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Frontal crashes (11-1 o'clock) were reviewed from the National Accident Severity Study file (NASS) for years 1980-87. Adult drivers and front right passengers, with lower extremity injuries of the pelvis, thigh, knee, leg or ankle/foot were reviewed. Analysis of age differences, injury contacts, and effectiveness of the 3-point restraint system were studied. Unrestrained drivers have a higher frequency of knee injuries than passengers, fewer leg injuries than passengers and both have the same frequency of ankle/foot injuries. Older unbelted drivers have more injuries to the pelvis, leg, and ankle/foot region than do young drivers. Passengers have more leg injuries. The instrument panel is the major contact for most of the lower extremity injuries. Lap/shoulder belts significantly reduce lower extremity injury frequency.

From a review of 722 “airbag” crashes investigated by UMTRI personnel, there were 117 front seat passengers exposed to passenger side airbag deployments. The majority of these were 16 years of age or older (90 of the 117), with 20 passengers. 11 years of age or younger. Two cases, both fatalities, will not be described, for these crashes have been investigated also by NHTSA's Special Crash Investigation Program personnel. The crashes and injuries of these 18 passengers are described. In this group there were 13 children who had MAIS-1 level injuries and two sustained an MAIS-2 injury. One child was without injury, and two had MAIS-5 level injuries. The description of the crash and of the major injuries sustained are detailed in each of the case capsule descriptions. Most of the children were properly restrained.

This paper presents an analysis of the NASS file (1980 - 1986). Cases were selected for near side impacts for drivers, i.e. left side of car, involving unrestrained adult drivers who were alone in the car, and who were not involved in any other collisions following the primary left side impact. Data analysis indicates that 11 % of the near side drivers had crush damage to only the passenger compartment, the ‘P’ zone, that the head, chest and abdomen predominate as the body areas of concern (AIS 3+ injuries), but that these injuries are sustained more often on structures other than the side interior.

The effects of child safety seats have been well documented in the medical literature. Scattered throughout the medical literature are individual case reports of cervical injury to children restrained in child restraint systems. A review of the literature is provided identifying previous documented cases. The authors also provide new case details of children with cervical spine injury without head contact. An overview of the growth of the infant and specific details in the cervical spine that may contribute to significant cervical injury without head impact is presented.

Crash injury reduction via lap-shoulder belt use has been well documented. As any interior car component, lap-shoulder belts may be related to injury in certain crashes. Relatively unknown is the fact that cervical fractures or fracture-dislocations to restrained front seat occupants where, in the crash, no head contact was evidenced by both medical records and car inspection. An extensive review of the available world's literature on car crash injuries revealed more than 100 such cases. A review of the NASS 80-88 was also conducted, revealing more examples. Cases from the author's own files are also detailed.

NASS 80-88 passenger side impacts data were analyzed. Location of primary car damage using the CDC classification, the AIS for injury severity studies, and the interior contacts of the various body areas. Drivers alone, or with passengers were studied separately in both left and right side crashes. Direct impacts to the passenger compartment only are less frequent than to other CDC side zones. Driver interior contacts vary by body region but also by side impacted in the crash. The presence of an unrestrained front passenger appears to enhance driver injury level in left side crashes but the presence of a passenger, in right side crashes appears to moderate driver injury severity.

At the University of Michigan Transportation Research Institute (UMTRI), 763 crashes involving steering wheel airbag deployments have been investigated in detail (as of 12/1/97). A subset of only frontal crashes, in which the steering wheel airbag deployed, and stature was known, was formed (636 drivers). In these crashes there were 201 “short” stature drivers, 165 cm or less in height (32% of all drivers). The vast majority of all drivers were lap-shoulder belted. Of these drivers, 69% sustained no injuries or an AIS-1 level injury. Of the shorter drivers there were 40 MAIS-2 level injuries and 15 who survived with an MAIS injury level of 3, 4, or 5. These higher level injuries were usually found in only one body area. Details of the injury locations and contacts are presented. Data on the taller drivers (435) were similarly tabulated. Of the taller drivers (> 168 cm), 74% had a MAIS-0 or 1 level injury.

From the authors' files, case examples of thoracolumbar injuries sustained by lap-shoulder belted front seat occupants, in frontal crashes, are presented. Additional cases were found in a review of the clinical literature. The biomechanical literature was reviewed, identifying laboratory studies on thoracolumbar spinal injuries. Suggested mechanisms in the production of these injuries in frontal type car crashes are postulated.

The “seat belt syndrome”, first described in 1961, identified abdominal organ injuries related to the use of the lap belt. Many articles have further documented detailed descriptions of intraabdominal lap belt related trauma. Lumbar spine distractions were later added to this injury list. Lap belt injury literature not infrequently hypothecates that some, if not all, of these seat belt syndrome injuries would be prevented, eliminated, or at least significantly reduced in frequency by the use of lap-shoulder belts. This report, based on data from crash investigations, documents lap-shoulder belt intraabdominal injuries occurring by belt loading alone, without significant intrusion and without significant dynamic flexing of the torso of the restrained front seat occupant.

This is an overview of air bag injuries, a review of the literature and descriptions of air bag related injuries to the various body areas. Some unusual injuries are also included. The cases presented are from the author's files and one from the Special Studies Division of NHTSA.

