eMedicine Specialties > Sports Medicine > Spine
Lumbosacral Spine Sprain/Strain Injuries
Updated: Nov 21, 2007
Introduction
Background
Low back pain (LBP) is a well-known health concern in the United States. Although the incidence of low back injuries is much less in athletes than in a corresponding population of industrial workers, such injuries are still seen in many athletes. The most common causes of LBP in athletes are musculoligamentous sprains and strains, which occur mainly at the lumbosacral region. This is true of both high-performance, world-class athletes and of "weekend athletes." With over 30 million Americans now involved in organized sports, these back injuries present health concerns on the national level.
(See also the eMedicine articles Mechanical Low Back Pain [in the Physical Medicine and Rehabilitation section], Lumbar Disk Problems in the Athlete [in the Sports Medicine section], and Pathophysiology of Chronic Back Pain [in the Neurology section], as well as Pain Measurement in Patients With Low Back Pain, Guidelines Issued for Management of Low Back Pain, and Epidemiology of Adolescent Spinal Pain: A Systematic Overview of the Research Literature on Medscape.)
For excellent patient education resources, visit eMedicine's Back, Ribs, Neck, and Head Center, Sports Injury Center, and Sprains and Strains Center. Also, see eMedicine's patient education articles Back Pain and Sprains and Strains.
Frequency
United States
Studies document that 7-13% of all sports injuries in intercollegiate athletes are low back injuries. The most common back injuries are muscle strains (60%), followed by disc injuries (7%). Athletes are more likely to sustain injuries in practice (80%) than during competition (6%).1 American football (17%) and gymnastics (11%) are reported to have the highest rates of low back injury.1
International
Exact numbers regarding the international frequency of low back injuries are not known, however, a recent French study reported over 50% of French individuals aged 30-64 years had experienced at least 1 day of LBP over the previous 12 months, and 17% had suffered LBP for more than 30 days in the same 12-month period.2 The authors noted that the prevalence of LBP varied between men and women, that there was an increased incidence with increasing age for LBP that lasted more than 30 days, and that these data were similar to those of other countries.
In an African study, the mean LBP point prevalence among adults was 32%, with an average 1-year prevalence of 50% and an average life-time prevalence of 62%.3
Functional Anatomy
Sprains are ligamentous injuries that are caused by a sudden violent contraction, sudden torsion, severe direct blows, or a forceful straightening from a crouched position. All major ligaments (ie, anterior longitudinal, posterior longitudinal, yellow, intertransversal, capsular, interspinosus, supraspinosus) can sustain sprains; however, the posterior ligaments are more prone to injury. The posterior longitudinal ligament, for example, is the biggest of this group of ligaments and is less developed than its anterior counterpart.
Strains are defined as tears, either partial or complete, of the muscle-tendon unit. Muscle strains and tears most frequently result from a violent muscular contraction during an excessively forceful muscular stretch. Any posterior spinal muscle and its associated tendon can be involved, although the most susceptible muscles are those that span several joints.
Combined with injured tendons and ligaments, all embedded structures may be temporarily or permanently damaged. Of major interest are proprioceptors that play a crucial role in the motor control of the spine. An inhibited motor control weakens spinal stability and may lead to chronic back problems or reinjury.
Sport-Specific Biomechanics
The lumbar spine bears tremendous loads: the large, superimposed body weight interacts with additional forces that are generated by lifting as well as other activities that involve powerful forces.4, 5, 6 The lumbar spine and the hips are responsible for the mobility of the trunk. The L4-5 and L5-S1 areas bear the highest loads and tend to undergo the most motion. Consequently, these areas are found to sustain the most spinal strain or sprain injuries. In addition, load-bearing strain and sprain injuries most frequently occur during the strongest coupling patterns (ie, lateral bending with flexion-extension, axial rotation with lateral bending).
The bony architecture and the ligamentous elements constitute the structural components of the spine.7 The muscles and tendons constitute the dynamic elements. With all elements intact, the biomechanical function of the spine is normal. The intrinsic translatory and rotatory stability of the spine is provided by the ligaments. The contribution of a given ligament depends not only upon its particular strength, but also upon its location. Moreover, a ligament may contribute relatively more to either the translatory or rotatory stability, depending upon the loading circumstances. Assuming that all ligaments are made of the same material, the strength of a ligament is proportional to its cross-sectional area. A ligament with a larger cross-sectional area provides greater stability and less displacement when the functional spinal unit (FSU) is subject to physiologic loads.
Another factor that contributes to spinal stability is the distance of a ligament from the center of rotation.8 A ligament that is located close to the center of rotation provides much less stability against bending than a ligament that is further away from the rotation center. The interspinous ligaments in the adult lumbar spine are frequently absent, ruptured, or degenerated and do not contribute to stability of the spine. However, supraspinous ligaments do play a role in stabilizing the spine. Muscles provide stability to the spine during all dynamic movements and actions. Injured trunk muscles can decrease spinal stability if the intact muscles are not able to compensate for the dysfunction of the injured unit.
