Your search keyword '"Joseph B. Long"' showing total 147 results

1. The effect of dietary omega-6 fatty acid enrichment in rodent models of military-relevant acute traumatic psychological stress and traumatic brain injury

Author

Matthew R. Rusling, James C. DeMar, Nabarun Chakraborty, Allison V. Hoke, Stacy Ann Miller, John G. Rosenberger, Andrew B. Batuure, Donna M. Wilder, Venkatasivasai Sujith Sajja, Joseph B. Long, Rasha Hammamieh, and Aarti Gautam

Subjects

omega-3, omega-6, microbiome, traumatic brain injury, post-traumatic stress disorder, linoleic acid, Microbial ecology, QR100-130

Abstract

IntroductionSequelae from traumatic brain injuries (TBIs) and post-traumatic stress disorder (PTSD) are major career-limiting factors for combat soldiers. Overlap between TBI and PTSD symptoms alongside other common comorbidities complicate the diagnosis and treatment. Systems-level and high-throughput approaches are key in understanding the underlying biomolecular mechanisms and differentiating these conditions.MethodsThe present study identifies dietary factors and proposes mechanisms behind psychological stress and TBI, using established preclinical animal models and a multi-omics approach. Here, we used microbiome characterizations of rats exposed to simulations of blast-induced TBI and underwater trauma (UWT)-induced psychological stress. We further studied the effect of dietary omega-6 versus omega-3 polyunsaturated fatty acid (n-6, n-3 PUFA) enrichment on the insult responses. The use of excess n-6 PUFA was chosen due to its high prevalence in the Western diet and pro-inflammatory nature. Prior to TBI or UWT, animals were maintained for 6 weeks and continued thereafter on either a standard diet or two customized chows imbalanced and diminished in omega-3 content. Corresponding shams were carried out for all groups. Fecal bacterial microbiome populations were assessed using 16S rRNA gene sequencing.ResultsPhysiologic outcome modeling identified that dietary status affected post-TBI lactate dehydrogenase (LDH) and triglyceride levels, with n-3 PUFA having a large attenuating influence. The UWT model showed similar trends, with diet significantly altering LDH, terminal corticosterone (14 days post-exposure), and a fear behavior susceptibility. Fecal microbiome alpha diversity was significantly reduced by high levels of n-3 PUFA. Likewise, beta diversity of the microbiome was significantly affected by both diet and time but not exposure to TBI or UWT. Compositionally, temporal effects on the microbiome were more likely to be observed with the diets. The most affected features fell within the Proteobacteria phyla, in which n-3 PUFA enrichment significantly reduced Alphaproteobacteria in the TBI model and increased Gammaproteobacteria in the UWT group.DiscussionAll these observations can influence the vulnerability or resilience of the warfighter to blast-induced TBI and acute psychological stress. The microbiome mechanisms facilitate and provide a knowledge-driven unbiased panel of signatures to discriminate between the two insults and is an essential tool for designing precise care management.

Published

2024

2. Longitudinal Biochemical and Behavioral Alterations in a Gyrencephalic Model of Blast-Related Mild Traumatic Brain Injury

Author

Shiyu Tang, Su Xu, Donna Wilder, Alexandre E. Medina, Xin Li, Gary M. Fiskum, Li Jiang, Venkata R. Kakulavarapu, Joseph B. Long, Rao P. Gullapalli, and Venkatasivasai Sujith Sajja

Subjects

biochemical and behavioral alterations, ferret, in vivo magnetic resonance spectroscopy, mild TBI, primary blast, Medical emergencies. Critical care. Intensive care. First aid, RC86-88.9

Abstract

Blast-related traumatic brain injury (bTBI) is a major cause of neurological disorders in the U.S. military that can adversely impact some civilian populations as well and can lead to lifelong deficits and diminished quality of life. Among these types of injuries, the long-term sequelae are poorly understood because of variability in intensity and number of the blast exposure, as well as the range of subsequent symptoms that can overlap with those resulting from other traumatic events (e.g., post-traumatic stress disorder). Despite the valuable insights that rodent models have provided, there is a growing interest in using injury models using species with neuroanatomical features that more closely resemble the human brain. With this purpose, we established a gyrencephalic model of blast injury in ferrets, which underwent blast exposure applying conditions that closely mimic those associated with primary blast injuries to warfighters. In this study, we evaluated brain biochemical, microstructural, and behavioral profiles after blast exposure using in vivo longitudinal magnetic resonance imaging, histology, and behavioral assessments. In ferrets subjected to blast, the following alterations were found: 1) heightened impulsivity in decision making associated with pre-frontal cortex/amygdalar axis dysfunction; 2) transiently increased glutamate levels that are consistent with earlier findings during subacute stages post-TBI and may be involved in concomitant behavioral deficits; 3) abnormally high brain N-acetylaspartate levels that potentially reveal disrupted lipid synthesis and/or energy metabolism; and 4) dysfunction of pre-frontal cortex/auditory cortex signaling cascades that may reflect similar perturbations underlying secondary psychiatric disorders observed in warfighters after blast exposure.

