Molecular biomarkers of diffuse axonal injury: recent advances and future perspectives.

INTRODUCTION: Diffuse axonal injury (DAI), with high mortality and morbidity both in children and adults, is one of the most severe pathological consequences of traumatic brain injury. Currently, clinical diagnosis, disease assessment, disability identification, and postmortem diagnosis of DAI is mainly limited by the absent of specific molecular biomarkers. AREAS COVERED: In this review, we first introduce the pathophysiology of DAI, summarized the reported biomarkers in previous animal and human studies, and then the molecular biomarkers such as ß-Amyloid precursor protein, neurofilaments, S-100ß, myelin basic protein, tau protein, neuron-specific enolase, Peripherin and Hemopexin for DAI diagnosis is summarized. Finally, we put forward valuable views on the future research direction of diagnostic biomarkers of DAI. EXPERT OPINION: In recent years, the advanced technology has ultimately changed the research of DAI, and the numbers of potential molecular biomarkers was introduced in related studies. We summarized the latest updated information in such studies to provide references for future research and explore the potential pathophysiological mechanism on diffuse axonal injury.

[Morphological markers of pathophysiological changes in the neuronal processes in the acute post-traumatic period of diffuse axonal injury]. / Morfologicheskie markery patofiziologicheskikh izmenenii otrostkov neironov v ostrom posttravmaticheskom periode diffuznogo aksonal'nogo povrezhdeniya mozga.

The purpose of the study was to establish morphological markers of pathophysiological changes in the neuronal processes of in the acute (up to 36 hours) post-traumatic period of diffuse axonal injury (DAI) for the purposes of expert practice. Histological examination of the body of corpus callosum of the corpses of 66 persons dead from DAI and of 25 persons dead from various non-violent and violent causes, excluding head trauma, was performed (control group). Morphological markers of specific pathophysiological changes in the neuronal process were established by light microscopy with the use of immunohistochemical examination in acute period DAI. Uneven contours of the processes suggested displacement of cytoskeletal elements, areas of vacuolization of the cytoplasm of the processes suggested violation of intracellular transport caused by a change of permeability with preserved integrity of the process shell without mechanical separation of the process, uneven thickness (3.9 ± 1.6 µm) of the processes, varicose and cone-shaped thickening of them was a manifestation of focal edema of the neuronal process and compression of the cytoskeleton as a result of ion-enzymatic disorders, uneven coloration, areas of fragmentary compaction of neurofilaments indicated the zones of deformation and compression of the cytoskeleton, zones of granular-lumpy decay and fibrillolysis of neurofilaments indicated destruction of the cytoskeleton. Changes in the neuronal processes are a manifestation of a polyethological general pathological process and are not a differential diagnostic criterion of DAI.

Axons-on-a-chip for mimicking non-disruptive diffuse axonal injury underlying traumatic brain injury.

Diffuse axonal injury (DAI) is the most severe pathological feature of traumatic brain injury (TBI). However, how primary axonal injury is induced by transient mechanical impacts remains unknown, mainly due to the low temporal and spatial resolution of medical imaging approaches. Here we established an axon-on-a-chip (AoC) model for mimicking DAI and monitoring instant cellular responses. Integrating computational fluid dynamics and microfluidic techniques, DAI was induced by injecting a precisely controlled micro-flux in the transverse direction. The clear correlation between the flow speed of injecting flux and the severity of DAI was elucidated. We next used the AoC to investigate the instant intracellular responses underlying DAI and found that the dynamic formation of focal axonal swellings (FAS) accompanied by Ca2+ surge occurs during the flux. Surprisingly, periodic axonal cytoskeleton disruption also occurs rapidly after the flux. These instant injury responses are spatially restricted to the fluxed axon, not affecting the overall viability of the neuron in the acute stage. Compatible with high-resolution live microscopy, the AoC provides a versatile system to identify early mechanisms underlying DAI, offering a platform for screening effective treatments to alleviate TBI.

[Expert errors in formulating a forensic diagnosis and conclusions in cases of diffuse axonal brain damage]. / Ekspertnye oshibki pri formulirovanii sudebno-meditsinskogo diagnoza i vyvodov v sluchayakh diffuznogo aksonal'nogo povrezhdeniya mozga.

