Sporting Elbow - Clinical Reasoning and Differential Diagnosis: Difference between revisions

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<div class="editorbox"> '''Original Editor '''- [[User:Wanda van Niekerk|Wanda van Niekerk]] based on the course by [https://members.physio-pedia.com/course_tutor/ian-gatt/ Ian Gatt]<br>
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== Introduction ==
== Introduction ==
The elbow is a complex joint and stability is provided by osseous and soft-tissue constraints. The elbow's relative instability makes it vulnerable to injuries, often caused by sports<ref>Zwerus EL, Somford MP, Maissan F, Heisen J, Eygendaal D, Van Den Bekerom MP. Physical examination of the elbow, what is the evidence? A systematic literature review. British journal of sports medicine. 2018 Oct 1;52(19):1253-60.</ref> and these injuries often involve several of the structures associated with the joint.<ref name=":5" /> Apart from the clinical history, clinical reasoning and the physical examination are essential to make a diagnosis.


== Anatomy of the Elbow ==
== Anatomy of the Elbow ==
The elbow joint is where the distal humerus meets the proximal radius and ulna bones. It is known as a trochleogingylomoid joint as it can flex and extend as a hinge (ginglymoid) joint as well as pivot around an axis (trochoid motion) known as pronation and supination. It is an extremely congruent and stable joint.<ref>Bryce CD, Armstrong AD. Anatomy and biomechanics of the elbow. Orthopedic Clinics of North America. 2008 Apr 1;39(2):141-54.</ref><ref>Cavallo M, Rotini R, Cutti AG, Parel I. Functional Anatomy and Biomechanic Models of the Elbow. In The Elbow 2018 (pp. 29-40). Springer, Cham.</ref> The stability of the elbow is provided by the osseus anatomy, capsuloligamentous structure and the musculotendinous units that cross the elbow.<ref>Vicenzino w, Scott A, Bell S, Popovic N. Elbow and arm pain. In: Brukner P, Clarsen B, Cook J, Cools A, Crossley K, Hutchinson M, McCrory P, Bahr R, Khan K. eds. Brukner & Khan’s Clinical Sports Medicine: Injuries, Volume 1, 5e.Sydney: McGraw Hill, 2017.</ref>
The distal humerus meets the proximal radius and ulna bones to form the elbow joint. It is known as a trochleogingylomoid joint as it can flex and extend as a hinge (ginglymoid) joint, as well as pivot around an axis (trochoid motion) (i.e. pronation and supination). It is an extremely congruent and stable joint.<ref>Bryce CD, Armstrong AD. Anatomy and biomechanics of the elbow. Orthopedic Clinics of North America. 2008 Apr 1;39(2):141-54.</ref><ref>Cavallo M, Rotini R, Cutti AG, Parel I. Functional Anatomy and Biomechanic Models of the Elbow. In The Elbow 2018 (pp. 29-40). Springer, Cham.</ref> The stability of the elbow is provided by the osseous anatomy, capsuloligamentous structure and the musculotendinous units that cross the elbow.<ref name=":6">Vicenzino w, Scott A, Bell S, Popovic N. Elbow and arm pain. In: Brukner P, Clarsen B, Cook J, Cools A, Crossley K, Hutchinson M, McCrory P, Bahr R, Khan K. eds. Brukner & Khan’s Clinical Sports Medicine: Injuries, Volume 1, 5e.Sydney: McGraw Hill, 2017.</ref>


=== Joints ===
=== '''Joints''' ===
The humerus, radius and ulna articulate to form the 3 joints that make up the elbow. <ref>Acosta Batlle J, Cerezal L, Lopez Parra MD, Alba B, Resano S, Blazquez Sanchez J. [https://insightsimaging.springeropen.com/articles/10.1186/s13244-019-0725-7/ The elbow: review of anatomy and common collateral ligament complex pathology using MRI]. Insights into imaging. 2019 Dec;10(1):1-25.</ref>
The humerus, radius and ulna articulate to form the three joints that make up the elbow. <ref name=":5">Acosta Batlle J, Cerezal L, Lopez Parra MD, Alba B, Resano S, Blazquez Sanchez J. [https://insightsimaging.springeropen.com/articles/10.1186/s13244-019-0725-7/ The elbow: review of anatomy and common collateral ligament complex pathology using MRI]. Insights into imaging. 2019 Dec;10(1):1-25.</ref> Table 1 provides an anatomical overview of the elbow. For more detailed information on the specific elbow joints, please read: [https://www.physio-pedia.com/Physiotherapy_Management_of_the_Elbow?utm_source=physiopedia&utm_medium=search&utm_campaign=ongoing_internal#The_Complex_Anatomy_of_the_Elbow The Complex Anatomy of the Elbow - Joints]
{| class="wikitable"
{| class="wikitable"
|+Table 1: Anatomical overview of the elbow<ref name=":0">Ward K. The elbow region: anatomy, assessment and injuries. InRoutledge Handbook of Sports Therapy, Injury Assessment and Rehabilitation 2015 Sep 16 (pp. 458-498). Routledge.</ref>
|+Table 1: Anatomical overview of the elbow<ref name=":0">Ward K. The elbow region: anatomy, assessment and injuries. InRoutledge Handbook of Sports Therapy, Injury Assessment and Rehabilitation 2015 Sep 16 (pp. 458-498). Routledge.</ref>
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=== Ligaments and Capsule ===
=== '''Ligaments and Capsule''' ===
#[[Medial Collateral Ligament of the Elbow|Medial Collateral Ligament Complex]]/Ulnar Collateral Ligament
[[File:Elbow Joint.jpg|thumb|Elbow Joint]]
#*Comprises an anterior and posterior bundle and a supporting transverse ligament (ligament of Cooper)
The [[Medial Collateral Ligament of the Elbow|Medial Collateral Ligament Complex]] (MCLC) / Ulnar Collateral Ligament is the most important stabiliser of the elbow and it provides valgus and posteromedial stability. It comprises an anterior and posterior bundle and a supporting transverse ligament (ligament of Cooper). The anterior band is more taught in extension and relaxes into flexion, whereas the posterior band tightens in flexion and releases in extension. Thus, the anterior band is more vulnerable to valgus stress in elbow extension and the posterior band of the anterior medial collateral ligament (AMCL) is more vulnerable to valgus stress in elbow flexion.<ref>Smith JR, Amirfeyz R. Clinical Anatomy of the Elbow. InSports Injuries of the Elbow 2021 (pp. 1-13). Springer, Cham.</ref>  
#*Anterior bundle (AMCL):  
 
#**most important stabiliser of the elbow, provides valgus and posteromedial stability
The Lateral Collateral Ligament Complex (LCLC) is the primary stabiliser against varus and external rotation stresses. It is formed by the lateral ulnar collateral ligament, the radial collateral ligament and the [[Annular Ligament|annular]] ligament.
#**anterior bundle divided into anterior and posterior bands:
 
