Anatomy, Biomechanics and Regional Interdependence of the Thorax
Top Contributors - Jess Bell, Lucinda hampton, Kim Jackson, Merinda Rodseth, Robin Tacchetti and Olajumoke Ogunleye
Introduction[edit | edit source]
The thorax is an area of the spine that has, historically, been under-explored. It can, however, be a silent contributor to many presentations in clinical practice.[1]
One cross-sectional survey in Denmark looked at the prevalence of spinal pain. It found that in one year:[2]
- 13 percent of respondents had thoracic pain
- 43 percent had low back pain
- 44 percent had neck pain
However, between 36 to 41 percent of individuals who present with neck or back pain will also have thoracic pain (i.e. around 4 in 10 patients).[3] This is, therefore, a region that should not be ignored in physiotherapy practice.[1]
Anatomy[edit | edit source]
There are 136 joints in the thoracic spine and 112 muscle attachments. The orientation of the thoracic joints and ribs limit flexion, extension and lateral flexion, but facilitate rotation.[1]
Range of Motion[edit | edit source]
The total rotation available in the thoracic spine is 85 degrees (+/- 14.8 degrees).[5] It contributes 80 percent of the total range of axial trunk rotation.[6] Each thoracic segment rotates between 6 and 8 degrees. This is significantly more than each lumbar segment, which only has 2 to 3 degrees of rotation.[7]
Thoracic movement is critical for optimal performance in rotational sports and the thoracic spine kinematically links the upper and lower quarters.[8][9] It also contributes 55 percent of the total force during a throw.[10]
Regions of the Thorax[edit | edit source]
- Verebromanubrial:
- Includes: T1 and T2, ribs 1 and 2, the manubrium and clavicle
- Vertebrosternal
- Includes: T3 to T7, true ribs 3 to 7 and sternum
- Vertebrochondral:
- Includes: T8 to T10 and false ribs 8 to 10
- Thoracolumbar
- Includes: T11 and T12, floating ribs 11 and 12[1]
NB: True ribs attach directly to the sternum via cartilage, false ribs attach to the lowest true ribs and floating ribs only have posterior attachments to the spine.
Ribs[edit | edit source]
- Ribs 1, 11 and 12 articulate with the named vertebra (i.e. rib 1 articulates with T1)
- Ribs 2 to 10 articulate with the named vertebra, as well as the body above, the intervertebral disc and the anterior surface of the transverse process of the named vertebra
- More information about the ribs is available here
The Thoracic Ring (T3-T9)[edit | edit source]
'The "thoracic ring” consists of two adjacent vertebrae and the related intervertebral disc, the right and left ribs (attached to the vertebra-disc-vertebra complex at the costovertebral joints), and the anterior attachments to the sternum/manubrium and related cartilages.'[11]
There are 13 articulations per thoracic ring:[1][11]
- Zygapophyseal / facet = 2
- Costovertebral = 4
- Intervertebral = 1
- Costotransverse = 2
- Costochondral = 2
- Sternocostal = 2
Because of the strong anatomical connections between the ribs and the thoracic spine, mobilising a rib laterally will cause motion at the vertebral segments of that thoracic ring, as well as the rib on the opposite side of the body.[1]
Thoracic Function[edit | edit source]
Lee has described the thoracic spine as a “slinky" or a "shock-absorbing spring”.[11] It consists of a dynamic stack of 10 thoracic rings[11] and has the following functions:[7]
- Force transmission
- Central area for myofascial attachments
- Protects heart, lungs, vessels and digestive tract[15]
- Aids optimal respiratory function
- Houses the autonomic nervous system
Thoracic Asymmetry[edit | edit source]
It is normal for there to be thoracic asymmetry of the facet orientation in the thoracic spine.[16] Asymmetrical anatomy may, however, cause changes in the coupled motion at a segment.[17]
Regional Interdependence[edit | edit source]
Regional interdependence occurs when: “seemingly unrelated impairments in remote anatomical regions of the body may contribute to and be associated with a patient’s primary report of symptoms.”[18]
Examples of interdependency in the thoracic spine include the following:[1]
1. Cervical spine[edit | edit source]
Tsang and colleagues found that during all cervical movements, there is associated movement at T1, T6 and T 12. In particular, the upper thorax contributes:[20]