The study objective is to review expert errors in the wording of a post-mortem diagnosis and expert conclusions in cases of traumatic brain injury with diffuse axonal brain damage. We reviewed 50 corpse examinations of those who died from a traumatic brain injury with diffuse axonal brain damage. A retrospective analysis of the results of expert examinations, the structure of the post-mortem forensic diagnosis, and the validity of expert conclusions showed that expert errors were made in 30% of cases. In 93% of cases, the errors were epistemological due to the lack of a scientifically based methodological approach to the expert opinion on a particular mechanism for the development of traumatic brain injury with diffuse axonal brain damage; and lack of professional expertise. A case is provided demonstrating the most common expert errors in the examination of this type of traumatic brain injury.

UPLC/Q-TOF MS-Based Urine Metabonomics Study to Identify Diffuse Axonal Injury Biomarkers in Rat.

Diffuse axonal injury (DAI) represents a frequent traumatic brain injury (TBI) type, significantly contributing to the dismal neurological prognosis and high mortality in TBI patients. The increase in mortality can be associated with delayed and nonspecific initial symptoms in DAI patients. Additionally, the existing approaches for diagnosis and monitoring are either low sensitivity or high cost. Therefore, novel, reliable, and objective diagnostic markers should be developed to diagnose and monitor DAI prognosis. Urine is an optimal sample to detect biomarkers for DAI noninvasively. Therefore, the DAI rat model was established in this work. Meanwhile, the ultraperformance liquid chromatography quadrupole-time-of-flight hybrid mass spectrometry- (UPLC/Q-TOF MS-) untargeted metabolomics approach was utilized to identify the features of urine metabolomics to diagnose DAI. This work included 57 metabolites with significant alterations and 21 abnormal metabolic pathways from the injury groups. Three metabolites, viz., urea, butyric acid, and taurine, were identified as possible biomarkers to diagnose DAI based on the great fold changes (FCs) and biological functions during DAI. The present study detected several novel biomarkers for noninvasively diagnosing and monitoring DAI and helped understand the DAI-associated metabolic events.

[Problems of forensic diagnosis of diffuse axonal brain injury in the acute post-traumatic period]. / Problemy sudebno-meditsinskoi diagnostiki ostrogo perioda diffuznogo aksonal'nogo povrezhdeniya golovnogo mozga.

The article refers to actual problems of forensic diagnostics of diffuse axonal brain injury in the acute post-traumatic period, that is of particular importance in the case of head trauma in conditions of non-evidence. To solve the existing problems, it is necessary to conduct a comprehensive study aimed at improving the diffuse axonal brain injury examination by developing a unified methodological approach to running the forensic medical diagnostics of this form of traumatic brain injury and determining the duration of the acute (up to three days) post-traumatic period.

[Methodology for forensic diagnosis of diffuse axonal injury]. / Metodologiya sudebno-meditsinskoi diagnostiki diffuznogo aksonal'nogo povrezhdeniya golovnogo mozga.

An original methodological approach for forensic diagnostics of diffuse axonal injury (DAI) was developed based on the comprehensive study results. The approach is based on the algorithm of expert actions, including utilizing the developed rational methods set to identify pathognomonic morphological features using accessible and effective histological techniques. Also, the approach includes ways of analysis and estimation of these features. The proposed methodological approach aims to provide an objective diagnosis of this type of traumatic brain injury (TBI) and establish the age of its acute post-traumatic period. The known and generally accepted definitions of DAI and TBI are clarified.

Toward a Comprehensive Delineation of White Matter Tract-Related Deformation.

Finite element (FE) models of the human head are valuable instruments to explore the mechanobiological pathway from external loading, localized brain response, and resultant injury risks. The injury predictability of these models depends on the use of effective criteria as injury predictors. The FE-derived normal deformation along white matter (WM) fiber tracts (i.e., tract-oriented strain) recently has been suggested as an appropriate predictor for axonal injury. However, the tract-oriented strain only represents a partial depiction of the WM fiber tract deformation. A comprehensive delineation of tract-related deformation may improve the injury predictability of the FE head model by delivering new tract-related criteria as injury predictors. Thus, the present study performed a theoretical strain analysis to comprehensively characterize the WM fiber tract deformation by relating the strain tensor of the WM element to its embedded fiber tract. Three new tract-related strains with exact analytical solutions were proposed, measuring the normal deformation perpendicular to the fiber tracts (i.e., tract-perpendicular strain), and shear deformation along and perpendicular to the fiber tracts (i.e., axial-shear strain and lateral-shear strain, respectively). The injury predictability of these three newly proposed strain peaks along with the previously used tract-oriented strain peak and maximum principal strain (MPS) were evaluated by simulating 151 impacts with known outcome (concussion or non-concussion). The results preliminarily showed that four tract-related strain peaks exhibited superior performance than MPS in discriminating concussion and non-concussion cases. This study presents a comprehensive quantification of WM tract-related deformation and advocates the use of orientation-dependent strains as criteria for injury prediction, which may ultimately contribute to an advanced mechanobiological understanding and enhanced computational predictability of brain injury.