#***anterior band is more taught in extension and relaxes into flexion
The joint capsule surrounds all three joints of the elbow. There is a thickening medially and laterally of the joint capsule that blend with the MCLC and LCLC respectively and this contributes to the stability of the elbow.<ref>Chin K, Hussain S, Mazis G, Arya A. Clinical anatomy and biomechanics of the elbow. Journal of Clinical Orthopaedics and Trauma. 2021 Jun 24:101485.</ref>
#***posterior band tightens in flexion and releases in extension
#***Thus the anterior band is more vulnerable to valgus stress in elbow extension and posterior band of the AMCL is more vulnerable to valgus stress in elbow flexion<ref>Smith JR, Amirfeyz R. Clinical Anatomy of the Elbow. InSports Injuries of the Elbow 2021 (pp. 1-13). Springer, Cham.</ref>  
#Lateral Collateral Ligament Complex (LCLC)
#*Primary stabiliser against varus and external rotation stresses
#*LCLC is formed by the lateral ulnar collateral ligament, the radial collateral ligament and the [[Annular Ligament|annular]] ligament
#**Lateral ulnar collateral ligament is important in maintaining posterolateral rotatory stability as well as stabilising against varus stresses.
#**Radial collateral ligament contributes to posterolateral rotational stability.
#**Annular ligament surrounds radial head, but does not attach to it. It is an important stabiliser of the proximal radioulnar and radiocapitellar joint.
#Joint capsule
#*Surrounds all 3 joints of the elbow
#*Thickening medially and laterally of joint capsule that blend with MCLC and LCLC respectively and contributes to the stability of the elbow (ref)


=== Muscles ===
For more information, please read: [https://www.physio-pedia.com/Physiotherapy_Management_of_the_Elbow?utm_source=physiopedia&utm_medium=search&utm_campaign=ongoing_internal#The_Complex_Anatomy_of_the_Elbow The Complex Anatomy of the Elbow - Ligaments and Capsule]
There are 4 main muscle groups at the elbow. The anterior biceps group, the posterior triceps group, the lateral extensor-supinator group and the medial flexor-pronator group.


Each muscle group applies a compressive load to the elbow joint when they contract.<ref name=":0" /><ref name=":1" />
=== '''Muscles''' ===
* Primary Elbow Flexors
{| class="wikitable"
**[[Brachialis]]
|+
** [[Biceps brachii]][[File:Elbow Muscles.jpeg|thumb|alt=|494x494px|Muscles of the elbow]]
! colspan="2" |Muscle Synergy of the Elbow
** [[Brachioradialis]]
|-
* Secondary Elbow Flexors
|Flexion
** [[Pronator Teres|Pronator teres]]
|Primary Flexors:
** [[Extensor carpi radialis longus]]
** [https://physio-pedia.com/Flexor_Carpi_Radialis Flexor carpi radialis] (at elbow angles 50 degrees or more)
* Primary Elbow Extensors
** [[Triceps brachii|Triceps]]
** [[Anconeus]]
* Secondary extensors
** [[Flexor Carpi Ulnaris Muscle|Flexor Carpi ulnaris]]
** [[Extensor Carpi Ulnaris|Extensor carpi ulnaris]]
* Pronation
** [[Pronator Teres|Pronator teres]]
** [[Pronator Quadratus|Pronator quadratus]]
* Supination
** Mainly [[Biceps brachii|Biceps]]
** Assistance from [[supinator]]
** Lesser degree finger and wrist extensors


* Biceps brachii
* Brachialis
* Brachioradialis
Secondary Flexors:
* Pronator teres
*[[Extensor carpi radialis longus]]
*[https://physio-pedia.com/Flexor_Carpi_Radialis Flexor carpi radialis] (at elbow angles 50 degrees or more)
|-
|Extension
|Primary Elbow Extensors
*[[Triceps brachii|Triceps]]
*[[Anconeus]]
Secondary Extensors
*[[Flexor Carpi Ulnaris Muscle|Flexor carpi ulnaris]]
*[[Extensor Carpi Ulnaris|Extensor carpi ulnaris]]
|-
|Pronation
|
*[[Pronator Teres|Pronator teres]]
*[[Pronator Quadratus|Pronator quadratus]]
|-
|Supination
|
* Mainly [[Biceps Brachii|biceps]]
* Assistance from [[supinator]]
* Lesser degree finger and wrist extensors
|}
== Differential Diagnosis  ==
== Differential Diagnosis  ==
Take into consideration both form (structures) and function in the differential diagnosis of the elbow.<ref name=":4" />


=== Form ===
=== Form ===
Take into consideration both form (structures) and function in the differential diagnosis of the elbow. (Ref – Ian Gatt course)


* Cervical Radiculopathy (Referred pain)<ref>Kang KC, Lee HS, Lee JH. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7788378/ Cervical radiculopathy focus on characteristics and differential diagnosis]. Asian Spine Journal. 2020 Dec;14(6):921.</ref>  
* [[Cervical Radiculopathy|Cervical radiculopathy]] (referred pain)<ref>Kang KC, Lee HS, Lee JH. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7788378/ Cervical radiculopathy focus on characteristics and differential diagnosis]. Asian Spine Journal. 2020 Dec;14(6):921.</ref>
* Systemic Conditions (e.g. Rheumatoid Arthritis)<ref>Javed M, Mustafa S, Boyle S, Scott F. [https://bjgp.org/content/bjgp/65/640/610.full.pdf Elbow pain: a guide to assessment and management in primary care.] British Journal of General Practice. 2015 Nov 1;65(640):610-2.</ref>  
* Systemic conditions (e.g. [[Rheumatoid Arthritis]])<ref>Javed M, Mustafa S, Boyle S, Scott F. [https://bjgp.org/content/bjgp/65/640/610.full.pdf Elbow pain: a guide to assessment and management in primary care.] British Journal of General Practice. 2015 Nov 1;65(640):610-2.</ref>
* Anterior Elbow:
* Anterior elbow:
** Biceps Strain/Tear/ Tendinopathy<ref>Bauer TM, Wong JC, Lazarus MD. Is nonoperative management of partial distal biceps tears really successful?. Journal of shoulder and elbow surgery. 2018 Apr 1;27(4):720-5.</ref>
** Biceps strain/tear/tendinopathy<ref>Bauer TM, Wong JC, Lazarus MD. Is nonoperative management of partial distal biceps tears really successful?. Journal of shoulder and elbow surgery. 2018 Apr 1;27(4):720-5.</ref>
** Myositis Ossificans in Brachioradialis<ref>Devilbiss Z, Hess M, Ho GW. [https://journals.lww.com/acsm-csmr/fulltext/2018/09000/myositis_ossificans_in_sport__a_review.7.aspx?casa_token=Vmz2RrS9TogAAAAA:fcv57AD-6vzfASqr6G8CXtY2-lmdZFxzCwPW6_91h6bbDWRM3nAdOOwmZb7pX3cZJx-USwoF9gPuGQ2kdh7x2Hv_ Myositis ossificans in sport: a review. Current sports medicine reports.] 2018 Sep 1;17(9):290-5.</ref>  
** [[Myositis Ossificans|Myositis ossificans]] in brachioradialis<ref>Devilbiss Z, Hess M, Ho GW. [https://journals.lww.com/acsm-csmr/fulltext/2018/09000/myositis_ossificans_in_sport__a_review.7.aspx?casa_token=Vmz2RrS9TogAAAAA:fcv57AD-6vzfASqr6G8CXtY2-lmdZFxzCwPW6_91h6bbDWRM3nAdOOwmZb7pX3cZJx-USwoF9gPuGQ2kdh7x2Hv_ Myositis ossificans in sport: a review. Current sports medicine reports.] 2018 Sep 1;17(9):290-5.</ref>
** Osteochondritis Dissecans (Trochlea)<ref name=":1">Churchill RW, Munoz J, Ahmad CS. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4896885/ Osteochondritis dissecans of the elbow.] Current reviews in musculoskeletal medicine. 2016 Jun;9(2):232-9.</ref>  
** [[Osteochondritis Dissecans|Osteochondritis dissecans]] (trochlea)<ref name=":1">Churchill RW, Munoz J, Ahmad CS. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4896885/ Osteochondritis dissecans of the elbow.] Current reviews in musculoskeletal medicine. 2016 Jun;9(2):232-9.</ref>