- 25 percent to cervical flexion and extension
- 10 percent to cervical rotation
Thoracic spine changes are, therefore, implicated in a loss of cervical range of motion, so this area should always be assessed in patients with neck dysfunction.[20]
2. Shoulder[edit | edit source]
The scapula is a sesamoid bone, which rests upon the thorax. It is influenced by the position of the thoracic spine elements and the ribs. Positions such as a thoracic kyphosis, a thoracic scoliosis or a flattened / inverted thoracic spine, can change the resting position of the scapula.[1]
- Treating the thoracic spine has been shown to alter shoulder symptoms[21][22] [23]
- Thoracic kyphosis is associated with a loss of glenohumeral range of motion and impingement symptoms[24]
3. Other Relationships[edit | edit source]
- Sympathetic nerve blocks at the thoracic spine can improve chronic upper extremity neuropathic pain[25]
- 70 percent of patients with lateral elbow pain have co-existing thoracic pain (compared to 16 percent of the control group)[26]
Postural and Positional Implications[edit | edit source]
Certain postural dysfunctions could result in compensatory thoracic dysfunction (i.e. ‘gives’):[1]
- Inextensible hamstrings force thoracic 'give' into flexion during stride, lunging and long sitting
- Inextensible hip flexors can cause lordosis and kyphosis
- A leg length discrepancy and asymmetrical load can cause thoracic scoliosis
Poor cervico-thoracic postures such as:[1]
- Forward head position (Figure 1)
- Thoracic kyphosis
- Scoliosis
- Flat / inverted thoracic spine
Can cause:[1]
- Muscle imbalances
- Joint incongruity
- Ligament laxity
- Altered neurodynamics
Thoracic scoliosis:[1]
- Even minor curves cause wedging of the vertebrae and discs[27]
- 80 percent of athletes who experience asymmetrical loading on their trunk and shoulders (e.g. javelin throwers, tennis players) have thoracic scoliosis[28]
- It could, therefore, be proposed that scoliosis provides a mechanical advantage in asymmetrical sports[1]
Summary[edit | edit source]
- Potentially 40 percent of patients presenting for physiotherapy with back or neck pain will have an associated thoracic spine dysfunction which needs to be assessed and managed
- Biomechanics and knowledge of the clinical anatomy of the thorax will help you to better understand the underlying pathogenesis of these conditions
- Thoracic rotation is essential for optimal sports performance and functional activities
- Postural dysfunctions such as tight hamstrings or hip flexors may force compensatory gives in the thoracic spine - it is essential to look for the source of the problem
References[edit | edit source]
- ↑ 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 Bell-Jenje T. The Thorax Simplified - Anatomy, Biomechanics and Regional Interdependence Course. Physioplus, 2021.
- ↑ Leboeuf-Yde C, Nielsen J, Kyvik KO, Fejer R, Hartvigsen J. Pain in the lumbar, thoracic or cervical regions: do age and gender matter? A population-based study of 34,902 Danish twins 20–71 years of age. BMC Musculoskelet Disord. 2009;10(39).
- ↑ Roquelaure Y, Bodin J, Ha C, Le Marec F, Fouquet N, Ramond-Roquin A et al. Incidence and risk factors for thoracic spine pain in the working population: the French Pays de la Loire study. Arthritis Care Res (Hoboken). 2014;66(11):1695-702.
- ↑ Kenhub - Learn Human Anatomy. Thoracic Spine - Definition & Components - Human Anatomy | Kenhub. Available from: https://www.youtube.com/watch?v=3mniZ_zQuRE [last accessed 28/8/2021]
- ↑ Heneghan NR, Hall A, Hollands M, Balanos GM. Stability and intra-tester reliability of an in vivo measurement of thoracic axial rotation using an innovative methodology. Manual Therapy. 2009; 14(4):452-5.
- ↑ Fujii R, Sakaura H, Mukai Y, Hosono N, Ishii T, Iwasaki M et al. Kinematics of the lumbar spine in trunk rotation: in vivo three-dimensional analysis using magnetic resonance imaging. Eur Spine J. 2007;16(11):1867-74.
- ↑ 7.0 7.1 Lee LJ. A closer look at the thorax [Internet. Physical Therapy Web [cited 30 August 2021]. Available from: https://physicaltherapyweb.com/closer-look-thorax-lj-lee/
- ↑ Heneghan NR, Lokhaug SM, Tyros I, Longvastøl S, Rushton A. Clinical reasoning framework for thoracic spine exercise prescription in sport: a systematic review and narrative synthesis. BMJ Open Sport Exerc Med. 2020;6(1):e000713.