Expression of orexin-A (hypocretin-A) in the hypothalamus after traumatic brain injury: A postmortem evaluation.

Traumatic brain injury (TBI) is one of the leading causes of mortality and morbidity. The key component of TBI pathophysiology is traumatic axonal injury (TAI), commonly referred to as diffuse axonal injury (DAI). Coma is a serious complication which can occur following traumatic brain injury (TBI). Recently, studies have shown that the central orexinergic/ hypocretinergic system exhibit prominent arousal promoting actions. Therefore, the purpose of this study is to investigate by immunohistochemistry the expression of beta-amyloid precursor protein (ß-APP) in white matter of parasagittal region, corpus callosum and brainstem and the expression of orexin-A (ORXA) in the hypothalamus after traumatic brain injury. RESULTS: DAI was found in 26 (53.06%) cases, assessed with ß-APP immunohistochemical staining in parasagittal white matter, corpus callosum and brainstem. Orexin-A immunoreactivity in hypothalamus was completely absent in 5 (10.2%) of the cases; moderate reduction of ORXA was observed in 9 (18.4%) of the cases; and severe reduction was observed in 7 (14.3%) of the cases. A statistically significant correlation was found between ß-APP immunostaining in white matter, corpus callosum and brainstem in relation to survival time (p < 0.002, p < 0.003 and p < 0.005 respectively). A statistically positive correlation was noted between ORX-A immunoreactivity in hypothalamus to survival time (p < 0.003). An inverse correlation was noted between the expression of ß-APP in the regions of brain studied to the expression of ORX-A in the hypothalamus of the cases studied (p < 0.005). CONCLUSIONS: The present study demonstrated by immunohistochemistry that reduction of orexin-A neurons in the hypothalamus, involved in coma status and arousal, enhanced the immunoexpression of ß-APP in parasagital white matter, corpus callosum and brainstem.

[Diagnostic mistakes in diffuse axonal brain injury]. / Oshibki pri diagnostike diffuznogo aksonal'nogo povrezhdeniya mozga.

Based on the study results it were identified and systematized the most common deficiencies and mistakes that negatively affect the diagnosis of diffuse axonal brain injury and its genesis detection in the early post-traumatic period. It makes possible to organize correctly the diagnostic process and prevent an erroneous assessment of morphological changes in the brain during the examination of traumatic brain injury.

Combination of Neutrophil-to-Lymphocyte Ratio and Admission Glasgow Coma Scale Score Is Independent Predictor of Clinical Outcome in Diffuse Axonal Injury.

BACKGROUND: The neutrophil-to-lymphocyte ratio (NLR) is an independent predictor of clinical outcome of different diseases, such as acute ischemic stroke, intracerebral hemorrhage, malignant tumor, and traumatic brain injury. However, the prognostic value of NLR plus admission Glasgow Coma Scale score (NLR-GCS) is still unclear in patients with diffuse axonal injury (DAI). Therefore this study assessed the relationship between the NLR-GCS and 6-month outcome of DAI patients. METHODS: The clinical characteristics of DAI patients admitted to our department between January 2014 and January 2020 were retrospectively analyzed. The candidate risk factors were screened by using univariate analysis, and the independence of resultant risk factors was evaluated by the binary logistic regression analysis and least absolute shrinkage and selection operator regression analysis. The predictive value of NLR-GCS in an unfavorable outcome was assessed by the receiver operating characteristics curve analysis. RESULTS: A total of 93 DAI patients were included. Binary logistic regression analysis and least absolute shrinkage and selection operator regression analysis showed the level of NLR on admission was an independent risk factor of unfavorable outcomes in DAI patients. The ROC curve analysis showed that the predictive capacity of the combination of NLR and admission GCS score and combination of NLR and coma duration outperformed NLR, admission GCS score, and coma duration alone. CONCLUSIONS: The higher NLR level on admission is independently associated with unfavorable outcomes of DAI patients at 6 months. Furthermore, the combination of NLR and admission GCS score provides the superior predictive capacity to either NLR or GCS alone.