* Posterior Elbow
* Posterior elbow
** Triceps strain/tears/tendinopathy<ref>Shuttlewood K, Beazley J, Smith CD. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5478494/ Distal triceps injuries (including snapping triceps): a systematic review of the literature]. World journal of orthopedics. 2017 Jun 18;8(6):507.</ref>
** Triceps strain/tears/tendinopathy<ref>Shuttlewood K, Beazley J, Smith CD. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5478494/ Distal triceps injuries (including snapping triceps): a systematic review of the literature]. World journal of orthopedics. 2017 Jun 18;8(6):507.</ref>
** Olecranon bursitis<ref>Nchinda NN, Wolf JM. Clinical Management of Olecranon Bursitis: A Review. The Journal of Hand Surgery. 2021 Apr 9.</ref>
** Olecranon bursitis<ref>Nchinda NN, Wolf JM. Clinical Management of Olecranon Bursitis: A Review. The Journal of Hand Surgery. 2021 Apr 9.</ref>
** Osteochondritis Dissecans (Olecranon)<ref name=":1" />
** Osteochondritis dissecans (olecranon)<ref name=":1" />
** Olecranon Spurs/Loose bodies<ref>Robinson PM, Watts AC. Boxer’s Elbow: Internal Impingement of the Coronoid and Olecranon Process. InSurgical Techniques for Trauma and Sports Related Injuries of the Elbow 2020 (pp. 189-193). Springer, Berlin, Heidelberg.</ref>  
** Olecranon spurs/loose bodies<ref>Robinson PM, Watts AC. Boxer’s Elbow: Internal Impingement of the Coronoid and Olecranon Process. InSurgical Techniques for Trauma and Sports Related Injuries of the Elbow 2020 (pp. 189-193). Springer, Berlin, Heidelberg.</ref>


* Radial side of elbow
* Radial side of elbow
** Synovial Plica<ref>Lubiatowski P, Wałecka J, Dzianach M, Stefaniak J, Romanowski L. Synovial plica of the elbow and its clinical relevance. EFORT Open Reviews. 2020 Sep;5(9):549-57.</ref>  
** Synovial plica<ref>Lubiatowski P, Wałecka J, Dzianach M, Stefaniak J, Romanowski L. Synovial plica of the elbow and its clinical relevance. EFORT Open Reviews. 2020 Sep;5(9):549-57.</ref>
** [[Tennis Elbow Management|Lateral Epicondylalgia]] (involvement of [[Extensor Carpi Radialis Brevis]])
** [[Tennis Elbow Management|Lateral epicondylalgia]] (involvement of [[Extensor Carpi Radialis Brevis|extensor carpi radialis brevis]])
** Osteochondritis dissecans (Radio-capitellum)<ref name=":1" />  
** Osteochondritis dissecans (radio-capitellum)<ref name=":1" />
** Postero-lateral rotatory instability (PLRI)  - Radiocarpal ligament combined with lateral ulnar collateral ligament<ref>Conti Mica M, Caekebeke P, van Riet R. Lateral collateral ligament injuries of the elbow–chronic posterolateral rotatory instability (PLRI). EFORT open reviews. 2016 Dec;1(12):461-8.</ref><ref>Fedorka CJ, Oh LS. Posterolateral rotatory instability of the elbow. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):240-6.</ref>
** Posterolateral rotatory instability (PLRI)  - radiocarpal ligament combined with lateral ulnar collateral ligament<ref>Conti Mica M, Caekebeke P, van Riet R. Lateral collateral ligament injuries of the elbow–chronic posterolateral rotatory instability (PLRI). EFORT open reviews. 2016 Dec;1(12):461-8.</ref><ref>Fedorka CJ, Oh LS. Posterolateral rotatory instability of the elbow. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):240-6.</ref>
** Nerve entrapment: [[Posterior Interosseous Nerve Syndrome|Posterior interosseus nerve]] (Radial tunnel syndrome)<ref>Moraes MA, Goncalves RG, Santos JB, Belloti JC, Faloppa F, Moraes VY. Diagnosis and treatment of posterior interosseous nerve entrapment: systematic review. Acta ortopedica brasileira. 2017 Jan;25:52-4.</ref>  
** Nerve entrapment: [[Posterior Interosseous Nerve Syndrome|posterior interosseus nerve]] (radial tunnel syndrome)<ref>Moraes MA, Goncalves RG, Santos JB, Belloti JC, Faloppa F, Moraes VY. Diagnosis and treatment of posterior interosseous nerve entrapment: systematic review. Acta ortopedica brasileira. 2017 Jan;25:52-4.</ref>


* Ulnar side
* Ulnar side
** Medial epicondylalgia (Golfer’s Elbow)<ref>Barco R, Antuña SA. Medial elbow pain. EFORT open reviews. 2017 Aug;2(8):362-71.
** Medial epicondylalgia ([[Golfer’s Elbow Test|Golfer’s Elbow]])<ref>Barco R, Antuña SA. Medial elbow pain. EFORT open reviews. 2017 Aug;2(8):362-71.


Instability UCL ligament Rossy WH, Oh LS. Pitcher’s elbow: medial elbow pain in the overhead-throwing athlete. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):207-14.</ref>  
Instability UCL ligament Rossy WH, Oh LS. Pitcher’s elbow: medial elbow pain in the overhead-throwing athlete. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):207-14.</ref>
** Nerve entrapment of ulnar nerve<ref>McCarty LP. Approach to medial elbow pain in the throwing athlete. Current reviews in musculoskeletal medicine. 2019 Mar;12(1):30-40.</ref>
** Nerve entrapment of ulnar nerve<ref>McCarty LP. Approach to medial elbow pain in the throwing athlete. Current reviews in musculoskeletal medicine. 2019 Mar;12(1):30-40.</ref>
** Dislocations can cause injury to ulnar nerve
** Dislocations can cause injury to the ulnar nerve