Published

2024

3. Blast Exposure Induces Acute Alterations in Circadian Clock Genes in the Hypothalamus and Pineal Gland in Rats: An Exploratory Study

Author

Manoj Govindarajulu, Mital Y. Patel, Jishnu Krishnan, Joseph B. Long, and Peethambaran Arun

Subjects

blast injury, circadian rhythm, clock genes, hypocretin, hypothalamus, pineal gland, Medical emergencies. Critical care. Intensive care. First aid, RC86-88.9

Abstract

Blast-induced traumatic brain injury (bTBI) frequently results in sleep and circadian rhythm disturbances. We have investigated whether dysregulation of circadian rhythm after bTBI is mediated by dysregulation of clock genes in the hypothalamus and pineal gland of rats at acute (24?h) and chronic (1 month) time points post-blast. Expression of core circadian genes (Bmal1, Clock, Per1, Per2, Cry1, and Cry2) in the hypothalamus and pineal gland were quantified using quantitative real-time polymerase chain reaction. Hypocretin (Hcrt) and hypocretin receptor (Hcrtr1 and Hcrtr2) expression in the hypothalamus were also quantified along with plasma corticosterone levels. Blast-exposed rats showed a statistically significant increase in Bmal1 and decreases in Per1, Per2, and Cry2 in the pineal gland at 24?h post-blast in rats euthanized at night. In the hypothalamus, increases in Bmal1, Cry1, and Cry2 were noted along with decreases in Per1 and Per2 gene expression at 24?h post-blast in rats euthanized at night. Except for Bmal1 in the hypothalamus, no statistically significant changes in expression of any of the clock genes were detected in the hypothalamus or pineal gland samples collected during daylight post-blast. In the hypothalamus, a decrease in Hcrt associated with increases in Hcrtr1 and Hcrtr2 were noted at 24?h post-blast in rats euthanized during daytime and nighttime. Increased plasma corticosterone was noted at 24?h post-blast in samples collected at night. No statistically significant changes in any of the core circadian genes?hypocretin, hypocretin receptors, or plasma corticosterone?were observed in the samples collected at 1 month post-blast injury. Blast exposure causes differential expression of core circadian genes in the hypothalamus and pineal gland during nighttime, along with dysregulation of hypocretin and its receptors, which might play a key role in the sleep disruptions associated with bTBI.

Published

2023

4. Differential effects on TDP-43, piezo-2, tight-junction proteins in various brain regions following repetitive low-intensity blast overpressure

Author

Lanier Heyburn, Shataakshi Dahal, Rania Abutarboush, Eileen Reed, Rodrigo Urioste, Andrew Batuure, Donna Wilder, Stephen T. Ahlers, Joseph B. Long, and Venkatasivasai Sujith Sajja

Subjects

relBOP, blast, TDP-43, piezo, tight junction proteins, Neurology. Diseases of the nervous system, RC346-429

Abstract

IntroductionMild traumatic brain injury (mTBI) caused by repetitive low-intensity blast overpressure (relBOP) in military personnel exposed to breaching and heavy weapons is often unrecognized and is understudied. Exposure to relBOP poses the risk of developing abnormal behavioral and psychological changes such as altered cognitive function, anxiety, and depression, all of which can severely compromise the quality of the life of the affected individual. Due to the structural and anatomical heterogeneity of the brain, understanding the potentially varied effects of relBOP in different regions of the brain could lend insights into the risks from exposures.MethodsIn this study, using a rodent model of relBOP and western blotting for protein expression we showed the differential expression of various neuropathological proteins like TDP-43, tight junction proteins (claudin-5, occludin, and glial fibrillary acidic protein (GFAP)) and a mechanosensitive protein (piezo-2) in different regions of the brain at different intensities and frequency of blast.ResultsOur key results include (i) significant increase in claudin-5 after 1x blast of 6.5 psi in all three regions and no definitive pattern with higher number of blasts, (ii) significant increase in piezo-2 at 1x followed by significant decrease after multiple blasts in the cortex, (iii) significant increase in piezo-2 with increasing number of blasts in frontal cortex and mixed pattern of expression in hippocampus and (iv) mixed pattern of TDP-3 and GFAP expression in all the regions of brain.DiscussionThese results suggest that there are not definitive patterns of changes in these marker proteins with increase in intensity and/or frequency of blast exposure in any particular region; the changes in expression of these proteins are different among the regions. We also found that the orientation of blast exposure (e.g. front vs. side exposure) affects the altered expression of these proteins.

Published

2023

5. A biomechanical-based approach to scale blast-induced molecular changes in the brain

Author

Jose E. Rubio, Dhananjay Radhakrishnan Subramaniam, Ginu Unnikrishnan, Venkata Siva Sai Sujith Sajja, Stephen Van Albert, Franco Rossetti, Andrew Frock, Giang Nguyen, Aravind Sundaramurthy, Joseph B. Long, and Jaques Reifman

Subjects

Medicine, Science

Abstract

Abstract Animal studies provide valuable insights on how the interaction of blast waves with the head may injure the brain. However, there is no acceptable methodology to scale the findings from animals to humans. Here, we propose an experimental/computational approach to project observed blast-induced molecular changes in the rat brain to the human brain. Using a shock tube, we exposed rats to a range of blast overpressures (BOPs) and used a high-fidelity computational model of a rat head to correlate predicted biomechanical responses with measured changes in glial fibrillary acidic protein (GFAP) in rat brain tissues. Our analyses revealed correlates between model-predicted strain rate and measured GFAP changes in three brain regions. Using these correlates and a high-fidelity computational model of a human head, we determined the equivalent BOPs in rats and in humans that induced similar strain rates across the two species. We used the equivalent BOPs to project the measured GFAP changes in the rat brain to the human. Our results suggest that, relative to the rat, the human requires an exposure to a blast wave of a higher magnitude to elicit similar brain-tissue responses. Our proposed methodology could assist in the development of safety guidelines for blast exposure.

