ISSN: 2476-2075
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  • Commentary   
  • Optom open access 2015, Vol 1(3): 102
  • DOI: 10.4172/2476-2075.1000102

Sports-Related Concussion: The Eyes Have It

Leonard V Messner*
Department of Optometry, The Illinois College of Optometry, USA
*Corresponding Author: Leonard V Messner, Professor of Optometry, Department of Optometry, The Illinois College of Optometry, USA, Tel: 312-949-7108, Fax: 312-949-7389, Email: lmessner@eyecare.ico.edu

Received: 01-Oct-2015 / Accepted Date: 15-Nov-2015 / Published Date: 20-Nov-2015 DOI: 10.4172/2476-2075.1000102

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Editorial

Concussion is a form of mild traumatic brain injury (TBI) owing to structural, metabolic and functional changes involving white mater tracts of the central nervous system in the absence of macroscopic findings [1-4]. Sports-related concussion is a rapidly evolving condition stimulating interest among lay and scientific communities [3]. Recent studies have shown a high rate of underreporting of concussion signs and symptoms by athletes and sideline personnel [5,6]. Accordingly, reliable and validated testing strategies are necessary to insure timely detection and removal from play for individuals suspected of concussion. Vision and visual motor problems are commonly reported among athletes following concussion [7-15]. This is to be expected as it is estimated that approximately 50% of the brain is devoted to vision and visual motor processing [16]. As such, testing of vision and ocular motility function are critical to the evaluation of a concussed individual. While disorders of vision and ocular motility have been well-reported with TBI, most of these studies have focused on visual motor problems in the setting of combatrelated TBI resulting from blast injuries [8]. There are limited studies related to vision and visual motor abnormalities from sport-related concussion.

While disorders of vision and ocular motility have been wellreported with TBI, most of these studies have focused on visual motor problems in the setting of combat-related TBI resulting from blast injuries [17]. There are limited studies related to vision and visual motor abnormalities from sport-related concussion.

Common vision and visual motor problems in the setting of concussion include photophobia, convergence insufficiency, disorders of accommodation and disorders of saccades and pursuit eye movements (versional dysfunction). A comprehensive ocular examination with attention to these areas of vision and visual motor function is essential to the evaluation of a concussed individual.

Photophobia

Photophobia and phonophobia are commonly reported in the setting of concussion [18-21]. It is speculated that the mechanism may be related to disturbance of the cortico-thalamic pathways with meningeal irritation in a manner similar to that reported with migraine [18]. Light-filtering lenses have shown benefit in reducing light intolerance and reading performance in patients with traumainduced photophobia [22]. Lynch et al. have recently reported on the therapeutic value of computer gaming lenses in the mitigation of photosensitivity and headache following concussion [23].

Vergence and accommodative disorders

Military models of traumatic brain injury show a high prevalence of vergence and accommodative deficits in these populations. In a study of 40 soldiers with combat-related mild traumatic brain injury (mTBI), Capo-Aponte and colleagues reported on the proportion of near pointrelated visual-motor abnormalities as compared to age-matched controls [17]. Specific oculomotor abnormalities included high exophoria, decreased fusion ranges, receded near point of convergence, defective pursuit and saccadic eye movements, decreased amplitude of accommodation and decreased monocular accommodative facility. These clinical findings were associated with reduced reading speed and comprehension and an increased convergence insufficiency symptom survey score [17].

Convergence insufficiency is a binocular vision disorder characterized by a receded near point of convergence with associated symptoms while performing near point tasks [24]. Convergence insufficiency has been reported in 23% to 46% of individuals with traumatic brain injury [8,25-27]. By comparison, convergence insufficiency is found in 1% to 8% of individuals without a history of traumatic brain injury [28-31]. Recession in near point of convergence in TBI populations has largely been reported among military and auto injury patients with sustained visual symptoms. In a recent study of soccer players, Tierney and colleagues reported on recession in near point of convergence following repetitive headers in test subjects who were exposed to ten consecutive headers from a JUGS machine [32]. In a prospective study of sports-related head trauma, Figler and colleagues have noted an improvement (shortening) in near point of convergence as a function of overall improvement in concussionrelated symptoms [33].