* Fractures
* Fractures


It is evident that there is an abundance of conditions related to form that should be considered with the differential diagnosis of elbow pain. One way to sort it is to distinguish between traumatic and non-traumatic mechanisms.<ref name=":4">Gatt, I. Sporting Elbow - Clinical Reasoning and Differential Diagnosis Course. Physioplus. 2021.</ref>
It is evident that there is a large number of conditions related to form that should be considered with the differential diagnosis of elbow pain. Thus, it can be helpful to distinguish between traumatic and non-traumatic mechanisms.<ref name=":4">Gatt, I. Sporting Elbow - Clinical Reasoning and Differential Diagnosis Course. Plus. 2021.</ref>
{| class="wikitable"
|+
Table 1: Sporting elbow conditions and the common sports it can occur in
!Diagnosis
!Sport in which injury commonly occur
|-
|Biceps tendon rupture
|Strength training; weightlifting<ref>Pitsilos C, Gigis I, Chitas K, Papadopoulos P, Ditsios K. Systematic review of distal biceps tendon rupture in athletes: Treatment and Rehabilitation. Journal of Shoulder and Elbow Surgery. 2022 Mar 31.</ref>
|-
|Lateral elbow tendinopathy
|Sports associated with repeated gripping and/or wrist extension activities such as tennis, squash, badminton<ref name=":6" />
|-
|Flexor/pronator tendinopathy (golfer's elbow)
|Golf and in tennis players who uses a lot of topspin on their forehand
|-
|Medial collateral ligament sprain
|Throwing sports such as baseball, javelin, water polo, handball, cricket<ref name=":6" />
|-
|Ulnar nerve entrapment
|Throwing sports<ref name=":6" />
|-
|Olecranon bursitis
|Athletes falling on the posterior aspect of the elbow on hard surfaces in sports such as football (goalkeepers) and basketball<ref name=":6" />
|-
|Posterior dislocation
|Contact sports or when falling from a height such as pole vaulting<ref name=":6" />
|}


=== Function ===
=== Function ===
Often in athletes with elbow injuries it is evident that although the form/structures might be compromised, the athletes still show a high level of function in the injured area. As part of the differential diagnosis, it is key to not only identify the structures involved but also to have a clear picture of function (i.e. what the athlete can do; the pain pattern over time; traumatic vs non-traumatic injury; and urgency vs non-urgency surgical management.<ref name=":4" />  
Although the form/structures might be compromised in athletes with elbow injuries, often these individuals still show a high level of function in the injured area. As part of the differential diagnosis, it is key to not only identify the structures involved but also to have a clear picture of function (i.e. what the athlete can do; the pain pattern over time; traumatic vs non-traumatic injury; and urgency vs non-urgency in relation to surgical management).<ref name=":4" />[[File:Kinetic chain boxer example.png|thumb|324x324px|Kinetic Chain]]Factors relevant to function include:
 
Factors to consider related to function include:


* Kinetic chain
* Kinetic chain
** Knowledge and understanding of the kinetic chain and how different components could be affected is important. For example, when a boxer throws a punch with his lead arm the force is coming from the feet driving up into the hip. Approximately 50% of the force will come from the lower legs and into the trunk(30%) and into the upper limb(20%).
** Knowledge and understanding of the kinetic chain and how different components can be affected is important. For example, when a boxer throws a punch with his lead arm, the force is coming from the feet driving up into the hip. Approximately 50% of the force will come from the lower legs, 30% from the trunk and 20% from the upper limb.
** Keep in mind that these percentages may be different in different athletes (i.e. wheelchair-based athletes and swimmers)
** Keep in mind that these percentages may be different in different athletes (i.e. wheelchair-based athletes and swimmers)
** The key consideration is to acknowledge and understand the whole body contribution in an injury, pathology or dysfunction.<ref name=":4" />
** The key consideration is to acknowledge and understand the whole body contribution in an injury, pathology or dysfunction.<ref name=":4" />
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* Strength Testing
* Strength Testing
** Isometric testing
** Isometric testing
*** Examiner applying resistance with hand in different ranges will provide information on quality
*** An examiner applying resistance with their hand in different ranges will provide information on quality
*** Isometric testing with a handheld dynamometer will provide quantitative information in different ranges
*** Isometric testing with a handheld dynamometer will provide quantitative information in different ranges
** Isokinetic testing
** Isokinetic testing
*** Testing strength through range of motion
*** Testing strength through range of motion
** Strength testing in tennis elbow
** Strength testing in tennis elbow
*** Dorf et al.<ref name=":2">Dorf ER, Chhabra AB, Golish SR, McGinty JL, Pannunzio ME. Effect of elbow position on grip strength in the evaluation of lateral epicondylitis. The Journal of hand surgery. 2007 Jul 1;32(6):882-6.</ref> investigated the effect of elbow position on grip strength in the evaluation of lateral epicondylitis. There was no difference in grip strength in elbow flexion and extension for the healthy extremity. Grip strength was 29% stronger in elbow flexion than extension for the affected extremity. When comparing the healthy extremity with the affected extremity the affected extremity was 50% weaker in elbow extension compared to the healthy extremity. In elbow flexion the affected extremity was 31% weaker than the health extremity. This is significant especially with regards to elbow extension providing a mechanical advantage in grip strength of the hand. Using strength testing in people with tennis elbow will provide better objectivity.<ref name=":2" />
*** Dorf et al.<ref name=":2">Dorf ER, Chhabra AB, Golish SR, McGinty JL, Pannunzio ME. Effect of elbow position on grip strength in the evaluation of lateral epicondylitis. The Journal of hand surgery. 2007 Jul 1;32(6):882-6.</ref> investigated the effect of elbow position on grip strength in the evaluation of lateral epicondylitis. They found that there was no difference in grip strength in elbow flexion and extension for the healthy extremity. Grip strength was 29% stronger in elbow flexion than extension for the affected extremity. When comparing the healthy extremity with the affected extremity, the affected extremity was 50% weaker in elbow extension compared to the healthy extremity. In elbow flexion, the affected extremity was 31% weaker than the healthy extremity. This is significant especially with regards to elbow extension providing a mechanical advantage in grip strength of the hand. Using strength testing in people with tennis elbow will provide better objectivity.<ref name=":2" />


* Range of motion
* Range of motion[[File:ROM elbow.png|thumb|Elbow range of motion measured with smartphone]]
** Movements at the elbow to consider and measure:
** Movements at the elbow to consider and measure:
*** Flexion and Extension
*** Flexion and extension
*** Pronation and Supination
*** Pronation and supination
** Smartphone apps are available to help clinicians measure elbow range of motion.<ref name=":3">Vauclair F, Aljurayyan A, Abduljabbar FH, Barimani B, Goetti P, Houghton F, Harvey EJ, Rouleau DM. The smartphone inclinometer: A new tool to determine elbow range of motion?. European Journal of Orthopaedic Surgery & Traumatology. 2018 Apr;28(3):415-21.</ref>
** Smartphone apps are available to help clinicians measure elbow range of motion.<ref name=":3">Vauclair F, Aljurayyan A, Abduljabbar FH, Barimani B, Goetti P, Houghton F, Harvey EJ, Rouleau DM. The smartphone inclinometer: A new tool to determine elbow range of motion?. European Journal of Orthopaedic Surgery & Traumatology. 2018 Apr;28(3):415-21.</ref>
** Measuring flexion and extension with an inclinometer app on smartphone
** Measuring flexion and extension with an inclinometer app on smartphone
*** Patient rests arm flat on table to have humerus parallel to the horizontal plane, forearm in neutral. Inclinometer set to zero on table, patient flexes elbow maximally. Smartphone placed parallel to forearm and value can be read.<ref name=":3" />
*** Patient rests arm flat on table, so that the humerus is parallel to the horizontal plane. The forearm is in neutral. Inclinometer is set to zero on table. The patient flexes elbow maximally. Smartphone placed parallel to forearm and value can be read.<ref name=":3" />
*** For elbow extension the smartphone is aligned to the forearm in maximal extension<ref name=":3" />
*** For elbow extension the smartphone is aligned to the forearm in maximal extension.<ref name=":3" />
*** Add images from Ian Gatt
*** Also refer to the hand and wrist courses and pages