Published

2022

6. Investigation of the direct and indirect mechanisms of primary blast insult to the brain

Author

Jose E. Rubio, Ginu Unnikrishnan, Venkata Siva Sai Sujith Sajja, Stephen Van Albert, Franco Rossetti, Maciej Skotak, Eren Alay, Aravind Sundaramurthy, Dhananjay Radhakrishnan Subramaniam, Joseph B. Long, Namas Chandra, and Jaques Reifman

Subjects

Medicine, Science

Abstract

Abstract The interaction of explosion-induced blast waves with the head (i.e., a direct mechanism) or with the torso (i.e., an indirect mechanism) presumably causes traumatic brain injury. However, the understanding of the potential role of each mechanism in causing this injury is still limited. To address this knowledge gap, we characterized the changes in the brain tissue of rats resulting from the direct and indirect mechanisms at 24 h following blast exposure. To this end, we conducted separate blast-wave exposures on rats in a shock tube at an incident overpressure of 130 kPa, while using whole-body, head-only, and torso-only configurations to delineate each mechanism. Then, we performed histopathological (silver staining) and immunohistochemical (GFAP, Iba-1, and NeuN staining) analyses to evaluate brain-tissue changes resulting from each mechanism. Compared to controls, our results showed no significant changes in torso-only-exposed rats. In contrast, we observed significant changes in whole-body-exposed (GFAP and silver staining) and head-only-exposed rats (silver staining). In addition, our analyses showed that a head-only exposure causes changes similar to those observed for a whole-body exposure, provided the exposure conditions are similar. In conclusion, our results suggest that the direct mechanism is the major contributor to blast-induced changes in brain tissues.

Published

2021

7. The Neurobehavioral Effects of Buprenorphine and Meloxicam on a Blast-Induced Traumatic Brain Injury Model in the Rat

Author

Laura M. Anderson, Sridhar Samineni, Donna M. Wilder, Marisela Lara, Ondine Eken, Rodrigo Urioste, Joseph B. Long, and Peethambaran Arun

Subjects

blast exposure, traumatic brain injury, neurobehavioral effects, analgesic, meloxicam, buprenorphine, Neurology. Diseases of the nervous system, RC346-429

Abstract

Previous findings have indicated that pain relieving medications such as opioids and non-steroidal anti-inflammatory drugs (NSAIDs) may be neuroprotective after traumatic brain injury in rodents, but only limited studies have been performed in a blast-induced traumatic brain injury (bTBI) model. In addition, many pre-clinical TBI studies performed in rodents did not use analgesics due to the possibility of neuroprotection or other changes in cognitive, behavioral, and pathology outcomes. To examine this in a pre-clinical setting, we examined the neurobehavioral changes in rats given a single pre-blast dose of meloxicam, buprenorphine, or no pain relieving medication and exposed to tightly-coupled repeated blasts in an advanced blast simulator and evaluated neurobehavioral functions up to 28 days post-blast. A 16.7% mortality rate was recorded in the rats treated with buprenorphine, which might be attributed to the physiologically depressive side effects of buprenorphine in combination with isoflurane anesthesia and acute brain injury. Rats given buprenorphine, but not meloxicam, took more time to recover from the isoflurane anesthesia given just before blast. We found that treatment with meloxicam protected repeated blast-exposed rats from vestibulomotor dysfunctions up to day 14, but by day 28 the protective effects had receded. Both pain relieving medications seemed to promote short-term memory deficits in blast-exposed animals, whereas vehicle-treated blast-exposed animals showed only a non-significant trend toward worsening short-term memory by day 27. Open field exploratory behavior results showed that blast exposed rats treated with meloxicam engaged in significantly more locomotor activities and possibly a lesser degree of responses thought to reflect anxiety and depressive-like behaviors than any of the other groups. Rats treated with analgesics to alleviate possible pain from the blast ate more than their counterparts that were not treated with analgesics, which supports that both analgesics were effective in alleviating some of the discomfort that these rats potentially experienced post-blast injury. These results suggest that meloxicam and, to a lesser extent buprenorphine alter a variety of neurobehavioral functions in a rat bTBI model and, because of their impact on these neurobehavioral changes, may be less than ideal analgesic agents for pre-clinical studies evaluating these neurobehavioral responses after TBI.