Accommodative dysfunction is reported in 21% to 47% of nonpresbyopic TBI populations [11,25,34,35]. As is true with convergence insufficiency, the majority of research studies devoted to accommodative disorders with TBI represent analysis of motor vehicle and military populations. Given that these populations encompass, on average, more severe and sustained forms of TBI, it is difficult to draw similar conclusions with sport-related injuries.

Impaired saccade and pursuit eye movements

Ocular motility dysfunction is reported in approximately 90% of individuals with concussion [14]. Anatomical correlates for impaired eye movements are linked to the lesions of the anterior corona radiata (ACR), dorsolateral prefrontal cortex (DLPFC) and genu of the corpus callosum [36,37]. These areas of “frontal vulnerability” also represent the most commonly affected substrates for trauma-induced axonal injury as determined through meta-analyses of functional magnetic resonance imaging (fMRI) and diffusion tensor imaging (DTI) abnormalities in individuals with mTBI [38]. In addition to the initiation and control of eye movements, frontal regions of neuronal injury also correlate with depressed working memory and neurocognitive dysfunction [38,39].

In 2009, Heitger and colleagues reported on impaired eye movements among individuals with post-concussion syndrome (PCS) following mild closed head injury (mCHI) [12]. This study compared 36 PCS subjects with 36 individually matched controls (mCHI patients with similar severity of injury but with resolution of signs and symptoms) as a function of reflexive, anti- and self-paced saccades, memory-guided sequences and smooth pursuits [12]. They found worse performance on anti-saccades, self-paced saccades, memoryguided sequences and smooth pursuits [12]. Furthermore, compared with neuropsychological tests, eye movement abnormalities were more likely to be related to PCS cases with high symptom load [12].

The King Devick (KD) Test has recently been studied as rapid sideline screening test for the detection of concussion [40]. KD is a test of rapid number naming that assesses saccades, accommodation, convergence, immediate recall and verbalization of response [41]. Post incident responses are recorded and compared to pre incident baseline responses with an increase in test time being suggestive of concussion [41]. In a study of boxers and mixed martial arts fighters, Galetta and colleagues showed reduced KD performance (longer test time) in the setting of concussion [41]. Similar studies have shown impaired rapid number naming with sports-related concussion in collegiate and youth sports [10,42,43] and club rugby players [44]. Meta-analysis of pooled data from 15 studies has shown an 86% sensitivity and 90% specificity for the detection of concussion using the KD rapid number naming protocol [45]. Marindes and colleagues have reported on a comparative analysis of cognitive performance (Standardized Assessment of Concussion {SAC}), balance (Balance Error Scoring System {BESS}) and rapid number naming (KD) among college athletes in the sideline evaluation of concussion [43,46]. Their analysis showed increase (worsening) of KD time scores in 79% of concussed athletes as compared to a 52% worsening with SAC. Combining KD and SAC correctly identified 89% of concussions. The addition of BESS to KD and SAC resulted in a 100% capture of all concussions.

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Conclusion

With increasing attention to sport-related concussion, there is a need to develop validated and efficient testing protocols for sideline concussion evaluation so as to facilitate immediate removal from play. Vision and visual motor abnormalities are common in the setting of concussion and are shown to be highly sensitive and specific for concussion detection as compared to cognitive and balance assessments. Optometrists are strategically positioned for the development of research initiatives and testing paradigms for individuals with suspected concussion. While no one test is definitive for the sideline diagnosis of concussion, composite test batteries that include vision, balance and cognitive function are emerging as required guidelines for concussion detection and removal from play.