* End Feel
* End-feel
** From a manual therapy perspective (especially when range of motion is similar), it is advised to consider the end feel of the elbow joints. Consider the type of end feel as well as the athletes reaction with this type of provocation.<ref name=":4" />
** From a manual therapy perspective (especially when range of motion is similar), it is advised to consider the [[End-Feel|end-feel]] of the elbow joints. Consider the type of end-feel, as well as the athlete's reaction with this type of provocation.<ref name=":4" />


== Special Investigations ==
== Special Investigations ==


* Ultrasound
* Ultrasound
** Assists in management of stubborn cases of lateral epicondylalgia by characterising the extent of the tendon tearing and identifying the presence of concomitant RCL injury.<ref>Smith J, Finnoff JT. Diagnostic and interventional musculoskeletal ultrasound: part 2. Clinical applications. PM&R. 2009 Feb 1;1(2):162-77.</ref>
** Can assist in the management of stubborn cases of lateral epicondylalgia by characterising the extent of the tendon tearing and identifying the presence of concomitant RCL injury.<ref>Smith J, Finnoff JT. Diagnostic and interventional musculoskeletal ultrasound: part 2. Clinical applications. PM&R. 2009 Feb 1;1(2):162-77.</ref>
* MRI
* MRI
* Injection (Lignocaine or Marcaine)<ref>Hsieh LF, Kuo YC, Lee CC, Liu YF, Liu YC, Huang V. Comparison between corticosteroid and lidocaine injection in the treatment of tennis elbow: a randomized, double-blinded, controlled trial. American journal of physical medicine & rehabilitation. 2018 Feb 1;97(2):83-9.</ref>  
* Injection (Lignocaine or Marcaine)<ref>Hsieh LF, Kuo YC, Lee CC, Liu YF, Liu YC, Huang V. Comparison between corticosteroid and lidocaine injection in the treatment of tennis elbow: a randomized, double-blinded, controlled trial. American journal of physical medicine & rehabilitation. 2018 Feb 1;97(2):83-9.</ref>  
Line 174: Line 193:
== Clinical Tests ==
== Clinical Tests ==


* Lateral Epicondylalgia
* Lateral epicondylalgia
** Middle Finger Strength test/[[Maudsley's test|Maudsley’s Test]]
** Middle finger strength test/[[Maudsley's test|Maudsley’s test]]
** [[Mill’s Test|Mill’s test]]
** [[Mill’s Test|Mill’s test]]
** [[Cozen’s Test|Cozen’s test]]
** [[Cozen’s Test|Cozen’s test]]
Line 181: Line 200:
** Polk’s test lateral
** Polk’s test lateral
** Grip strength test
** Grip strength test
 
<div class="row">
* Medial Collateral Ligament Complex/Ulnar Collateral Ligament insufficiency
  <div class="col-md-4"> {{#ev:youtube|watch?v=tV8mymHe8Nw|250}} <div class="text-right"><ref>Clinical Physio. Maudsley's Test. Available from: watch?v=tV8mymHe8Nw[last accessed 1 December 2021]</ref></div></div>
** [[Moving Valgus Stress Test|Moving valgus stress test]]
  <div class="col-md-4"> {{#ev:youtube|watch?v=-qbwX4SCHNY|250}} <div class="text-right"><ref>The Student Physical Therapist. Mill's Test. Available from: https://www.youtube.com/watch?v=-qbwX4SCHNY [last accessed 1 December 2021]</ref></div></div>
<div class="col-md-4"> {{#ev:youtube|watch?v=faCi3v5Heo0&t=24s|250}} <div class="text-right"><ref>Clinical Physio. Cozen Test for Lateral Epicondylitis (Tennis Elbow) Available from: watch?v=faCi3v5Heo0&t=24s [last accessed 1 December 2021]</ref></div></div>
</div>
* Medial collateral ligament complex/ulnar collateral ligament insufficiency
**[[Moving Valgus Stress Test|Moving valgus stress test]]
** Valgus stress test
** Valgus stress test
** [[Milking Maneuver|Milking manoeuvre]]
** [[Milking Maneuver|Milking manoeuvre]]
 
<div class="row">
  <div class="col-md-6">
<clinicallyrelevant id="83479995" title="Valgus Stress Test" />
</div>
  <div class="col-md-6">
<clinicallyrelevant id="83479910" title="Milking Maneuver Test" />
</div>
</div>
* Posterolateral rotatory instability
* Posterolateral rotatory instability
** Table-top relocation test
** Table-top relocation test
Line 192: Line 222:
** Push-up test
** Push-up test
** Lateral pivot shift test
** Lateral pivot shift test
 
<div class="row">
  <div class="col-md-4">
<clinicallyrelevant id="83474671" title="Table Top Relocation Test" />
</div>
  <div class="col-md-4">
<clinicallyrelevant id="83479894" title="Lateral Pivot Shift Test" />
</div>
<div class="col-md-4"><clinicallyrelevant id="83473589" title="Chair Sign Test" /> </div>
</div>
* Total distal biceps rupture
* Total distal biceps rupture
** [[Elbow Hook Test|Hook test]]
**[[Elbow Hook Test|Hook test]]
** PFP test
** Passive forearm pronation (PFP) test
** Supination-pronation test
** Supination-pronation test
** [[Biceps Squeeze Test|Biceps squeeze test]]
** [[Biceps Squeeze Test|Biceps squeeze test]]
** BCI
** Biceps crease interval (BCI)
** BA flex test
** Bicipital aponeurosis (BA) flex test


* Total distal triceps rupture
* Total distal triceps rupture
Line 213: Line 251:


Whatever clinical test is being performed, always consider the amount of stress being applied to the structure and the element of safety.<ref name=":4" />
Whatever clinical test is being performed, always consider the amount of stress being applied to the structure and the element of safety.<ref name=":4" />
 
*  
**
 
== Proximal Radioulnar Joint and Humeroradial Joints in Lateral Epicondylalgia ==
== Proximal Radioulnar Joint and Humeroradial Joints in Lateral Epicondylalgia ==
It is important to consider the proximal radioulnar joint (PRUJ) and the humeroradial joints (HR) in relation to lateral epicondylalgia. Specifically taking into consideration the following:
It is important to consider the proximal radioulnar joint (PRUJ) and the humeroradial joints (HR) in relation to lateral epicondylalgia. Specifically taking into consideration the following:


* Extensor Carpi Radialis Brevis arises from the lateral epicondyle and the annular ligament
* Extensor carpi radialis brevis arises from the lateral epicondyle and the annular ligament


* Radial collateral ligament also originates from lateral epicondyle and inserts into the ligament.
* Radial collateral ligament also originates from lateral epicondyle and inserts into the ligament
* The close relationship between ECRB and RCL is seen in:
* The close relationship between ECRB and RCL is seen in:
** Concomitant injuries occurring
** Concomitant injuries  
** Potential instability around this region may provoke lateral epicondylalgia (tennis elbow)
** Potential instability around this region may provoke lateral epicondylalgia (tennis elbow)


Therefore having a good understanding of the close relationship between ECRB and RCL as well as the mobility of the radiohumeral joint will have an impact on lateral epicondylalgia (tennis elbow) management. Furthermore, consider the open and close-packed positions of the elbow joints to avoid confusion when palpating or mobilising these joints.  
Therefore, having a good understanding of the close relationship between ECRB and RCL, as well as the mobility of the radiohumeral joint will have an impact on lateral epicondylalgia (tennis elbow) management. Furthermore, consider the open- and close-packed positions of the elbow joints to avoid confusion when palpating or mobilising these joints.  
{| class="wikitable"
{| class="wikitable"
|+PRUJ and HR Joints in LE
|+PRUJ and HR Joints in LE
Line 248: Line 284:
== Medial Epicondylalgia and Pronator Teres ==
== Medial Epicondylalgia and Pronator Teres ==


* Hypertrophy of [[Pronator Teres]] may lead to symptoms around the medial epicondyle of the elbow.
* Hypertrophy of [[Pronator Teres|pronator teres]] may lead to symptoms around the medial epicondyle of the elbow.
* Pronator teres syndrome – median nerve being trapped between the two heads of pronator – this will mainly produce symptoms distally rather than locally.
* Pronator teres syndrome – i.e. the median nerve is trapped between the two heads of pronator – will mainly produce symptoms distally rather than locally.


== Conclusion ==
== Conclusion ==
Line 256: Line 292:
* Diagnosis
* Diagnosis
** Consider traumatic vs non-traumatic injuries
** Consider traumatic vs non-traumatic injuries
** Structures (Form) involved
** Structures (form) involved


* Prognosis = Function
* Prognosis = function
** What can or can’t the athlete do?
** What can or can’t the athlete do?
** Strength
** Strength
Line 266: Line 302:
* With non-traumatic injuries consider contributions from the shoulder and forearm, as well as the hand and wrist.
* With non-traumatic injuries consider contributions from the shoulder and forearm, as well as the hand and wrist.


* For Lateral Epicondylalgia and Medial Epicondylalgia – consider surrounding structures that can also be involved
* For lateral epicondylalgia and medial epicondylalgia, consider the surrounding structures that could also be involved
 
* '''The elbow can be tricky – if insure get a second opinion!'''
 
== Resources ==
*bulleted list
*x
or


#numbered list
* '''The elbow can be tricky – if unsure get a second opinion!'''
#x


== References  ==
== References  ==


<references />
<references />
[[Category:Course Pages]]
[[Category:Plus Content]]
[[Category:Elbow - Assessment and Examination]]
[[Category:Sports Injuries]]
[[Category:Sports Medicine]]

Revision as of 11:48, 18 August 2022

Original Editor - Wanda van Niekerk based on the course by Ian Gatt
Top Contributors - Wanda van Niekerk, Kim Jackson, Jess Bell, Robin Leigh Tacchetti and Robin Tacchetti

Introduction[edit | edit source]

The elbow is a complex joint and stability is provided by osseous and soft-tissue constraints. The elbow's relative instability makes it vulnerable to injuries, often caused by sports[1] and these injuries often involve several of the structures associated with the joint.[2] Apart from the clinical history, clinical reasoning and the physical examination are essential to make a diagnosis.

Anatomy of the Elbow[edit | edit source]

The distal humerus meets the proximal radius and ulna bones to form the elbow joint. It is known as a trochleogingylomoid joint as it can flex and extend as a hinge (ginglymoid) joint, as well as pivot around an axis (trochoid motion) (i.e. pronation and supination). It is an extremely congruent and stable joint.[3][4] The stability of the elbow is provided by the osseous anatomy, capsuloligamentous structure and the musculotendinous units that cross the elbow.[5]

Joints[edit | edit source]

The humerus, radius and ulna articulate to form the three joints that make up the elbow. [2] Table 1 provides an anatomical overview of the elbow. For more detailed information on the specific elbow joints, please read: The Complex Anatomy of the Elbow - Joints

Table 1: Anatomical overview of the elbow[6]
Humeroulnar Joint Radiohumeral Joint Proximal Radioulnar Joint
Active range of motion norms Flexion 140°

Extension 0 - 10°

Flexion 140°

Extension 0 - 10°

Pronation 80 -90°

Supination 80 -90°

Capsular pattern Flexion and extension Flexion and extension Equal limitations of supination and pronation
Ligaments Ulnar collateral ligament

(UCL -anterior oblique bundle; posterior oblique bundle; intermediate bundle; transverse ligament)

Lateral ulnar collateral

ligament (LUCL)

Radial collateral ligament (RCL) Annular ligament

Quadrate ligament

Oblique cord

Interosseous membrane

Ligaments and Capsule[edit | edit source]

Elbow Joint

The Medial Collateral Ligament Complex (MCLC) / Ulnar Collateral Ligament is the most important stabiliser of the elbow and it provides valgus and posteromedial stability. It comprises an anterior and posterior bundle and a supporting transverse ligament (ligament of Cooper). The anterior band is more taught in extension and relaxes into flexion, whereas the posterior band tightens in flexion and releases in extension. Thus, the anterior band is more vulnerable to valgus stress in elbow extension and the posterior band of the anterior medial collateral ligament (AMCL) is more vulnerable to valgus stress in elbow flexion.[7]

The Lateral Collateral Ligament Complex (LCLC) is the primary stabiliser against varus and external rotation stresses. It is formed by the lateral ulnar collateral ligament, the radial collateral ligament and the annular ligament.