Published

2021

8. Blast Exposure Dysregulates Nighttime Melatonin Synthesis and Signaling in the Pineal Gland: A Potential Mechanism of Blast-Induced Sleep Disruptions

Author

Manoj Govindarajulu, Mital Y. Patel, Donna M. Wilder, Joseph B. Long, and Peethambaran Arun

Subjects

blast injury, circadian rhythm, melatonin, pineal gland, gene expression, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Blast-induced traumatic brain injury (bTBI) frequently results in sleep-wake disturbances. However, limited studies have investigated the molecular signaling mechanisms underlying these sleep disturbances, and potentially efficacious therapies are lacking. We investigated the levels of melatonin and genes involved in melatonin synthesis pathway in the pineal glands of Sprague Dawley rats exposed to single and tightly coupled repeated blasts during the night and daytime. Rats were exposed to single and tightly coupled repeated blasts using an advanced blast simulator. The plasma, cerebrospinal fluid (CSF), and pineal gland were collected at 6 h, 24 h, or 1 month postblast at two different time points: one during the day (1000 h) and one at night (2200 h). Differential expressions of genes involved in pineal melatonin synthesis were quantified using quantitative real-time polymerase chain reaction (qRT-PCR). Plasma and CSF melatonin levels were assessed using a commercial melatonin ELISA kit. The plasma and CSF melatonin levels showed statistically significant decreases at 6 h and 24 h in the blast-exposed rats euthanized in the night (in dim light), with no significant alterations noted in rats euthanized in the morning (daylight) at all three-time points. Blast-exposed rats showed statistically significant decreases in Tph1, Aanat, Asmt, and Mtnr1b mRNA levels, along with increased Tph2 mRNA, in the pineal gland samples collected at night at 6 h and 24 h. No significant changes in the mRNA levels of these genes were noted at 1 month. These findings imply that the melatonin circadian rhythm is disrupted following blast exposure, which may be a factor in the sleep disturbances that blast victims frequently experience.

Published

2022

9. A Methodology to Compare Biomechanical Simulations With Clinical Brain Imaging Analysis Utilizing Two Blunt Impact Cases

Author

X. Gary Tan, Venkata Siva Sai Sujith Sajja, Maria M. D’Souza, Raj K. Gupta, Joseph B. Long, Ajay K. Singh, and Amit Bagchi

Subjects

traumatic brain injury (TBI), computational, modeling and prediction, traffic accidents, magnetic resonance imaging (MRI), diffusion weighted imaging (DWI), Biotechnology, TP248.13-248.65

Abstract

According to the US Defense and Veterans Brain Injury Center (DVBIC) and Centers for Disease Control and Prevention (CDC), mild traumatic brain injury (mTBI) is a common form of head injury. Medical imaging data provides clinical insight into tissue damage/injury and injury severity, and helps medical diagnosis. Computational modeling and simulation can predict the biomechanical characteristics of such injury, and are useful for development of protective equipment. Integration of techniques from computational biomechanics with medical data assessment modalities (e.g., magnetic resonance imaging or MRI) has not yet been used to predict injury, support early medical diagnosis, or assess effectiveness of personal protective equipment. This paper presents a methodology to map computational simulations with clinical data for interpreting blunt impact TBI utilizing two clinically different head injury case studies. MRI modalities, such as T1, T2, diffusion-weighted imaging (DWI) and apparent diffusion coefficient (ADC), were used for simulation comparisons. The two clinical cases have been reconstructed using finite element analysis to predict head biomechanics based on medical reports documented by a clinician. The findings are mapped to simulation results using image-based clinical analyses of head impact injuries, and modalities that could capture simulation results have been identified. In case 1, the MRI results showed lesions in the brain with skull indentation, while case 2 had lesions in both coup and contrecoup sides with no skull deformation. Simulation data analyses show that different biomechanical measures and thresholds are needed to explain different blunt impact injury modalities; specifically, strain rate threshold corresponds well with brain injury with skull indentation, while minimum pressure threshold corresponds well with coup–contrecoup injury; and DWI has been found to be the most appropriate modality for MRI data interpretation. As the findings from these two cases are substantiated with additional clinical studies, this methodology can be broadly applied as a tool to support injury assessment in head trauma events and to improve countermeasures (e.g., diagnostics and protective equipment design) to mitigate these injuries.

Published

2021

10. Editorial: Neurosensory Alterations From Blast Exposure and Blunt Impact

Author

Venkatasivasaisujith Sajja, Joseph B. Long, and Catherine C. Tenn

Subjects

blast, blunt, neurosensory alterations, clinical, preclinical, computational, Neurology. Diseases of the nervous system, RC346-429

Published

2021

11. Blast Exposure Causes Long-Term Degeneration of Neuronal Cytoskeletal Elements in the Cochlear Nucleus: A Potential Mechanism for Chronic Auditory Dysfunctions

Author

Peethambaran Arun, Franco Rossetti, Donna M. Wilder, Ying Wang, Irene D. Gist, and Joseph B. Long

Subjects

blast exposure, cochlear nucleus, tinnitus, auditory dysfunction, degeneration of neuronal cytoskeletal elements, Neurology. Diseases of the nervous system, RC346-429

