Muhammad at sajjad.muhammad@med.uni-duesseldorf.de for any inquiries regarding the availability of data and materials.
Code availability
Not applicable.
Abbreviations
- MCA:
-
Middle cerebral artery
- SAH:
-
Subarachnoid hemorrhage
- GCS:
-
Glasgow Coma Scale
- WFNS:
-
World Federation of Neurological Surgeons
- CT:
-
Computed tomography
- CTA:
-
Computed tomography angiography
- DSA:
-
Digital subtraction angiography
- EVD:
-
Extra ventricular drainage
- ICA:
-
Internal carotid artery
- ICG:
-
Indocyanine green
- MR:
-
Magnetic resonance
- DWI:
-
Diffusion-weighted Imaging
- FLAIR:
-
Fluid-attenuated inversion recovery
- MRA:
-
Magnetic resonance angiography
- SSEP:
-
Somatosensory-evoked potentials
- MEP:
-
Motor-evoked potentials
References
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Funding
Open Access funding enabled and organized by Projekt DEAL. We are thankful to Stiftung Neurochirurgische Forschung (DGNC), EANS Research Funds, Forschungskommission HHU Düsseldorf, James und Elisabeth Cloppenburg, Peek & Cloppenburg Düsseldorf Fund, and BMBF to Sajjad. Muhammad. Rui Zhang is supported by China Scholarship Council (CSC scholarship number: 202108130055) to study at the Medical Faculty and University Hospital Düsseldorf, Heinrich-Heine-University, Dusseldorf, Germany.
Author information
Authors and Affiliations
Contributions
Sajjad Muhammad performed the surgical procedure, confirmed the scientific nature of the method, and guided and reviewed the paper. Rui Zhang collected the data, prepared the images, and wrote and reviewed the manuscript.
Corresponding author
Ethics declarations
Ethics approval
The patient received informed consent for operation and publication of data in framework of our neurovascular research (Studien-Nr.: 2019–787-bio,Medical Faculty and University Hospital Düsseldorf, Heinrich-Heine-Universität Düsseldorf, Germany).
Consent to participate
All participants in this study provided informed consent prior to their involvement. They were made aware of the study’s objectives, procedures, and their rights as participants.
Consent for publication
All authors of this study have reviewed and approved the final manuscript for publication. They consent to the publication of this research in its current form.
Conflict of interest
The authors declare no competing interests.
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Key points
In the context of potential intraoperative aneurysm re-rupture, meticulous preoperative planning is indispensable.
It is advisable to undergo comprehensive training and foster collaboration within a proficient team.
The surgeon must possess the capability to manage unforeseen emergencies adeptly. Especially when the first plan fails, a proper “plan B” is remarkable to guarantee the patient’s safety.
Optimal use of a standard pterional craniotomy is recommended, with an emphasis on enlarged Sylvian fissure exposure for early proximal control of the MCA.
During aneurysm exposure, especially in cases of rupture, manipulation should be executed with gentleness to prevent re-rupture. The use of retractor is not recommended by authors, only for very limited time usage if needed (e.g., deep suturing).
Recognizing the diversity of cases, it is essential to acknowledge that no single strategy for dealing with aneurysm is universally applicable, and the surgeon should tailor their strategy accordingly.
The optimization of ischemic time and controlled elevation of blood pressure is crucial to prevent postoperative ischemia. This treatment should also be adjusted individually based on specific situations.
An interrupted suture technique is recommended. In the event of leakage, additional sutures can be easily applied.
Utilizing Doppler examination and ICG angiography proves valuable in confirming aneurysm perfusion elimination and assessing parent vessel patency. Somatosensory-evoked potentials (SSEP) and motor-evoked potentials (MEP) both help assess the integrity of the nervous system during surgery to prevent iatrogenic damage; we recommend the application of SSEP and MEP.
Due to the vulnerable nature of the suture site, long-term follow-up is crucial for monitoring the recurrence of the aneurysm. A 2-year follow-up in our case was deemed satisfactory.
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Zhang, R., Muhammad, S. Surgical repair of torn base of ruptured middle cerebral artery trifurcation aneurysm. Acta Neurochir 166, 148 (2024). https://doi.org/10.1007/s00701-024-06016-y
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DOI: https://doi.org/10.1007/s00701-024-06016-y