Using the CDC (SAE J224), a comparison of the NASS data and the UMTRI field accident files (UM series) indicates a similar distribution of offset frontal crashes. Offset frontal damage occurs in 56-61% of crashes, often involving more than one third of the front of the car. Lap-shoulder belted drivers sustain more AIS 2 or greater injuries when there is interior intrusion and occur more often when the offset damage is in front of the driver. However, this may well be due to the severity of the crash. European studies have no uniformity as to offset frontal collision descriptors are difficult to interpret, or to compare one to another.

In a review of 540 crashes in which the steering-wheel airbag deployed, 38% of the drivers sustained some level of upper extremity injury. The majority of these were AIS-1 injuries including abrasions, contusions and small lacerations. In 18 crashes the drivers sustained AIS-2 or-3 level upper extremity injuries, including fractures of the radius and/or ulna, or of the metacarpal bones, all related to airbag deployments. It was determined that six drivers sustained the fracture(s) directly from the deploying airbag or the airbag module cover. The remaining 12 drivers had fractures from the extremity being flung into interior vehicle structures, usually the instrument panel. Most drivers were taller than 170 cm and, of the 18 drivers, 10 were males.

Data from 101 front seat automobile occupant fatality crashes that the authors had investigated were reviewed along with 70 front seat automobile occupants who had the more severe (AIS 3, 4, or 5) level injuries who did not die. The effectiveness of the lap belt alone, lap-shoulder belt, air bag alone, air bag with lap belt, and the passive shoulder belt were made. The estimates reveal that none of the restraints would have prevented 42 to 51 of the fatalities. The air bag with lap belt, and the lap-shoulder belt system, have the highest effectiveness for reducing fatalities (AB+LB, 34%; LB+SH, 32%). The air bag with lap belt has an effectiveness of 68% in reducing the more serious injuries with the lap-shoulder belt nearly as equal (64%). NHTSA's fatality reduction estimates are excessively high and overly optomistic compared to ours, but theirs are noticeably lower for serious injury reduction than are ours. Comparisons with other restraint effectiveness studies are also made.

This paper reviews some clinical case studies taken from field investigations conducted by the authors of actual crashes involving light trucks and vans. An attempt is made to indicate where Federal Motor Vehicle Safety Standards might possibly be applicable and to compare cases where vehicle design changes apparently reduced the severity of injuries. In particular, cases are shown where occupants were restrained and where steering column energy absorbing and rearward displacement systems have been installed.

On-scene investigations of 104 fatal accidents involving 136 fatalities have shown that ejection from the vehicle was the leading cause of the fatalities. The data indicate that the majority of these victims could have survived by the use of the simple lap seat belt. The steering assembly -- the end of the steering column or steering wheel proper -- was the leading cause of the fatalities among drivers. The majority of these driver fatalities could not have been saved even with the seat belt-shoulder harness restraint. Other than death by ejection, the instrument panel was the leading cause of death of the front seat passengers, most of whom could have survived by using seat belts. Impacts to the door caused invasion of the passenger compartment, and most occupants would have died even if restraints had been used. To decrease the number of fatal injuries from automobile accidents, future designs of automobile interiors must include adequate crash attenuation features.

Based upon nine years of experience in conducting in-depth, clinical motor vehicle accident investigations, the conditions and practices that have been found to be essential to the collection of reliable and adequate information are defined. The role of the director and the selection of personnel for the investigation teams and their qualifications, training, and supervision are discussed. The establishment and maintenance of relationships with the civil authorities, and hospitals and para-medical personnel with which the accident investigation teams must work, are explained. Examples from actual experience are presented to demonstrate the usefulness of the authors' accident investigation information in identifying areas where vehicle design improvement is desirable and evidence that corrective action taken by the vehicle manufacturers has proved effective.

Modulation of the occupant's movement within the vehicle by the seat belt reduces the potential for striking certain structures and decreases severity of the injuries. The seat belt also functions to direct the upper torso, especially the head, to specific interior surfaces. Design modifications of these areas are needed to prevent serious facial fractures that have been seen. Lap belted drivers contact the steering wheel rim or instrument panel in front of the wheel in head-on crashes; the front passenger strikes the upper instrument panel. Improper positioning of the lap seat belts produces serious intraabdominal injury, especially in the case of the rear passengers. Seat belt fatality cases were, in general, due to collapse and compromise of the occupant space as typified by the broadside intersection collision.

Investigations of 1967 and 1968 model cars indicate that the injuries sustained by driver impacts to the steering assembly are markedly reduced because of the energy absorbing steering column. Drivers, however, are sustaining facial injuries from impact to the steering wheel rim even in low speed crashes. In more severe head-on collisions, the driver is compressing the energy absorbing column and is striking his face on the upper padded instrument panel in front of the steering wheel. Relatively severe facial fractures are sustained by impacting this portion of the panel.

An analysis of 211 automobiles having the ball-type E.A. device (GM cars - 1972–1980), involved in frontal crashes was made to determine the relationship between driver injury and the steering assembly. The majority of the drivers had MAIS of 0 or 1 (66%). The head was the most frequently injured body region with the lower extremities next in frequency. Of the unrestrained drivers studied, 43% had a thoracic injury, the majority of which were minor. There is no correlation between injury severity and steering rim or spoke deformation, or the amount of E.A. column compression. Specific terminology for certain aspects of the E.A. performance are suggested.