Abstract

Blast-induced auditory dysfunctions including tinnitus are the most prevalent disabilities in service members returning from recent combat operations. Most of the previous studies were focused on the effect of blast exposure on the peripheral auditory system and not much on the central auditory signal-processing regions in the brain. In the current study, we have exposed rats to single and tightly coupled repeated blasts and examined the degeneration of neuronal cytoskeletal elements using silver staining in the central auditory signal-processing regions in the brain at 24 h, 14 days, 1 month, 6 months, and 1 year. The brain regions evaluated include cochlear nucleus, lateral lemniscus, inferior colliculus, medial geniculate nucleus, and auditory cortex. The results obtained indicated that a significant increase in degeneration of neuronal cytoskeletal elements was observed only in the left and right cochlear nucleus. A significant increase in degeneration of neuronal cytoskeletal elements was observed in the cochlear nucleus at 24 h and persisted through 1 year, suggesting acute and chronic neuronal degeneration after blast exposure. No statistically significant differences were observed between single and repeated blasts. The localized degeneration of neuronal cytoskeletal elements in the cochlear nucleus suggests that the damage could be caused by transmission of blast shockwaves/noise through the ear canal and that use of suitable ear protection devices can protect against acute and chronic central auditory signal processing defects including tinnitus after blast exposure.

Published

2021

12. Repeated Low-Level Blast Acutely Alters Brain Cytokines, Neurovascular Proteins, Mechanotransduction, and Neurodegenerative Markers in a Rat Model

Author

Lanier Heyburn, Rania Abutarboush, Samantha Goodrich, Rodrigo Urioste, Andrew Batuure, Jaimena Wheel, Donna M. Wilder, Peethambaran Arun, Stephen T. Ahlers, Joseph B. Long, and Venkatasivasai Sujith Sajja

Subjects

blast wave-induced neurotrauma, blood-brain barrier, Piezo2 channel, TAR DNA-bindingprotein 43 (TDP-43), repetitive blast, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Exposure to the repeated low-level blast overpressure (BOP) periodically experienced by military personnel in operational and training environments can lead to deficits in behavior and cognition. While these low-intensity blasts do not cause overt changes acutely, repeated exposures may lead to cumulative effects in the brain that include acute inflammation, vascular disruption, and other molecular changes, which may eventually contribute to neurodegenerative processes. To identify these acute changes in the brain following repeated BOP, an advanced blast simulator was used to expose rats to 8.5 or 10 psi BOP once per day for 14 days. At 24 h after the final BOP, brain tissue was collected and analyzed for inflammatory markers, astrogliosis (GFAP), tight junction proteins (claudin-5 and occludin), and neurodegeneration-related proteins (Aβ40/42, pTau, TDP-43). After repeated exposure to 8.5 psi BOP, the change in cytokine profile was relatively modest compared to the changes observed following 10 psi BOP, which included a significant reduction in several inflammatory markers. Reduction in the tight junction protein occludin was observed in both groups when compared to controls, suggesting cerebrovascular disruption. While repeated exposure to 8.5 psi BOP led to a reduction in the Alzheimer’s disease (AD)-related proteins amyloid-β (Aβ)40 and Aβ42, these changes were not observed in the 10 psi group, which had a significant reduction in phosphorylated tau. Finally, repeated 10 psi BOP exposures led to an increase in GFAP, indicating alterations in astrocytes, and an increase in the mechanosensitive ion channel receptor protein, Piezo2, which may increase brain sensitivity to injury from pressure changes from BOP exposure. Overall, cumulative effects of repeated low-level BOP may increase the vulnerability to injury of the brain by disrupting neurovascular architecture, which may lead to downstream deleterious effects on behavior and cognition.

Published

2021

13. Antibodies Against Lysophosphatidic Acid Protect Against Blast-Induced Ocular Injuries

Author

Peethambaran Arun, Franco Rossetti, James C. DeMar, Ying Wang, Andrew B. Batuure, Donna M. Wilder, Irene D. Gist, Andrew J. Morris, Roger A. Sabbadini, and Joseph B. Long

Subjects

blast exposure, eye injury, ocular dysfunction, lysophosphatidic acid, anti-LPA antibody, rat, Neurology. Diseases of the nervous system, RC346-429

Abstract

Exposure to blast overpressure waves is implicated as the major cause of ocular injuries and resultant visual dysfunction in veterans involved in recent combat operations. No effective therapeutic strategies have been developed so far for blast-induced ocular dysfunction. Lysophosphatidic acid (LPA) is a bioactive phospholipid generated by activated platelets, astrocytes, choroidal plexus cells, and microglia and is reported to play major roles in stimulating inflammatory processes. The levels of LPA in the cerebrospinal fluid have been reported to increase acutely in patients with traumatic brain injury (TBI) as well as in a controlled cortical impact (CCI) TBI model in mice. In the present study, we have evaluated the efficacy of a single intravenous administration of a monoclonal LPA antibody (25 mg/kg) given at 1 h post-blast for protection against injuries to the retina and associated ocular dysfunctions. Our results show that a single 19 psi blast exposure significantly increased the levels of several species of LPA in blood plasma at 1 and 4 h post-blast. The anti-LPA antibody treatment significantly decreased glial cell activation and preserved neuronal cell morphology in the retina on day 8 after blast exposure. Optokinetic measurements indicated that anti-LPA antibody treatment significantly improved visual acuity in both eyes on days 2 and 6 post-blast exposure. Anti-LPA antibody treatment significantly increased rod photoreceptor and bipolar neuronal cell signaling in both eyes on day 7 post-blast exposure. These results suggest that blast exposure triggers release of LPAs, which play a major role promoting blast-induced ocular injuries, and that a single early administration of anti-LPA antibodies provides significant protection.