The joint capsule surrounds all three joints of the elbow. There is a thickening medially and laterally of the joint capsule that blend with the MCLC and LCLC respectively and this contributes to the stability of the elbow.[8]

For more information, please read: The Complex Anatomy of the Elbow - Ligaments and Capsule

Muscles[edit | edit source]

Muscle Synergy of the Elbow
Flexion Primary Flexors:
  • Biceps brachii
  • Brachialis
  • Brachioradialis

Secondary Flexors:

Extension Primary Elbow Extensors

Secondary Extensors

Pronation
Supination
  • Mainly biceps
  • Assistance from supinator
  • Lesser degree finger and wrist extensors

Differential Diagnosis[edit | edit source]

Take into consideration both form (structures) and function in the differential diagnosis of the elbow.[9]

Form[edit | edit source]

  • Posterior elbow
    • Triceps strain/tears/tendinopathy[15]
    • Olecranon bursitis[16]
    • Osteochondritis dissecans (olecranon)[14]
    • Olecranon spurs/loose bodies[17]
  • Ulnar side
    • Medial epicondylalgia (Golfer’s Elbow)[22]
    • Nerve entrapment of ulnar nerve[23]
    • Dislocations can cause injury to the ulnar nerve
  • Fractures

It is evident that there is a large number of conditions related to form that should be considered with the differential diagnosis of elbow pain. Thus, it can be helpful to distinguish between traumatic and non-traumatic mechanisms.[9]

Table 1: Sporting elbow conditions and the common sports it can occur in
Diagnosis Sport in which injury commonly occur
Biceps tendon rupture Strength training; weightlifting[24]
Lateral elbow tendinopathy Sports associated with repeated gripping and/or wrist extension activities such as tennis, squash, badminton[5]
Flexor/pronator tendinopathy (golfer's elbow) Golf and in tennis players who uses a lot of topspin on their forehand
Medial collateral ligament sprain Throwing sports such as baseball, javelin, water polo, handball, cricket[5]
Ulnar nerve entrapment Throwing sports[5]
Olecranon bursitis Athletes falling on the posterior aspect of the elbow on hard surfaces in sports such as football (goalkeepers) and basketball[5]
Posterior dislocation Contact sports or when falling from a height such as pole vaulting[5]

Function[edit | edit source]

Although the form/structures might be compromised in athletes with elbow injuries, often these individuals still show a high level of function in the injured area. As part of the differential diagnosis, it is key to not only identify the structures involved but also to have a clear picture of function (i.e. what the athlete can do; the pain pattern over time; traumatic vs non-traumatic injury; and urgency vs non-urgency in relation to surgical management).[9]

Kinetic Chain

Factors relevant to function include:

  • Kinetic chain
    • Knowledge and understanding of the kinetic chain and how different components can be affected is important. For example, when a boxer throws a punch with his lead arm, the force is coming from the feet driving up into the hip. Approximately 50% of the force will come from the lower legs, 30% from the trunk and 20% from the upper limb.
    • Keep in mind that these percentages may be different in different athletes (i.e. wheelchair-based athletes and swimmers)
    • The key consideration is to acknowledge and understand the whole body contribution in an injury, pathology or dysfunction.[9]
  • Strength Testing
    • Isometric testing
      • An examiner applying resistance with their hand in different ranges will provide information on quality
      • Isometric testing with a handheld dynamometer will provide quantitative information in different ranges
    • Isokinetic testing
      • Testing strength through range of motion
    • Strength testing in tennis elbow
      • Dorf et al.[25] investigated the effect of elbow position on grip strength in the evaluation of lateral epicondylitis. They found that there was no difference in grip strength in elbow flexion and extension for the healthy extremity. Grip strength was 29% stronger in elbow flexion than extension for the affected extremity. When comparing the healthy extremity with the affected extremity, the affected extremity was 50% weaker in elbow extension compared to the healthy extremity. In elbow flexion, the affected extremity was 31% weaker than the healthy extremity. This is significant especially with regards to elbow extension providing a mechanical advantage in grip strength of the hand. Using strength testing in people with tennis elbow will provide better objectivity.[25]
  • Range of motion
    Elbow range of motion measured with smartphone
    • Movements at the elbow to consider and measure:
      • Flexion and extension
      • Pronation and supination
    • Smartphone apps are available to help clinicians measure elbow range of motion.[26]
    • Measuring flexion and extension with an inclinometer app on smartphone
      • Patient rests arm flat on table, so that the humerus is parallel to the horizontal plane. The forearm is in neutral. Inclinometer is set to zero on table. The patient flexes elbow maximally. Smartphone placed parallel to forearm and value can be read.[26]
      • For elbow extension the smartphone is aligned to the forearm in maximal extension.[26]
  • End-feel
    • From a manual therapy perspective (especially when range of motion is similar), it is advised to consider the end-feel of the elbow joints. Consider the type of end-feel, as well as the athlete's reaction with this type of provocation.[9]

Special Investigations[edit | edit source]

  • Ultrasound
    • Can assist in the management of stubborn cases of lateral epicondylalgia by characterising the extent of the tendon tearing and identifying the presence of concomitant RCL injury.[27]
  • MRI
  • Injection (Lignocaine or Marcaine)[28]

Clinical Tests[edit | edit source]

[29]
[30]
[31]

Valgus Stress Test video provided by Clinically Relevant

Milking Maneuver Test video provided by Clinically Relevant

  • Posterolateral rotatory instability
    • Table-top relocation test
    • Stand-up test/chair push up test
    • Push-up test
    • Lateral pivot shift test

Table Top Relocation Test video provided by Clinically Relevant

Lateral Pivot Shift Test video provided by Clinically Relevant

Chair Sign Test video provided by Clinically Relevant

  • Total distal biceps rupture
    • Hook test
    • Passive forearm pronation (PFP) test
    • Supination-pronation test
    • Biceps squeeze test
    • Biceps crease interval (BCI)
    • Bicipital aponeurosis (BA) flex test
  • Total distal triceps rupture
    • Triceps squeeze test
  • Posteromedial impingement syndrome
    • Arm bar test
    • Valgus overload test/posteromedial impingement test
  • Medial epicondylalgia
    • Epicondylitis medialis test/ Golfer’s elbow test
    • Polk’s test medial

Whatever clinical test is being performed, always consider the amount of stress being applied to the structure and the element of safety.[9]

Proximal Radioulnar Joint and Humeroradial Joints in Lateral Epicondylalgia[edit | edit source]

It is important to consider the proximal radioulnar joint (PRUJ) and the humeroradial joints (HR) in relation to lateral epicondylalgia. Specifically taking into consideration the following:

  • Extensor carpi radialis brevis arises from the lateral epicondyle and the annular ligament
  • Radial collateral ligament also originates from lateral epicondyle and inserts into the ligament
  • The close relationship between ECRB and RCL is seen in:
    • Concomitant injuries
    • Potential instability around this region may provoke lateral epicondylalgia (tennis elbow)

Therefore, having a good understanding of the close relationship between ECRB and RCL, as well as the mobility of the radiohumeral joint will have an impact on lateral epicondylalgia (tennis elbow) management. Furthermore, consider the open- and close-packed positions of the elbow joints to avoid confusion when palpating or mobilising these joints.

PRUJ and HR Joints in LE
Joints Open Packed Close Packed
PRUJ Elbow flexion (70°)

Supination (5°)

Elbow extension

Full supination

HR Elbow extension

Full supination

Elbow flexion (70°)

Supination (5°)

Medial Epicondylalgia and Pronator Teres[edit | edit source]

  • Hypertrophy of pronator teres may lead to symptoms around the medial epicondyle of the elbow.
  • Pronator teres syndrome – i.e. the median nerve is trapped between the two heads of pronator – will mainly produce symptoms distally rather than locally.

Conclusion[edit | edit source]

General guidelines to consider:[9]

  • Diagnosis
    • Consider traumatic vs non-traumatic injuries
    • Structures (form) involved
  • Prognosis = function
    • What can or can’t the athlete do?
    • Strength
    • Range of motion
    • End feel
  • With non-traumatic injuries consider contributions from the shoulder and forearm, as well as the hand and wrist.
  • For lateral epicondylalgia and medial epicondylalgia, consider the surrounding structures that could also be involved
  • The elbow can be tricky – if unsure get a second opinion!