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References

  1. Giza CC, Kutcher JS, Ashwal S, Barth J, Getchius TS, et al. (2013) Summary of evidence-based guideline update: evaluation and management of concussion in sports: report of the Guideline Development Subcommittee of the American Academy of Neurology. Neurology 80: 2250-2257.
  2. Halstead ME, Walter KD, Council on Sports Medicine and Fitness (2010) American Academy of Pediatrics. Clinical report--sport-related concussion in children and adolescents. Pediatrics 126: 597-615.
  3. Harmon KG, Drezner JA, Gammons M, Guskiewicz KM, Halstead M, et al. (2013) American Medical Society for Sports Medicine position statement: concussion in sport.Br J Sports Med 47: 15-26.
  4. Giza CC, Hovda DA (2014) The new neurometabolic cascade of concussion.Neurosurgery 75 Suppl 4: S24-33.
  5. Kroshus E, Daneshvar DH, Baugh CM, Nowinski CJ, Cantu RC (2014) NCAA concussion education in ice hockey: an ineffective mandate.Br J Sports Med 48: 135-140.
  6. Torres DM, Galetta KM, Phillips HW, Dziemianowicz EM, Wilson JA, et al. (2013) Sports-related concussion: Anonymous survey of a collegiate cohort.NeurolClinPract 3: 279-287.
  7. Ciuffreda KJ, Kapoor N, Rutner D, Suchoff IB, Han ME, et al. (2007) Occurrence of oculomotor dysfunctions in acquired brain injury: a retrospective analysis. Optometry 78: 155-161.
  8. Cohen M, Groswasser Z, Barchadski R, Appel A (2015) Convergence insufficiency in brain-injured patients. Brain Inj. 3:187-191.
  9. Dougherty AL, MacGregor AJ, Han PP, Heltemes KJ, Galarneau MR (2011) Visual dysfunction following blast-related traumatic brain injury from the battlefield. Brain Inj 25: 8-13.
  10. Galetta KM, Morganroth J, Moehringer N, Mueller B, Hasanaj L, et al. (2015) Adding Vision to Concussion Testing: A Prospective Study of Sideline Testing in Youth and Collegiate Athletes. J Neuroophthalmol 35: 235-241.
  11. Green W, Ciuffreda KJ, Thiagarajan P, Szymanowicz D, Ludlam DP, et al. (2010) Accommodation in mild traumatic brain injury. Rehabil Res Dev 47: 183-199.
  12. Heitger MH, Jones RD, MacLeod AD, Snell DL, Frampton CM, et al. (2009) Impaired eye movements in post-concussion syndrome indicate suboptimal brain function beyond the influence of depression, malingering or intellectual ability. Brain132: 2850-2870.
  13. Maruta J, Ghajar J (2014) Detecting eye movement abnormalities from concussion.  ProgNeurolSurg 28: 226-233.
  14. Samadani U, Ritlop R, Reyes M, Nehrbass E, Li M, et al. (2015) Eye tracking detects disconjugate eye movements associated with structural traumatic brain injury and concussion. J Neurotrauma 32: 548-556.
  15. Thiagarajan P, Ciuffreda KJ, Ludlam DP (2011) Vergence dysfunction in mild traumatic brain injury (mTBI): a review. Ophthalmic Physiol Opt 31: 456-468.
  16. Kaas JH (2008) The evolution of the complex sensory and motor systems of the human brain.Brain Res Bull 75: 384-390.
  17. Capó-Aponte JE, Urosevich TG, Temme L a, Tarbett AK, Sanghera NK (2012) Visual dysfunctions and symptoms during the subacute stage of blast-induced mild traumatic brain injury. Mil Med 177 :804-813.
  18. Digre KB, Brennan KC (2012) Shedding light on photophobia.J Neuroophthalmol 32: 68-81.
  19. Truong JQ, Ciuffreda KJ, Han MH, Suchoff IB (2014) Photosensitivity in mild traumatic brain injury (mTBI): a retrospective analysis.Brain Inj 28: 1283-1287.
  20. Waddell PA, Gronwall DM (1984) Sensitivity to light and sound following minor head injury. ActaNeurolScand 69 :270-276.
  21. Bohnen N, Twijnstra A, Wijnen G, Jolles J (1991) Tolerance for light and sound of patients with persistent post-concussional symptoms 6 months after mild head injury. J Neurol 238 :443-446.
  22. Jackowski MM, Sturr JF, Taub HA, Turk MA (1996) Photophobia in patients with traumatic brain injury: Uses of light-filtering lenses to enhance contrast sensitivity and reading rate.NeuroRehabilitation 6: 193-201.
  23. Lynch JM, Anderson M, Benton B, Green SS (2015) The gaming of concussions: a unique intervention in postconcussion syndrome.J Athl Train 50: 270-276.
