REFINEMENT OF SALIVA MI-RNA BIOMARKERS FOR SPORT-RELATED CONCUSSION

ABSTRACT Introduction: The changes in brain structure caused by a sports-related concussion may initially be indistinguishable, however, the irreversible deleterious effects are noted in the long term. An early diagnosis may provide the patient with a better recovery chance and increased survival. For this purpose, this paper studies the feasibility of a diagnosis for concussion by microRNA (mi-RNA) biomarkers contained in the saliva of athletes. Objective: Verify whether salivary miRNAs could be considered good biomarkers for sports concussion. Methodology: Salivary mi-RNA levels were determined from 120 saliva samples of 120 players. There were 43 with a diagnosis of concussion and 77 without a diagnosis of concussion. Samples from players with a concussion were collected 30 minutes prior to activity, samples from individuals who did not engage in physical activity were also compared. Results: On the evaluation of 30 miRNA from individuals with a concussion between contact and non-contact sports there was high detection reliability(P<.05). Both miR-532-5p and miR-182-5p showed reduced amounts of physical activity. The miRNA-532-5p and miRNA-182-5p show significant results among 43 subjects from pre-exercise to post-exercise. The miRNA-4510 showed a significant result (p < 0.05) between contact and non-contact sport types. The amount of miRNA-4510 expanded in 20 individuals in the contact sport at post-exercise but remained normal in the non-contact sports group. Conclusion: The salivary miRNAs are reliable biomarkers for concussion. Evidence Level II; Therapeutic Studies – Investigating the results.

[1]  M. Tan,et al.  Epigenetic modification of BDNF mediates neuropathic pain via miR-30a-3p/EP300 axis in CCI rats , 2020, Bioscience reports.

[2]  F. Middleton,et al.  Diagnosing mild traumatic brain injury using saliva RNA compared to cognitive and balance testing , 2020, Clinical and translational medicine.

[3]  Guoqiang Yu,et al.  N-hydroxy-N'-(4-butyl-2-methylphenyl)-formamidine attenuates oxygen-glucose deprivation and reoxygenation-induced cerebral ischemia-reperfusion injury via regulation of microRNAs. , 2020, Journal of integrative neuroscience.

[4]  F. Middleton,et al.  The Transcriptional Signature of a Runner’s High , 2019, Medicine and science in sports and exercise.

[5]  H. Goodkin,et al.  Investigating the effects of subconcussion on functional connectivity using mass-univariate and multivariate approaches , 2018, Brain Imaging and Behavior.

[6]  Peter Seidenberg,et al.  The effect of repetitive subconcussive collisions on brain integrity in collegiate football players over a single football season: A multi-modal neuroimaging study , 2017, NeuroImage: Clinical.

[7]  Elizabeth M Davenport,et al.  Subconcussive Head Impact Exposure and White Matter Tract Changes over a Single Season of Youth Football. , 2016, Radiology.

[8]  K. Tanriverdi,et al.  Circulating MicroRNAs as Potential Biomarkers for Traumatic Brain Injury-Induced Hypopituitarism. , 2016, Journal of neurotrauma.

[9]  L. Papa Potential Blood-based Biomarkers for Concussion , 2016, Sports medicine and arthroscopy review.

[10]  L. Papa,et al.  A Panel of Serum MiRNA Biomarkers for the Diagnosis of Severe to Mild Traumatic Brain Injury in Humans , 2016, Scientific Reports.

[11]  S. Silvestri,et al.  Performance of Glial Fibrillary Acidic Protein in Detecting Traumatic Intracranial Lesions on Computed Tomography in Children and Youth With Mild Head Trauma. , 2015, Academic emergency medicine : official journal of the Society for Academic Emergency Medicine.

[12]  L. Papa,et al.  Systematic review of clinical studies examining biomarkers of brain injury in athletes after sports-related concussion. , 2015, Journal of neurotrauma.

[13]  M. Hallett,et al.  Effects of subconcussive head trauma on the default mode network of the brain. , 2014, Journal of neurotrauma.

[14]  T. Talavage,et al.  Role of subconcussion in repetitive mild traumatic brain injury A review , 2013 .

[15]  N. Wu,et al.  Circulating MicroRNAs: A Novel Class of Potential Biomarkers for Diagnosing and Prognosing Central Nervous System Diseases , 2013, Cellular and Molecular Neurobiology.

[16]  R. Berger,et al.  Systematic review of clinical research on biomarkers for pediatric traumatic brain injury. , 2013, Journal of neurotrauma.

[17]  G. Solomon,et al.  Prevalence of invalid computerized baseline neurocognitive test results in high school and collegiate athletes. , 2012, Journal of athletic training.

[18]  R. McCarron,et al.  MicroRNA let-7i is a promising serum biomarker for blast-induced traumatic brain injury. , 2012, Journal of neurotrauma.

[19]  Philip Schatz,et al.  Group Versus Individual Administration Affects Baseline Neurocognitive Test Performance , 2011, The American journal of sports medicine.

[20]  J. Bailes,et al.  Who should conduct and interpret the neuropsychological assessment in sports-related concussion? , 2009, British Journal of Sports Medicine.

[21]  S. Hicks,et al.  Association of Salivary MicroRNA Changes With Prolonged Concussion Symptoms , 2018, JAMA pediatrics.

[22]  S. Hicks,et al.  Overlapping MicroRNA Expression in Saliva and Cerebrospinal Fluid Accurately Identifies Pediatric Traumatic Brain Injury. , 2018, Journal of neurotrauma.

[23]  PapaLinda,et al.  In Children and Youth with Mild and Moderate Traumatic Brain Injury, Glial Fibrillary Acidic Protein Out-Performs S100β in Detecting Traumatic Intracranial Lesions on Computed Tomography , 2016 .

[24]  J. Bailes,et al.  Cumulative effects of repetitive mild traumatic brain injury. , 2014, Progress in neurological surgery.

[25]  Brandon E Gavett,et al.  Chronic traumatic encephalopathy: a potential late effect of sport-related concussive and subconcussive head trauma. , 2011, Clinics in sports medicine.