[Postmortem diagnostic of diffuse axonal injury considering histoarchitectonic of the corpus callosum]. / Posmertnaya diagnostika diffuznogo aksonal'nogo povrezhdeniya s uchetom gistoarkhitektoniki mozolistogo tela.

The results of studying the morphological signs of diffuse axonal injury (DAI) postmortem diagnosis in the brain are presented. It was investigated the histoarchitectonics of the corpus callosum in various types of non-violent and violent death. In the indusium griseum of the corpus callosum, neurons were identified; the features of the morphology and the interposition of the neurons processes, glia and vessels in various parts of the corpus callosum were studied. Taking into account the revealed architectonics of the corpus callosum, changes in DAI were determined. It was found that the main diagnostically significant morphological sign of DAI is hemorrhages localized in the trunk and indusium griseum on sagittal corpus callosum sections, which may be important in solving expert questions about the morphogenesis of hemorrhages in the corpus callosum.

Serum levels of tau protein increase according to the severity of the injury in DAI rat model.

Traumatic brain injury (TBI) in the form of diffuse axonal injury (DAI) is difficult to diagnose in the early phase of the injury. Early diagnosis of DAI may provide opportunity for developing treatment and management strategies. Tau protein has been demonstrated to increase in the early phase of TBI with high diagnostic accuracy in patients with DAI. We tested the biological plausibility of tau protein using a rat DAI model by evaluating the association between serum tau levels and the severity of brain injury. DAI was induced in animals using the Marmarou model. After a survival of 60 minutes, rats were anesthetized and sacrificed after obtaining blood samples (5ml) from the heart. Eighteen rats were employed in the present study and were randomly subjected to sham-operated control (n=4), mild DAI (n=7), and severe DAI (n=7). Of seven severe DAI rats, two rats that had focal injury caused by skull fracture were excluded in the measurement of tau protein level. The serum levels of tau protein in the rat DAI model were found to increase significantly and consistently according to the severity of the injury. Rats with DAI showed significantly higher serum levels of tau protein compared to sham rats; the severe DAI rats had higher levels of tau than moderate DAI and sham rats (sham vs. mild,  P=0.02; mild vs. severe,  P=0.02). In conclusion, serum tau protein levels may be useful as a biomarker for diagnosing and estimating the severity of DAI in the early phase.

[Application of immunohistochemical study for the verification of diffuse axonal injury and determination of cause-and-effect relationships]. / Primenenie immunogistokhimicheskogo issledovaniia dlia verifikatsii diffuznogo aksonal'nogo povrezhdeniia i ustanovleniia prichinno-sledstvennykh sviazei.

Aim of this study is to establish a possibility of finding morphologic signs of diffuse axonal injury early after the injury. Use of immunohistochemical examination of the brain to detect protein ß-APP made it possible not only to diagnose this condition correctly, but also to reasonably and categorically answer the question of a causal relationship between causing damage and the onset of death.

iTRAQ-based proteomic analysis discovers potential biomarkers of diffuse axonal injury in rats.

Diffuse axonal injury (DAI) is one of the most common and severe pathological consequences of traumatic brain injury (TBI). The molecular mechanism of DAI is highly complicated and still elusive, yet a clear understanding is crucial for the diagnosis, treatment, and prognosis of DAI. In our study, we used rats to establish a DAI model and applied isobaric tags for relative and absolute quantitation (iTRAQ) coupled with liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis to identify differentially expressed proteins (DEPs) in the corpus callosum. As a result, a total of 514 proteins showed differential expression between the injury groups and the control. Among these DEPs, 14 common DEPs were present at all seven time points postinjury (1, 3, 6, 12, 24, 48, and 72 h). Next, bioinformatic analysis was performed to elucidate the pathogenesis of DAI, which was found to possibly involve calcium ion-regulatory proteins (e.g., calsenilin and ryanodine receptor 2), cytoskeleton organization (e.g., peripherin, NFL, NFM, and NFH), apoptotic processes (e.g., calsenilin and protein kinase C delta type), and inflammatory response proteins (e.g., complement C3 and C-reactive protein). Moreover, peripherin and calsenilin were successfully confirmed by western blotting to be significantly upregulated during DAI, and immunohistochemical (IHC) analysis revealed that their expression increased and could be observed in axons after injury, thus indicating their potential as DAI biomarkers. Our experiments not only provide insight into the molecular mechanisms of axonal injury in rats during DAI but also give clinicians and pathologists important reference data for the diagnosis of DAI. Our findings may expand the list of DAI biomarkers and improve the postmortem diagnostic rate of DAI.