References[edit | edit source]

  1. Zwerus EL, Somford MP, Maissan F, Heisen J, Eygendaal D, Van Den Bekerom MP. Physical examination of the elbow, what is the evidence? A systematic literature review. British journal of sports medicine. 2018 Oct 1;52(19):1253-60.
  2. 2.0 2.1 Acosta Batlle J, Cerezal L, Lopez Parra MD, Alba B, Resano S, Blazquez Sanchez J. The elbow: review of anatomy and common collateral ligament complex pathology using MRI. Insights into imaging. 2019 Dec;10(1):1-25.
  3. Bryce CD, Armstrong AD. Anatomy and biomechanics of the elbow. Orthopedic Clinics of North America. 2008 Apr 1;39(2):141-54.
  4. Cavallo M, Rotini R, Cutti AG, Parel I. Functional Anatomy and Biomechanic Models of the Elbow. In The Elbow 2018 (pp. 29-40). Springer, Cham.
  5. 5.0 5.1 5.2 5.3 5.4 5.5 Vicenzino w, Scott A, Bell S, Popovic N. Elbow and arm pain. In: Brukner P, Clarsen B, Cook J, Cools A, Crossley K, Hutchinson M, McCrory P, Bahr R, Khan K. eds. Brukner & Khan’s Clinical Sports Medicine: Injuries, Volume 1, 5e.Sydney: McGraw Hill, 2017.
  6. Ward K. The elbow region: anatomy, assessment and injuries. InRoutledge Handbook of Sports Therapy, Injury Assessment and Rehabilitation 2015 Sep 16 (pp. 458-498). Routledge.
  7. Smith JR, Amirfeyz R. Clinical Anatomy of the Elbow. InSports Injuries of the Elbow 2021 (pp. 1-13). Springer, Cham.
  8. Chin K, Hussain S, Mazis G, Arya A. Clinical anatomy and biomechanics of the elbow. Journal of Clinical Orthopaedics and Trauma. 2021 Jun 24:101485.
  9. 9.0 9.1 9.2 9.3 9.4 9.5 9.6 Gatt, I. Sporting Elbow - Clinical Reasoning and Differential Diagnosis Course. Plus. 2021.
  10. Kang KC, Lee HS, Lee JH. Cervical radiculopathy focus on characteristics and differential diagnosis. Asian Spine Journal. 2020 Dec;14(6):921.
  11. Javed M, Mustafa S, Boyle S, Scott F. Elbow pain: a guide to assessment and management in primary care. British Journal of General Practice. 2015 Nov 1;65(640):610-2.
  12. Bauer TM, Wong JC, Lazarus MD. Is nonoperative management of partial distal biceps tears really successful?. Journal of shoulder and elbow surgery. 2018 Apr 1;27(4):720-5.
  13. Devilbiss Z, Hess M, Ho GW. Myositis ossificans in sport: a review. Current sports medicine reports. 2018 Sep 1;17(9):290-5.
  14. 14.0 14.1 14.2 Churchill RW, Munoz J, Ahmad CS. Osteochondritis dissecans of the elbow. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):232-9.
  15. Shuttlewood K, Beazley J, Smith CD. Distal triceps injuries (including snapping triceps): a systematic review of the literature. World journal of orthopedics. 2017 Jun 18;8(6):507.
  16. Nchinda NN, Wolf JM. Clinical Management of Olecranon Bursitis: A Review. The Journal of Hand Surgery. 2021 Apr 9.
  17. Robinson PM, Watts AC. Boxer’s Elbow: Internal Impingement of the Coronoid and Olecranon Process. InSurgical Techniques for Trauma and Sports Related Injuries of the Elbow 2020 (pp. 189-193). Springer, Berlin, Heidelberg.
  18. Lubiatowski P, Wałecka J, Dzianach M, Stefaniak J, Romanowski L. Synovial plica of the elbow and its clinical relevance. EFORT Open Reviews. 2020 Sep;5(9):549-57.
  19. Conti Mica M, Caekebeke P, van Riet R. Lateral collateral ligament injuries of the elbow–chronic posterolateral rotatory instability (PLRI). EFORT open reviews. 2016 Dec;1(12):461-8.
  20. Fedorka CJ, Oh LS. Posterolateral rotatory instability of the elbow. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):240-6.
  21. Moraes MA, Goncalves RG, Santos JB, Belloti JC, Faloppa F, Moraes VY. Diagnosis and treatment of posterior interosseous nerve entrapment: systematic review. Acta ortopedica brasileira. 2017 Jan;25:52-4.
  22. Barco R, Antuña SA. Medial elbow pain. EFORT open reviews. 2017 Aug;2(8):362-71. Instability UCL ligament Rossy WH, Oh LS. Pitcher’s elbow: medial elbow pain in the overhead-throwing athlete. Current reviews in musculoskeletal medicine. 2016 Jun;9(2):207-14.
  23. McCarty LP. Approach to medial elbow pain in the throwing athlete. Current reviews in musculoskeletal medicine. 2019 Mar;12(1):30-40.
  24. Pitsilos C, Gigis I, Chitas K, Papadopoulos P, Ditsios K. Systematic review of distal biceps tendon rupture in athletes: Treatment and Rehabilitation. Journal of Shoulder and Elbow Surgery. 2022 Mar 31.
  25. 25.0 25.1 Dorf ER, Chhabra AB, Golish SR, McGinty JL, Pannunzio ME. Effect of elbow position on grip strength in the evaluation of lateral epicondylitis. The Journal of hand surgery. 2007 Jul 1;32(6):882-6.
  26. 26.0 26.1 26.2 Vauclair F, Aljurayyan A, Abduljabbar FH, Barimani B, Goetti P, Houghton F, Harvey EJ, Rouleau DM. The smartphone inclinometer: A new tool to determine elbow range of motion?. European Journal of Orthopaedic Surgery & Traumatology. 2018 Apr;28(3):415-21.
  27. Smith J, Finnoff JT. Diagnostic and interventional musculoskeletal ultrasound: part 2. Clinical applications. PM&R. 2009 Feb 1;1(2):162-77.
  28. Hsieh LF, Kuo YC, Lee CC, Liu YF, Liu YC, Huang V. Comparison between corticosteroid and lidocaine injection in the treatment of tennis elbow: a randomized, double-blinded, controlled trial. American journal of physical medicine & rehabilitation. 2018 Feb 1;97(2):83-9.
  29. Clinical Physio. Maudsley's Test. Available from: watch?v=tV8mymHe8Nw[last accessed 1 December 2021]
  30. The Student Physical Therapist. Mill's Test. Available from: https://www.youtube.com/watch?v=-qbwX4SCHNY [last accessed 1 December 2021]
  31. Clinical Physio. Cozen Test for Lateral Epicondylitis (Tennis Elbow) Available from: watch?v=faCi3v5Heo0&t=24s [last accessed 1 December 2021]
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