1. Lower Back Pain: Management and Prevention Jon Rowe, Bkin, CEP

2. Objectives Review specific anatomy in relation to the lower back (lumbar spine) Touch on a few spinal injuries and mechanisms of injury How to determine some causes of lower back pain (LBP) Action after identifying cause of LBP Management and Prevention

3. Sources McGill, Stuart; Lower Back Disorders, 2 nd edition McGill, Stuart; Ultimate Back Fitness and Performance, 4 th edition

4. Anatomy of the Lumbar Spine Highly vascular, with the exception of the disk – only they remain avascular Circular vertebral body, filled with cancellous bone Pedicle attaches body to posterior elements “Neural Arch” is composed of laminae and pedicles; transverse processes and spinous process attach to neural arch Neural arch is relatively flexible while body is more rigid

5. Intervertebral Disks Rigid annuli surrounding viscous nucleus Notice cross fibers of annulus rings – allows for greater protective forces under compression in multiple planes

6. Interspinous Ligaments

7. Some Key Musculature Iliocostalis and longissimus both act as thoracolumbar extensors; also posterior shear force protectors, moreso in the lumbar region Thus, they are essential for maintaining a neutral spine Multifidus also act as extensors, but more local to lumbar spine Function can change through thoracic flexion, hip flexion, and lumbar flexion – erectors to shear force protectors

8. Latissimus Dorsi Involved in lumbar extensor moment generation; often acts as a major stabilizer Originates at each lumbar spinous process and inserts on humerus – giving it a very large extensor moment arm Active during pulling and lifting, which has implications for training proper functional motion patterns

9. Abdominal Complex rectus abdominus internal oblique external oblique transverse abdominus responsible for trunk flexion, lateral flexion, rotation, and stabilization

10. “Hoop” Stresses

11. Psoas acts mostly as a hip flexor when the hip is flexed, psoas can also act as a lumbar stabilizer

12. Quadratus Lumborum lumbar stabilizer

13. How does a normal spine function? “[compression]…tolerance of the lumbar spine in an average healthy young man probably approaches 12 to 15kN (2688- 3360 lb)”, LBD, p. 82 Competitive weight lifters have safely exceeded 20kN (4480 lb) The lumbar spine can withstand up to 2000-2800 N of shear force

14. When does injury occur?

15. Tolerance Until Failure “Injury, or failure of a tissue, occurs when the applied load exceeds the failure tolerance (or strength of the tissue)”, LBD, p11.

16. When the tissue fails…

17. Optimal Loading “…very few back injuries…result from a single event”, LBD, p11 Just as most systems of the body, the spine needs appropriate loads to improve capabilities

18. What are some causes of tissue overload? “…jobs characterized by manual handling of materials, sitting in vibrating vehicles, and remaining sedentary are all linked with lower back disorder”, LBD, p 29. Though these risk factors do not necessarily determine LBP/LBD, they are part of a list of surrogate factors: “static work posture; seated work postures; frequent bending and twisting; lifting; pulling and pushing; and vibration (especially seated)”, LBD, p 29.

19. The Spine Itself A purely ligamentous spine buckles under 90 N of compression, about 20 lbs (LBD, p. 114) Since we know the spine can withstand much more compression, this shows how the musculature greatly increases compressive load potential by acting as “guy wires”

20. What are some specific injuries? Bulge/Herniation Compression + flexion, especially full flexion = herniation Add rotation and the disk tends to bulge away from the axis of rotation Spondylolisthesis Full cycling of flexion and extension can fatigue the neural arch (laminae and pedicles) Excessive shear force can cause damage to posterior elements

21. Lower Back Pain vs. Injury Assuming spinal injury is not present, ie: fracture, bulge, spondy, avulsion, neural, etc. Assess each client to see what movement causes the pain or where deficiencies lie

22. After Injury It is necessary to identify the mechanism of injury, ascertain potentially injured tissues (bone, ligament, muscle, etc); and develop the next plan of action There is strong evidence to support that after a lower back injury, muscle activation patters are altered “…stability comes from stiffness, passive stiffness is lost with tissue damage and active stiffness throughout the range of motion is lost with perturbed motor patterns following injury”, LBD, p. 119

23. McGill’s 5 Steps 1.Groove motion patterns, motor patterns, and corrective exercise 2.Build whole-body and joint stability 3.Increase Endurance 4.Build Strength 5.Develop speed, power, agility

24. 1. Grooving Patterns It is important to begin corrections pain free Neutral spine is desired and should never be compromised in this phase Proper motor control is correct muscles engaged for corresponding movement Eg: gluteal amnesia following injury Eliminate the faults in testing movements

25. 2. Spinal Stability “Big Three” 1.Curl-Up 2.Side Bridge 3.Birddog Abdominal bracing vs. hollowing or protruding Fascial raking

26. Why the “Big Three”? Curl up imposes minimal compressive loads to the lumbar spine and allows neutral lordodic curve Side Bridge activates entire abdominal complex, plus lower back stabilizers like QL and lats, while maintaining neutral spine Birddog activates entire set of spinal extensors, though not to MVC, while keeping the spine in neutral Compressive forces reach ~3000N Traditional sit up imposes ~3300N (~730lbs) of compression on lumbar spine; plus add full flexion! “Superman” extension exercise can impose up to 6000N (over 1300lbs) of compression on spine; Roman Chair extension can impose over 4000N (~890lbs), LBD, p. 91

27. 3. Building Endurance Do not take muscles to fatigue failure Complete repetitions while muscles are still strong: McGill advocates reverse pyramid reps/sets Side plank, birddog, chin ups, squats

28. 4. Building Strength This is where you get creative Know what will be required of your client and train them accordingly Be sure to maintain proper progression Never let a regression of technique occur: DO NOT compromise neutral spine! Can introduce labile surfaces: SB, wobble boards, Airex pads, etc.

29. 5. Develop Speed, Power, Agility Once sufficient endurance and strength are achieved, performance skills should be integrated into training regime Olympic Lifting, MB work, sport specific exercises

30. “The motor control system is able to control stability of the joints through coordinated muscle coactivation and to a lesser degree by placing joints in positions that modulate passive stiffness contribution. However, a faulty motor control system can lead to inappropriate magnitudes of muscle force and stiffness, allowing … for a joint to buckle or undergo shear translation”, LBD, p. 119.

31. Be wise… …and be careful