Tau protein as a diagnostic marker for diffuse axonal injury.

BACKGROUND: Diffuse axonal injury (DAI) is difficult to identify in the early phase of traumatic brain injury (TBI) using common diagnostic methods. Tau protein is localized specifically in nerve axons. We hypothesized that serum level of tau can be a useful biomarker to diagnose DAI in the early phase of TBI. METHODS & RESULTS: We measured serum tau levels in 40 TBI patients who were suspected of DAI within 6 hours after TBI to evaluate the accuracy of the tau level as a diagnostic marker for DAI. Diagnosis of DAI was confirmed according to magnetic resonance imaging (MRI) findings. The serum tau level in the DAI group (n = 13) was significantly higher than that in the non-DAI group (n = 27) (DAI vs. non-DAI, 25.3 [0 to 99.1] pg/mL vs. 0 [0 to 44.4] pg/mL, P = 0.03)). A receiver-operating characteristic curve to evaluate the diagnostic ability of serum tau level within 6 hours for DAI showed an area under the curve of 0.690 with 74.1% for sensitivity and 69.2% for specificity. Serum tau level was not significantly higher in unfavorable outcome group (Glasgow Outcome scale [GOS] score = 1-3 at hospital discharge) compared with favorable outcome group (GOS score = 4-5) (P = 0.19). CONCLUSIONS: Tau protein may be a useful biomarker for diagnosis of DAI in the early phase of TBI.

Integrated Proteomics and Metabolomic Analyses of Plasma Injury Biomarkers in a Serious Brain Trauma Model in Rats.

Diffuse axonal injury (DAI) is a prevalent and serious brain injury with significant morbidity and disability. However, the underlying pathogenesis of DAI remains largely unclear, and there are still no objective laboratory-based tests available for clinicians to make an early diagnosis of DAI. An integrated analysis of metabolomic data and proteomic data may be useful to identify all of the molecular mechanisms of DAI and novel potential biomarkers. Therefore, we established a rat model of DAI, and applied an integrated UPLC-Q-TOF/MS-based metabolomics and isobaric tag for relative and absolute quantitation (iTRAQ)-based proteomic analysis to obtain unbiased profiling data. Differential analysis identified 34 metabolites and 43 proteins in rat plasma of the injury group. Two metabolites (acetone and 4-Hydroxybenzaldehyde) and two proteins (Alpha-1-antiproteinase and Alpha-1-acid glycoprotein) were identified as potential biomarkers for DAI, and all may play important roles in the pathogenesis of DAI. Our study demonstrated the feasibility of integrated metabolomics and proteomics method to uncover the underlying molecular mechanisms of DAI, and may help provide clinicians with some novel diagnostic biomarkers and therapeutic targets.

Histopathology mapping of biochemical changes in diffuse axonal injury by FTIR micro-spectroscopy.

The diagnosis of diffuse axonal injury (DAI) is an important task in forensic pathology and clinical medicine. This study aimed to explore the use of Fourier transform infrared spectroscopy (FTIR) to detect DAI. The DAI area of the rat model was detected point by point by the FTIR-mapping system. Infrared spectral data of DAI were obtained by selecting the amide A band, CH3 symmetric stretching, collagen triple-helix structure and asymmetric stretching vibrational frequency of nucleic acid and phospholipid PO2 as the target peak positions. The system can automatically draw infrared spectral color pathological images. In the DAI group, the amide A protein secondary amine N-H stretching vibration and the collagen triple-helix structure of the high-absorption area were consistent with the DAI area confirmed by the silver and ß-APP staining. The CH3 symmetric stretching, nucleic acid and phospholipid PO2 symmetric stretching vibration absorption spectra showed no significant differences between the experimental and verification groups. The FTIR-mapping technique can visually express the molecular characteristics of DAI, which is expected to be applied to the pathological diagnosis of DAI.