Amputations
Auto Accident Injury
Amusement Park Injury
Asbestos Injury
Back & Neck Injury
Benzene Injury
Beryllium Injury
Bextra Injury
Bicycle Accident Injury
Birth Injury
Boating Accident Injury
Brain Damage
Burn Accident
Bus Accident Injury
Celebrex Injury
Construction Zone Injury
Defective Air Bags
Defective Child Restraints
Defective Road Accidents
Defective Seat Belts
Defective Tire Accidents
Dental Malpractice
Diving Injury
Dog Bite Injury
Drunk Driving
Dram Shop and Liquor Liability
Drug Recall
Electrocutions
Gas Tank Explosions
Gross Negligence
Ground Water Contamination
Guidant Heart Defibrillator
Helicopter Crash Injury
Industrial Accident
Manganese Injury
Maritime Accident
Medical Malpractice
Mesothelioma Injury
Motorcycle Accident Injury
Nursing Home Negligence
Ortho Evra Patch
Paralysis
Paraplegia
Pedestrian Accident Injury
Railroad Accident Injury
Pharmaceutical Liability
School Bus Accident Injury
Silicosis Injury
Slip & Fall Injury
Spinal Cord Injury - Quadriplegic
SUV Rollover Accident
Jeep Rollover Accident
Tainted Human Tissue
Toxic Mold
Truck Accident Injury
18 Wheeler Accident
Whiplash Injury
Workplace Accident
Workers Compensation
Wrongful Death

Biomechanics of Traumatic Brain Injury

Traumatic brain injury or a closed head injury can occur when the head is subjected to a direct external impact. Likewise, injury can occur when the head is subjected to a sudden acceleration and then is suddenly stopped. A sudden acceleration/deceleration often follows a violent flexion - extension movement of the head. This response is extremely common in rear-end vehicle collisions.

Condensed to its most simplistic, there are three major mechanisms which contribute to traumatic brain injury.

These include: (a) impact of the brain against the skull; (b) shear between layers of the brain; and (c) cavitation.

(a) Brain v. Skull. Depending upon how the impact occurred, be it a rear-end collision or other source, the head starts its movement to the rear while the brain resists, thereby leaving a space at the back of the skull. As this force progresses, a centrifugal force lifts the brain thereby leaving spaces between it. Both inertia and centrifugal force causes the brain to impact against the skull. This impact may cause damage to the brain.

While the skull provides considerable external protection because of its strength, its inner-contours are not smooth and are characterized by sharp, bony proturbences. When a blow is dealt to the head, the brain is flung against these bony proturbences and is bruised and torn, resulting in brain damage.

(b) Shear - Diffuse Axonal Shearing. Another mechanism of brain injury is that of shear. Shear is based on rotational acceleration/deceleration, and a sliding effect of one layer of the brain upon another. Shear occurs within the brain because of the difference of density in layers.

Axonal shearing can occur where an axon transverses between two or more layers of the brain which are subject to shearing forces. Often times, damage to the axons is diffuse and degeneration happens throughout the brain rather than in specific clusters. Diffuse axonal shearing is a common cause of "mild" traumatic brain injury, and is rarely visible upon imaging.

(c) Cavitation.   Cavitation occurs when mass moves rapidly through fluid. The pressure in front of the mass is high and the pressure behind the mass is low. Vapor filled bubbles form in low pressure. When a mass returns in the opposite direction, the bubbles collapse. If this occurs often, the brain can be injured.

Many times, injuries are found opposite the point of impact. This type of injury is called the "countre-coup", a French term meaning "against the blow". Cavitation is the most commonly accepted explanation for this type of injury.

Work-up of the biomechanics of injury is especially required in the proper trial presentation of any traumatic brain injury case.