Summary

Handcrafted Silicone Coated Filament for Mice Middle Cerebral Artery Occlusion Models

Published: August 09, 2024
doi:

Summary

This protocol describes a straightforward method for creating coated filaments for the middle cerebral artery occlusion (MCAO) model in mice using silicone, nylon sutures, and syringe needles. This method allows for the production of filaments with a consistent diameter and various silicone wrapping lengths tailored to experimental needs.

Abstract

As the global population ages, ischemic stroke has risen to become the second leading cause of disability and mortality worldwide, placing an immense burden on both society and families. Although treatments such as intravenous thrombolysis and endovascular interventions can substantially improve the outcomes for patients with acute ischemic stroke, only a small percentage of individuals benefit from these therapies. To advance our understanding of the disease and to discover more effective treatments, researchers are continuously developing and refining animal models. Among these, the middle cerebral artery occlusion (MCAO) model stands out as the most commonly used model in cerebrovascular disease research. The filament used in this model is crucial for its development. This protocol outlines a method for creating filaments with consistent diameters and varying lengths of silicone coating. The MCAO model produced using this method in C57 mice has demonstrated high success and consistency, offering a valuable tool for tailored investigations into ischemic cerebrovascular diseases.

Introduction

Stroke is one of the most prevalent causes of mortality and disability worldwide. Ischemic and hemorrhagic strokes are the primary types of cerebrovascular event, with ischemic strokes accounting for approximately 87% of cases1,2,3. Currently, there are two treatment modalities for patients with ischemic stroke: pharmacological therapy with recombinant tissue plasminogen activator (rtPA) and mechanical thrombectomy. However, the narrow therapeutic window and extensive exclusion criteria limit the application of these treatments, benefiting only a minority of patients. This underscores the need for continued efforts to improve ischemic stroke therapies4,5. In vitro models are inadequate for replicating the complex pathophysiological responses following a stroke, making animal models an indispensable component of preclinical stroke research. Human focal cerebral ischemia is most frequently caused by thrombotic or embolic occlusion of the middle cerebral artery (MCA), which makes rodent models designed to simulate MCA occlusion (MCAO) highly relevant6.

The filament-induced MCAO model, the most widely adopted in stroke research, facilitates occlusion at the onset of the middle cerebral artery (MCA) and subsequent reperfusion, leading to extensive infarctions across subcortical and cortical areas of the brain. The advantage of this model lies in its ability to restore blood flow after inducing focal ischemia, thereby paralleling the pathophysiological processes observed in human stroke7. Additionally, the model simulates reperfusion injury, a critical factor in the extent of damage8. However, the MCAO model has limitations, including variability in infarct volume, with the standard deviation potentially reaching up to 64% of the mean value in some studies9. Despite over three decades of use, efforts to enhance the model's reliability are ongoing, yet significant variations in ischemic lesion volume persist across studies and laboratories10,11,12.

This article introduces a self-manufactured filament for inducing models evaluating neurological deficit scores and cerebral infarction areas. It examines the correlation between filament lengths coated with silicone and the success and stability of the MCAO model. This production technique yields filaments with commendable consistency, contributing to the development of a relatively stable MCAO model.

Protocol

All animal procedures adhered to the experimental procedures and standards approved by the Shanxi Provincial People's Hospital Institutional Animal Care and Use Committee (approval number: 2024 Provincial Medical Ethics Committee No. 64). The mice used in this experiment were male C57BL/6 mice, 8-10 weeks old, weighing 24-26 g. Details of the reagents and equipment used are listed in the Table of Materials. 1. Filament preparation Marking the o…

Representative Results

In the creation of the MCAO model, the primary tools used for fabricating the filaments and the finished filaments are shown in Figure 3. Following filament production, the MCAO model is established by inserting the filament through the external carotid artery, with the duration of the operation recorded. Successful modeling is defined by a Longa score of 1-3 4 h post-filament withdrawal. Body weight is monitored daily after the operation. Neurological deficits are evaluated using modified n…

Discussion

This study demonstrates a simple and cost-effective method for fabricating filament, confirming its feasibility in creating an MCAO model. The length of the filament's silicone coat can be adjusted according to experimental needs, offering additional flexibility. The preparation of a 5 mm filament embolus achieved a 100% success rate without any occurrences of subarachnoid hemorrhage (SAH) in mice. In the group using 10 mm filament emboli, there were instances of SAH, while the rest of the mice showed clear infarctio…

Divulgaciones

The authors have nothing to disclose.

Acknowledgements

This work was supported by the Wu Jieping Medical Foundation (320.6750.161290).

Materials

10 mL Syringe Haidike Medical Products Co., Ltd. Instrument for making filaments
2,3,5-Triphenyltetrazolium Chloride (TTC) Sigma-Aldrich G3005 Dye for TTC staining
24-well culture plate Corning  CLS3527 Vessel for TTC staining
26 G syringe needle Haidike Medical Products Co., Ltd. Instrument for making filaments
4% paraformaldehyde Servicebio G1101 Tissue fixation
6-0 nylon suture Haidike Medical Products Co., Ltd. Materials for making filaments
Anesthesia system for isoflurane Rwd Life Science Co., Ltd. R610  Anesthetized animal
Bipolar electrocoagulation generator Yirun Medical Instrument Co., Ltd. ZG300 Equipment for surgery
Constant temperature water bath Spring  Instrument Co., Ltd. HH-M6 TTC staining
Eye ointment Guangzhou Pharmaceutical H44023098 Material for surgery
Heat blanket ZH Biomedical Instrument Co., Ltd. Maintain body temperatur 
Isoflurane Rwd Life Science Co., Ltd. R510-22-10 Anesthetized animal
Meloxicam Boehringer-Ingelheim J20160020 Analgesia for animal
Microsurgical artery clamp Shanghai Jinzhong Surgical Instruments Co., Ltd.  W40130 Instrument for surgery
Microsurgical hemostatic clamp forceps Shanghai Jinzhong Surgical Instruments Co., Ltd.  M-W-0022 Instrument for surgery
Microsurgical instruments set Rwd Life Science Co., Ltd. SP0009-R Equipment for surgery
Mouse thermometer Hubei Dasjiaer Biotechnology FT3400 Intraoperative temperature monitoring
Pentobarbital sodium Sigma-Aldrich P3761 Euthanized animal
Shaver Joyu Electrical Appliances PHC-920 Equipment for surgery
Silicone Sealant Kafuter K-704 Materials for making filaments
Stereomicroscope Rwd Life Science Co., Ltd. 77001S Equipment for surgery
Suture thread with needle (3-0) Shanghai Pudong Jinhuan Medical Products Co., Ltd.  F404SUS302 Equipment for surgery

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Zhang, M., Yuan, Y., Du, R., Wen, C., Lin, S., Zhang, Y., Xiang, Z., Hu, F., Wang, C. Handcrafted Silicone Coated Filament for Mice Middle Cerebral Artery Occlusion Models. J. Vis. Exp. (210), e67002, doi:10.3791/67002 (2024).

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