  24. Scheiman M, Gwiazda J, Li T (2011) Non-surgical interventions for convergence insufficiency.Cochrane Database Syst Rev : CD006768.
  25. Alvarez TL, Kim EH, Vicci VR, Dhar SK, Biswal BB, et al. (2012) Concurrent vision dysfunctions in convergence insufficiency with traumatic brain injury.Optom Vis Sci 89: 1740-1751.
  26. Timmons SD, Duhaime AC, Lee SM (2010) Mild traumatic brain injury. Introduction. Neurosurg Focus 29 :1.
  27. Brahm KD, Wilgenburg HM, Kirby J, Ingalla S, Chang CY, et al. (2009) Visual impairment and dysfunction in combat-injured servicemembers with traumatic brain injury.Optom Vis Sci 86: 817-825.
  28. Cohen M, Groswasser Z, Barchadski R, Appel A (2009) Convergence insufficiency in brain-injured patients. Brain Inj 3: 187-191.
  29. Létourneau JE, Lapierre N, Lamont A (1979) The relationship between convergence insufficiency and school achievement. Am J OptomPhysiol Opt 56: 18-22
  30. Rouse MW, Borsting E, Hyman L, Hussein M, Cotter SA, et al. (1999) Frequency of convergence insufficiency among fifth and sixth graders. The Convergence Insufficiency and Reading Study (CIRS) group. Optom Vis Sci 76: 643-649.
  31. Porcar E, Martinez-Palomera A (1997) Prevalence of general binocular dysfunctions in a population of university students. Optom Vis Sci 74: 111-113.
  32. Lara F, Cacho P, García A, Megías R (2001) General binocular disorders: prevalence in a clinic population. Ophthalmic Physiol Opt 21: 70-74.
  33. Tierney RT (2014) In: American Academy of Neurology Sports Concussion Conference.
  34. Figler R (2014) In: American Academy of Neurology Sports Concussion Conference.
  35. Goodrich GL, Kirby J, Cockerham G, Ingalla SP, Lew HL (2007) Visual function in patients of a polytrauma rehabilitation center: A descriptive study. J Rehabil Res Dev 44: 929-936.
  36. Stelmack JA, Frith T, Van Koevering D, Rinne S, Stelmack TR (2009) Visual function in patients followed at a Veterans Affairs polytrauma network site: an electronic medical record review. Optometry 80: 419-424.
  37. Maruta J, Suh M, Niogi SN, Mukherjee P, Ghajar J (2010) Visual tracking synchronization as a metric for concussion screening.J Head Trauma Rehabil 25: 293-305.
  38. Pierrot-Deseilligny C (1994) Saccade and smooth-pursuit impairment after cerebral hemispheric lesions. EurNeurol 34:121-134.
  39. Eierud C, Craddock RC, Fletcher S, Aulakh M, King-Casas B, et al. (2014) Neuroimaging after mild traumatic brain injury: Review and meta-analysis.NeuroimageClin 4: 283-294.
  40. Galetta MS, Galetta KM, McCrossin J, Wilson JA, Moster S, et al. (2013) Saccades and memory: baseline associations of the King-Devick and SCAT2 SAC tests in professional ice hockey players.J NeurolSci 328: 28-31.
  41. Ventura RE, Jancuska JM, Balcer LJ, Galetta SL (2015) Diagnostic tests for concussion: is vision part of the puzzle?J Neuroophthalmol 35: 73-81.
  42. Galetta KM, Barrett J, Allen M, Madda F, Delicata D, et al. (2011) The King-Devick test as a determinant of head trauma and concussion in boxers and MMA fighters.Neurology 76: 1456-1462.
  43. Galetta KM, Brandes LE, Maki K, Dziemianowicz MS, Laudano E, et al. (2011) The King-Devick test and sports-related concussion: study of a rapid visual screening tool in a collegiate cohort.J NeurolSci 309: 34-39.
  44. Marinides Z, Galetta KM, Andrews CN, Wilson JA, Herman DC, et al. (2014) Vision testing is additive to the sideline assessment of sports-related concussion. NeurolClin 1-10
  45. King D, Clark T, Gissane C (2012) Use of a rapid visual screening tool for the assessment of concussion in amateur rugby league: a pilot study.J NeurolSci 320: 16-21.
  46. Galetta KM, Liu M, Leong DF, Ventura RE, Galetta SL, et al. (2015) The King-Devick test of rapid number naming for concussion detection: meta-analysis and systematic review of the literature. Concussion.

Citation: Messner LV (2015) Sports-Related Concussion: The “Eyes” Have It. Optom open access 1: 102. DOI: 10.4172/2476-2075.1000102

Copyright: © 2015 Messner LV. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

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