Published

2020

14. Blast Exposure Leads to Accelerated Cellular Senescence in the Rat Brain

Author

Peethambaran Arun, Franco Rossetti, Donna M. Wilder, Sujith Sajja, Stephen A. Van Albert, Ying Wang, Irene D. Gist, and Joseph B. Long

Subjects

blast exposure, traumatic brain injury, aging, senescence, SA-β-gal, SMP-30, Neurology. Diseases of the nervous system, RC346-429

Abstract

Blast-induced traumatic brain injury (bTBI) is one of the major causes of persistent disabilities in Service Members, and a history of bTBI has been identified as a primary risk factor for developing age-associated neurodegenerative diseases. Clinical observations of several military blast casualties have revealed a rapid age-related loss of white matter integrity in the brain. In the present study, we have tested the effect of single and tightly coupled repeated blasts on cellular senescence in the rat brain. Isoflurane-anesthetized rats were exposed to either a single or 2 closely coupled blasts in an advanced blast simulator. Rats were euthanized and brains were collected at 24 h, 1 month and 1 year post-blast to determine senescence-associated-β-galactosidase (SA-β-gal) activity in the cells using senescence marker stain. Single and repeated blast exposures resulted in significantly increased senescence marker staining in several neuroanatomical structures, including cortex, auditory cortex, dorsal lateral thalamic nucleus, geniculate nucleus, superior colliculus, ventral thalamic nucleus and hippocampus. In general, the increases in SA-β-gal activity were more pronounced at 1 month than at 24 h or 1 year post-blast and were also greater after repeated than single blast exposures. Real-time quantitative RT-PCR analysis revealed decreased levels of mRNA for senescence marker protein-30 (SMP-30) and increased mRNA levels for p21 (cyclin dependent kinase inhibitor 1A, CDKN1A), two other related protein markers of cellular senescence. The increased senescence observed in some of these affected brain structures may be implicated in several long-term sequelae after exposure to blast, including memory disruptions and impairments in movement, auditory and ocular functions.

Published

2020

15. Repeated mild blast exposure in young adult rats results in dynamic and persistent microstructural changes in the brain

Author

Alexandra Badea, Alaa Kamnaksh, Robert J. Anderson, Evan Calabrese, Joseph B. Long, and Denes V. Agoston

Subjects

Computer applications to medicine. Medical informatics, R858-859.7, Neurology. Diseases of the nervous system, RC346-429

Abstract

A history of mild traumatic brain injury (mTBI), particularly repeated mTBI (rmTBI), has been identified as a risk factor for late-onset neurodegenerative conditions. The mild and transient nature of early symptoms often impedes diagnosis in young adults who are disproportionately affected by mTBIs. A proportion of the affected population will incur long-term behavioral and cognitive consequences but the underlying pathomechanism is currently unknown. Diffusion tensor imaging (DTI) provides sensitive and quantitative assessment of TBI-induced structural changes, including white matter injury, and may be used to predict long-term outcome. We used DTI in an animal model of blast rmTBI (rmbTBI) to quantify blast-induced structural changes at 7 and 90 days post-injury, and their evolution between the two time points. Young adult male rats (~P65 at injury) were exposed to repeated mild blast overpressure, or anesthetized as shams, and their fixed brains were imaged using high-field (7 T) MRI. We found that whole brain volumes similarly increased in injured and sham rats from 7 to 90 days. However, we detected localized volume increases in blast-exposed animals 7 days post-injury, mainly ipsilateral to incident blast waves. Affected regions included gray matter of the frontal association, cingulate, and motor cortex, thalamus, substantia nigra, and raphe nuclei (median and dorsal), as well as white matter of the internal capsule and cerebral peduncle. Conversely, we measured volume reductions in these and other regions, including the hippocampus and cerebellum, at 90 days post-injury. DTI also detected both transient and persistent microstructural changes following injury, with some changes showing distinct ipsilateral versus contralateral side differences relative to blast impact. Early changes in fractional anisotropy (FA) were subtle, becoming more prominent at 90 days in the cerebral and inferior cerebellar peduncles, and cerebellar white matter. Widespread increases in radial diffusivity (RD) and axial diffusivity (primary eigenvalue or E1) at 7 days post-injury largely subsided by 90 days, although RD was more sensitive than E1 at detecting white matter changes. E1 effects in gray and white matter, which paralleled increases in apparent diffusion, were likely more indicative of dysregulated water homeostasis than pathologic structural changes. Importantly, we found evidence for a different developmental trajectory following rmbTBI, as indicated by significant injury x age interactions on volume. Our findings demonstrate that rmbTBI initiates dynamic pathobiological processes that may negatively alter the course of late-stage neurodevelopment and adversely affect long-term cognitive and behavioral outcomes. Keywords: White matter injury, Neurodegeneration, Traumatic brain injury

Published

2018

16. The Role of Very Low Level Blast Overpressure in Symptomatology

Author

Venkata Siva Sai Sujith Sajja, Christina LaValle, Jonathan E. Salib, Anthony C. Misistia, Meron Y. Ghebremedhin, Alejandro N. Ramos, Michael Joseph Egnoto, Joseph B. Long, and Gary H. Kamimori