Spinal instability can occur as a result of trauma, disease, surgery, or some combination of the 3 causes. Clinical instability is defined as a loss of the ability of the spine to maintain relationships between vertebrae under physiologic loads in such a way that (1) there is neither initial nor subsequent damage to the spinal cord or nerve roots, and (2) there is no development of incapacitating deformity or severe pain. Instability leads to abnormal kinetics (stiffness) and/or kinematics (coupling patterns).
When the tissues surrounding the spine are damaged, structures embedded within those tissues may also become temporarily or permanently harmed. Proprioceptors, including muscle spindles, Golgi tendon organs, and joint receptors, are of great importance for postural control. Damaged proprioceptors weaken the stability of the spine and may lead to reinjuries or chronic problems. Although some studies document changes in the normal quality and quantity of motion, there has been no compelling correlation of either with pain behavior.
Clinical
History
- Obtain the following key information:
- The mechanism of injury, with an exact description of the event leading to the pain
- The exact localization and duration of the pain
- Any pain radiation
- Movements that aggravate or minimize the pain
- Typical symptoms are pain and spasm that are localized over the posterior lumbar spinal muscle bellies lateral to the spinous process or at the insertion of the muscle at the iliac crest.
- If the injury is confined to a sprain or strain injury, then structural deformities, a generalized midback pain indicating disc involvement, and neurologic symptoms should be absent. (See also the eMedicine articles Lumbar Disk Problems in the Athlete [in the Sports Medicine section], Lumbar (Intervertebral) Disk Disorders [in the Emergency Medicine section], Lumbar Degenerative Disk Disease [in the Physical Medicine and Rehabilitation section], and Lumbar Disc Disease [in the Neurosurgery section].)
- Range of motion (ROM), particularly in flexion, is usually painful and decreased.
- Any neurologic compromise, (eg, numbness in the lower extremity, motor weakness) or any urinary or fecal incontinence syndrome indicates the possible presence of disc prolapse, nerve root impingement, or spinal canal stenosis. (See also the eMedicine articles Urinary Incontinence [in the Emergency Medicine section], Fecal Incontinence [in the Obstetrics/Gynecology section], Nerve Entrapment Syndromes of the Lower Extremity [in the Orthopedic Surgery section], Spinal Stenosis [in the Neurosurgery section], and Spinal Stenosis and Neurogenic Claudication [in the Physical Medicine and Rehabilitation section].)
Physical
- With the patient in a standing position, evaluate for obvious deformities, changes in alignment, or difficulties in achieving changes in position or full ROM. Evaluation of these signs may provide clues to muscle spasm(s) and activities that worsen the patient's pain.
- Palpation of painful area: Palpation, performed with the patient in a prone position, helps to reveal the area and the size of muscle spasm(s) and the location of any point tenderness, if present. A point-specific midline back pain between the spinous processes indicates a ligamentous injury or lumbar interspinous bursitis ("kissing spines").
- Neurologic examination: Evaluation of the lower extremities should include a motor examination, a sensory evaluation, and reflex testing at the knees and ankles. The straight-leg raising test helps to evaluate disc involvement, sciatica, or a neurologic deficit. A positive Patrick test points to a sacroiliac joint inflammation, but this test should be negative in lumbosacral sprains and strains. (See also the eMedicine article Sacroiliac Joint Injury.)
Causes
Most athletes who sustain a low back injury do so while lifting weights during their training sessions or while performing unexpected coupled motions (eg, lateral bending and flexion, lateral bending and axial rotation). During such activities, tremendous loads are placed on the lumbar spine, which may cause a temporary instability and lead to a subsequent injury to the soft tissue that surrounds the spine.
Risk factors for LBP include the following9, 10:
- Muscular imbalances or weaknesses of the abdominal and posterior spinal muscles may constitute a risk factor to sustain a low back injury.
- Deficits in the afferent or efferent pathways or proprioceptors are known risk factors for spinal soft-tissue injuries.
- Preexisting structural deformities, such as scoliosis, spondylolysis, or spinal fusions, may predispose to a spinal injury. Preexisting injuries make athletes more vulnerable to sustaining a reinjury of the same area. (See also the eMedicine article Scoliosis, Idiopathic and Spondylolysis [in the Radiology section], Lumbosacral Spondylolysis [in the Sports Medicine section], and Lumbar Spondylolysis and Spondylolisthesis [in the Physical Medicine and Rehabilitation section], as well as Effectiveness and Cost-Effectiveness of Three Types of Physiotherapy Used to Reduce Chronic Low Back Pain Disability: A Pragmatic Randomized Trial With Economic Evaluation, Biomechanics of the Posterior Lumbar Articulating Elements, Prevalence of Musculoskeletal Disorders at the NFL Combine - Trends from 1987 to 2000, and Lumbar Spine Injuries in Athletes on Medscape.)
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References
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Further Reading
Keywords
low back injury, low back pain, LBP, lumbosacral soft-tissue injury, lumbar strain, lumbar sprain
