Controlled Cortical Impact Model for Traumatic Brain Injury
Summary
Traumatic brain injuries (TBIs) remain a serious health problem. Using the controlled cortical impact surgery model, research on the effects of TBI and possible treatment methods may be performed.
Abstract
Every year over a million Americans suffer a traumatic brain injury (TBI). Combined with the incidence of TBIs worldwide, the physical, emotional, social, and economical effects are staggering. Therefore, further research into the effects of TBI and effective treatments is necessary. The controlled cortical impact (CCI) model induces traumatic brain injuries ranging from mild to severe. This method uses a rigid impactor to deliver mechanical energy to an intact dura exposed following a craniectomy. Impact is made under precise parameters at a set velocity to achieve a pre-determined deformation depth. Although other TBI models, such as weight drop and fluid percussion, exist, CCI is more accurate, easier to control, and most importantly, produces traumatic brain injuries similar to those seen in humans. However, no TBI model is currently able to reproduce pathological changes identical to those seen in human patients. The CCI model allows investigation into the short-term and long-term effects of TBI, such as neuronal death, memory deficits, and cerebral edema, as well as potential therapeutic treatments for TBI.
Introduction
Traumatic brain injury (TBI) is defined as an alteration in brain function, or other evidence of brain pathology, caused by an external force1. TBIs remain a serious health problem throughout the world, particularly in the United States. According to the Centers for Disease Control and Prevention, at least 1.7 million TBIs occur annually in the United States resulting in 30.5% of all injury-related deaths. In 2000, the direct medical costs and indirect costs of TBIs totaled an estimated $76.5 billion in the United States alone. Although technological and therapeutic advancements in preceding decades have improved the quality and length of life for those suffering from TBIs, no effective pharmaceutical or preventative treatments currently exist. Due to the complexity and wide-reaching effects of TBIs, including tissue lesions, cell death, and axon degeneration, no two injuries are identical; thus, no current TBI model for animals accurately reproduces all aspects of TBI as seen in humans. However, animal models do provide the ability to produce nearly identical injuries necessary to investigate various effects of TBI with the hope of further understanding the clinical manifestations of TBIs.
The controlled cortical impact (CCI) model uses an impact system to deliver physical impact to the exposed dura of an animal. It induces TBIs ranging from mild to severe similar to those experienced by humans. This injury was first characterized in the ferret2 and was later adapted for use in the rat3,4, mouse5-7, and sheep8. Since the first characterization, the site of injury has been placed both over the midline2,9 and the lateral cortex10. CCI provides an easy and accurate method of investigating the effects and potential treatments for TBIs.
In addition to the CCI model, the fluid percussion and weight drop models are commonly used to produce TBIs. However, these models present limitations, including less control over injury parameters, producing histopathalogical changes not seen in human TBIs, and greater incidence of accidental death in mice3,5,10. The blast wave model is also used to produce TBIs. Although the blast wave model does not reproduce the histopathalogical changes seen following a mechanical impact, this model does accurately produce TBIs experienced particularly by military personnel11. The controlled cortical impact model is easy to control due to the precise control over deformation parameters such as time, velocity, and depth of impact5. Such accuracy makes replicating nearly identical injuries across an entire group of animals more feasible. Most importantly, CCI reproduces TBIs with features seen in human TBIs12. However, there is no single animal model that is entirely successful in reproducing the complete spectrum of pathological changes observed after TBI. Further research is necessary to fully reveal the acute and chronic changes that occur after TBI.
Two types of injuries occur following a TBI: primary and secondary injuries. The primary injury occurs at the moment of impact and is not sensitive to therapeutic treatments; however, the secondary injuries that persist after the initial injury are subject to treatments13. The controlled cortical impact model produces the primary injury, thus allowing researchers to investigate the effects of TBI and potential therapeutic treatments for the potentially long-lasting effects of secondary injuries. Areas of potential research using the CCI model include neuronal death, cerebral edema, neurogenesis, vascular effects, histopathalogical changes, and memory deficits and more3,13-16.
Protocol
Representative Results
Discussion
The most critical steps for successfully generating consistent TBIs using an electronic magnet impact system to cause a CCI are: 1) stably fixing the mouse head in the stereotactic frame; 2) generating the same size of bone window between mice and removing the bone without damaging the dura under it during craniectomy; 3) correctly positioning the impact tip in the center of the open area and establishing the zero point before impacting.
A mouse head must be fixed in the stereotactic frame ver…
Divulgations
The authors have nothing to disclose.
Acknowledgements
This work was supported by funding from the Indiana Spinal Cord & Brain Injury Research Grants (SCBI 200-12), the Ralph W. and Grace M. Showalter Research Award, Indiana University Biological Research Grant, NIH grants RR025761 and 1R21NS072631-01A.
Materials
| Povidone-iodine 7.5% | Purdue product L.P. | Surgical scrub | |
| Cotton tipped applicators | Henry Schein | 100-6015 | Remove blood and debris |
| scissor | Fine Science Tools | 14084-08 | Surgery |
| forcept | Fine Science Tools | 11293-00 | Surgery |
| hemostat | Fine Science Tools | 13021-12 | Surgery |
| Rechargeable Cordless Micro Drill | Stoelting | 58610 | Combine with Burrs for generating the bone window |
| Burrs for Micro Drill | Fine Science Tools | 19007-05 | |
| Suture monofilament | Ethicon | G697 | Suture |
| tert-Amyl alcohol | Sigma | 152463-250ML | Making 2.5% Avertin |
| 2,2,2-Tribromoethanol | Sigma | T48402-25G | Making 2.5% Avertin |
References
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