Subjects

sound pressure, blast, overpressure, mTBI, bTBI, symptomology, Neurology. Diseases of the nervous system, RC346-429

Abstract

Blast overpressure exposure has been linked to transient, but measurably deteriorated performance and symptomatologies in law enforcement and military personnel. Overlapping sub-concussive symptomatology associated with the very low level blast overpressures (vLLB) but high sound pressure (

Published

2019

17. Repeated Low-Level Blast Overpressure Leads to Endovascular Disruption and Alterations in TDP-43 and Piezo2 in a Rat Model of Blast TBI

Author

Lanier Heyburn, Rania Abutarboush, Samantha Goodrich, Rodrigo Urioste, Andrew Batuure, Jonathan Statz, Donna Wilder, Stephen T. Ahlers, Joseph B. Long, and Venkata Siva Sai Sujith Sajja

Subjects

blast-induced neurotrauma, blood-brain barrier, Piezo2, TDP-43, low-level blast, training relevant, Neurology. Diseases of the nervous system, RC346-429

Abstract

Recent evidence linking repeated low-level blast overpressure exposure in operational and training environments with neurocognitive decline, neuroinflammation, and neurodegenerative processes has prompted concern over the cumulative deleterious effects of repeated blast exposure on the brains of service members. Repetitive exposure to low-level primary blast may cause symptoms (subclinical) similar to those seen in mild traumatic brain injury (TBI), with progressive vascular and cellular changes, which could contribute to neurodegeneration. At the cellular level, the mechanical force associated with blast exposure can cause cellular perturbations in the brain, leading to secondary injury. To examine the cumulative effects of repetitive blast on the brain, an advanced blast simulator (ABS) was used to closely mimic “free-field” blast. Rats were exposed to 1–4 daily blasts (one blast per day, separated by 24 h) at 13, 16, or 19 psi peak incident pressures with a positive duration of 4–5 ms, either in a transverse or longitudinal orientation. Blood-brain barrier (BBB) markers (vascular endothelial growth factor (VEGF), occludin, and claudin-5), transactive response DNA binding protein (TDP-43), and the mechanosensitive channel Piezo2 were measured following blast exposure. Changes in expression of VEGF, occludin, and claudin-5 after repeated blast exposure indicate alterations in the BBB, which has been shown to be disrupted following TBI. TDP-43 is very tightly regulated in the brain and altered expression of TDP-43 is found in clinically-diagnosed TBI patients. TDP-43 levels were differentially affected by the number and magnitude of blast exposures, decreasing after 2 exposures, but increasing following a greater number of exposures at various intensities. Lastly, Piezo2 has been shown to be dysregulated following blast exposure and was here observed to increase after multiple blasts of moderate magnitude, indicating that blast may cause a change in sensitivity to mechanical stimuli in the brain and may contribute to cellular injury. These findings reveal that cumulative effects of repeated exposures to blast can lead to pathophysiological changes in the brain, demonstrating a possible link between blast injury and neurodegenerative disease, which is an important first step in understanding how to prevent these diseases in soldiers exposed to blast.

Published

2019

18. The Role of TDP-43 in Military-Relevant TBI and Chronic Neurodegeneration

Author

Lanier Heyburn, Venkata S. S. S. Sajja, and Joseph B. Long

Subjects

blast-induced brain injuries, TDP43 proteinopathy, frontotemporal lobar degeneration, TBI, Frontotemporal dementia (FTD), Neurology. Diseases of the nervous system, RC346-429

Abstract

Due largely to the use of improvised explosive devices (IEDs) and other explosives in recent military conflicts, blast-related TBI has emerged as a prominent injury sustained by warfighters. In the recent wars in Iraq and Afghanistan, traumatic brain injury (TBI) has been one of the most common types of injury sustained by soldiers and military personnel; of the ~380,000 TBIs reported in service members from 2000 to 2017, 82.3% were classified as mild (mTBI). While mTBI is associated with normal structural imaging, brief or no loss of consciousness, and rapid recovery of mental state, mTBI can nevertheless lead to persistent behavioral and cognitive effects. As in other cases of mTBI, exposure to low-level blast often does not cause immediate overt neurological effects, but may similarly lead to persistent behavioral and cognitive deficits. These effects are likely to be compounded when multiple exposures to blast and/or impact are sustained, since there is increasing evidence that multiple mTBIs can lead to chronic neurodegeneration. One common form of this deleterious outcome is frontotemporal lobar degeneration (FTLD), which is a progressive neurodegenerative process marked by atrophy of the frontal and temporal lobes, leading to frontotemporal dementia, a common form of dementia affecting behavior, cognition and language. About half of all cases of FTLD are marked by TAR-DNA binding protein (TDP-43)-positive protein inclusions. TDP-43, a DNA/RNA binding protein, controls the expression of thousands of genes and is associated with several neurodegenerative diseases including amyotrophic lateral sclerosis, Alzheimer's disease, Huntington's disease, and chronic traumatic encephalopathy. TDP-43 abnormalities have also been associated with traumatic brain injury in both pre-clinical and clinical studies. The role of TDP-43 in the manifestation of FTLD pathology in military TBI cases is currently unclear, and to date there has been only a limited number of pre-clinical studies addressing the effects of repeated blast-related mild TBI (rbTBI) in relation to FTLD and TDP-43. This review will summarize some of these findings and address the concerns and critical knowledge gaps associated with FTLD manifestation with military populations, as well as clinical findings on other forms of mTBI.

