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Abstract
Motor control deficits outlasting self-reported symptoms are often reported following mild traumatic brain injury (mTBI). The exact duration and nature of these deficits remains unknown. The current study aimed to compare postural responses to static or dynamic virtual visual inputs and during standard clinical tests of balance in 38 children between 9 and 18 years-of-age, at 2 weeks, 3 and 12 months post-concussion. Body sway amplitude (BSA) and postural instability (vRMS) were measured in a 3D virtual reality (VR) tunnel (i.e., optic flow) moving in the antero-posterior direction in different conditions. Measures derived from standard clinical balance evaluations (BOT-2, Timed tasks) and post-concussion symptoms (PCSS-R) were also assessed. Results were compared to those of 38 healthy non-injured children following a similar testing schedule and matched according to age, gender, and premorbid level of physical activity. Results highlighted greater postural response with BSA and vRMS measures at 3 months post-mTBI, but not at 12 months when compared to controls, whereas no differences were observed in post-concussion symptoms between mTBI and controls at 3 and 12 months. These deficits were specifically identified using measures of postural response in reaction to 3D dynamic visual inputs in the VR paradigm, while items from the BOT-2 and the 3 timed tasks did not reveal deficits at any of the test sessions. PCSS-R scores correlated between sessions and with the most challenging condition of the BOT-2 and as well as with the timed tasks, but not with BSA and vRMS. Scores obtained in the most challenging conditions of clinical balance tests also correlated weakly with BSA and vRMS measures in the dynamic conditions. These preliminary findings suggest that using 3D dynamic visual inputs such as optic flow in a controlled VR environment could help detect subtle postural impairments and inspire the development of clinical tools to guide rehabilitation and return to play recommendations.
Highlights
IntroductionPostural control in humans involves the integration of different sensory inputs to control motor output
Following mild traumatic brain injury, postural problems are commonly reported in challenging situations in both adults [1,2,3,4,5,6,7,8] and children [9, 10]; yet, these findings are often ignored in clinical practice guidelines and not adequately tested before patients are discharged from follow-up programs
A number of recent reviews and meta-analyses have pointed out potential persistent motor system and attentional deficits following mild traumatic brain injury (mTBI) that are not detected with standard clinical balance tests, but that would lead to an increase risk of neuromuscular injuries within the year following an mTBI [25,26,27]
Summary
Postural control in humans involves the integration of different sensory inputs to control motor output. Residual sensory integration dysfunction can be seen 30 days post-injury, manifesting as postural deficits induced by visual field motion [5]. A study by our group using psychophysical assessment tools has shown poor integration of higher level visual information (i.e., second order stimuli requiring higherlevel visual cortical function), which persisted up to 3 months in children aged 8–16 years following mTBI [13]. No previous study has investigated the role of high-level visuo-motor integration in postural control in children following mTBI while measuring the evolution of such a behavior prospectively post-injury. A number of recent reviews and meta-analyses have pointed out potential persistent motor system and attentional deficits following mTBI that are not detected with standard clinical balance tests, but that would lead to an increase risk of neuromuscular injuries (i.e., lower extremity injury) within the year following an mTBI [25,26,27]
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