- ↑ Heneghan NR. Webb K, Mahoney T, Rushton A. Thoracic spine mobility, an essential link in upper limb kinetic chains in athletes: A systematic review. Transl Sports Med. 2019;2:301-15.
- ↑ Kaczmarek PK, Lubiatowski P, Cisowski P, Grygorowicz M, Łepski M, Długosz J et al. Shoulder problems in overhead sports. Part I - biomechanics of throwing. Pol Orthop Traumatol. 2014;79:50-8.
- ↑ 11.0 11.1 11.2 11.3 Lee LJ. Thoracic ring approach. Available from: https://ljlee.ca/teaching-models/the-thoracic-ring-approach/ (accessed 28 August 2021).
- ↑ McConnell J. Recalcitrant chronic low back and leg pain--a new theory and different approach to management. Man Ther. 2002;7(4):183-92.
- ↑ Mohanty PP, Pattnaik M. Mobilisation of the thoracic spine in the management of spondylolisthesis. J Bodyw Mov Ther. 2016;20(3):598-603.
- ↑ Cleland JA, Childs JD, McRae M, Palmer JA, Stowell T. Immediate effects of thoracic manipulation in patients with neck pain: a randomized clinical trial. Man Ther. 2005;10(2):127-35.
- ↑ Edmondston SJ, Singer KP. Thoracic spine: anatomical and biomechanical considerations for manual therapy. Man Ther. 1997;2(3):132-43.
- ↑ Masharawi Y, Rothschild B, Dar G, Peleg S, Robinson D, Been E et al. Facet orientation in the thoracolumbar spine: three-dimensional anatomic and biomechanical analysis. Spine (Phila Pa 1976). 2004;29(16):1755-63.
- ↑ Andriacchi T, Schultz A, Belytschko T, Galante J. A model for studies of mechanical interactions between the human spine and rib cage. J Biomech. 1974;7(6):497–507.
- ↑ Sueki DG, Cleland JA, Wainner RS. A regional interdependence model of musculoskeletal dysfunction: research, mechanisms, and clinical implications. J Man Manip Ther. 2013;21(2):90-102.
- ↑ FoundationPT. The truth about aches and pains - Regional Interdependence Overview. Available from: https://www.youtube.com/watch?v=v4YXQgamW2Q [last accessed 28/8/2021]
- ↑ 20.0 20.1 Tsang SM, Szeto GP, Lee RY. Normal kinematics of the neck: the interplay between the cervical and thoracic spines. Man Ther. 2013;18(5):431-7.
- ↑ Strunce JB, Walker MJ, Boyles RE, Young BA. The immediate effects of thoracic spine and rib manipulation on subjects with primary complaints of shoulder pain. J Man Manip Ther. 2009;17(4):230-6.
- ↑ Boyles RE, Ritland BM, Miracle BM, Barclay DM, Faul MS, Moore JH et al. The short-term effects of thoracic spine thrust manipulation on patients with shoulder impingement syndrome. Man Ther. 2009;14(4):375-80.
- ↑ Haider R, Bashir MS, Adeel M, Ijaz MJ, Ayub A. Comparison of conservative exercise therapy with and without Maitland Thoracic Manipulative therapy in patients with subacromial pain: Clinical trial. J Pak Med Assoc. 2018 Mar;68(3):381-7.
- ↑ Barrett E, O'Keeffe M, O'Sullivan K, Lewis J, McCreesh K. Is thoracic spine posture associated with shoulder pain, range of motion and function? A systematic review. Man Ther. 2016;26:38-46.
- ↑ Yoo HS, Nahm FS, Lee PB, Lee CJ. Early thoracic sympathetic block improves the treatment effect for upper extremity neuropathic pain. Anesth Analg. 2011;113(3):605-9.
- ↑ Berglund KM, Persson BH, Denison E. Prevalence of pain and dysfunction in the cervical and thoracic spine in persons with and without lateral elbow pain. Man Ther. 2008;13(4):295-9.
- ↑ Stokes IA, Aronsson DD. Disc and vertebral wedging in patients with progressive scoliosis. J Spinal Disord. 2001;14(4):317-22.
- ↑ Swärd L. The thoracolumbar spine in young elite athletes. Current concepts on the effects of physical training. Sports Med. 1992;13(5):357-64.