Published

2019

19. A Comparative Study of Two Blast-Induced Traumatic Brain Injury Models: Changes in Monoamine and Galanin Systems Following Single and Repeated Exposure

Author

Lizan Kawa, Alaa Kamnaksh, Joseph B. Long, Ulf P. Arborelius, Tomas Hökfelt, Denes V. Agoston, and Mårten Risling

Subjects

anxiety, catecholamines, dorsal raphe nucleus, locus coeruleus, animal models, neuropeptide, Neurology. Diseases of the nervous system, RC346-429

Abstract

Repeated mild blast-induced traumatic brain injury (rmbTBI), caused by recurrent exposure to low levels of explosive blast, is a significant concern for military health systems. However, the pathobiology of rmbTBI is currently poorly understood. Animal models are important tools to identify the molecular changes of rmbTBI, but comparisons across different models can present their own challenges. In this study, we compared two well-established rodent models of mbTBI, the “KI model” and the “USU/WRAIR model.” These two models create different pulse forms, in terms of peak pressure and duration. Following single and double exposures to mild levels of blast, we used in situ hybridization (ISH) to assess changes in mRNA levels of tyrosine hydroxylase (TH), tryptophan hydroxylase (TPH2), and galanin in the locus coeruleus (LC) and dorsal raphe nucleus (DRN). These systems and their transmitters are known to mediate responses to stress and anxiety. We found increased mRNA levels of TH, TPH2 and galanin in the LC and DRN of single-exposed rats relative to sham rats in the KI but not the USU/WRAIR model. Sham mRNA values measured in the USU/WRAIR model were substantially higher than their KI counterparts. Double exposure caused similarly significant increases in mRNA values in the KI model but not the USU/WRAIR model, except TPH2 and galanin levels in the DRN. We detected no cumulative effect of injury in either model at the used inter-injury interval (30 min), and there were no detectable neuropathological changes in any experimental group at 1 day post-injury. The apparent lack of early response to injury as compared to sham in the USU/WRAIR model is likely caused by stressors (e.g., transportation and noise), associated with the experimental execution, that were absent in the KI model. This study is the first to directly compare two established rodent models of rmbTBI, and to highlight the challenges of comparing findings from different animal models. Additional studies are needed to understand the role of stress, dissect the effects of psychological and physical injuries and to identify the window of increased cerebral vulnerability, i.e., the inter-injury interval that results in a cumulative effect following repeated blast exposure.

Published

2018

20. Stress and traumatic brain injury; a behavioral, proteomics and histological study

Author

Sook-Kyung C. Kwon, Erzsebet eKovesdi, Andrea B. Gyorgy, Daniel eWingo, Alaa eKamnaksh, John eWalker, Joseph B. Long, and Denes V. Agoston

Subjects

Anxiety, Gliosis, Inflammation, Memory, Neurogenesis, stress, Neurology. Diseases of the nervous system, RC346-429

Abstract

Psychological stress and traumatic brain injury (TBI) can both result in lasting neurobehavioral abnormalities. Post-traumatic stress disorder (PTSD) and blast induced TBI (bTBI) have become the most significant health issues in current military conflicts. Importantly, military bTBI virtually never occurs without stress. In this experiment, we assessed anxiety and spatial memory of rats at different time points after repeated exposure to stress alone or in combination with a single mild blast. At 2 months after injury or sham we analyzed the serum, prefrontal cortex (PFC), and hippocampus (HC) of all animals by proteomics and immunohistochemistry. Stressed sham animals showed an early increase in anxiety but no memory impairment at any measured time point. They had elevated levels of serum corticosterone (CORT) and hippocampal IL-6 but no other cellular or protein changes. Stressed injured animals had increased anxiety that returned to normal at 2 months and significant spatial memory impairment that lasted up to 2 months. They had elevated serum levels of CORT, CK-BB, NF-H, NSE, GFAP, and VEGF. Moreover, all of the measured protein markers were elevated in the HC and the PFC; rats had an increased number of TUNEL+ cells in the HC and elevated GFAP and Iba1 immunoreactivity in the HC and the PFC. Our findings suggest that exposure to repeated stress alone causes a transient increase in anxiety and no significant memory impairment or cellular and molecular changes. In contrast, repeated stress and blast results in lasting behavioral, molecular, and cellular abnormalities characterized by memory impairment, neuronal and glial cell loss, inflammation, and gliosis. These findings may have implications in the development of diagnostic and therapeutic measures for conditions caused by stress or a combination of stress and bTBI.

Published

2011

21. Traumatic Brain Injury - Pathobiology, Advanced Diagnostics and Acute Management.

Author

Joseph B. Long and Nikolai V. Gorbunov

Subjects

Health Sciences, Medicine, Mental and Behavioural Disorders and Diseases of the Nervous System, Neurology

Abstract

Summary: Traumatic brain injury (TBI) syndrome has emerged as a serious health concern worldwide due to the severity of outcomes and growing socioeconomic impacts of the diseases, e.g., high cost of long-term medical care and loss of quality of life. This book focuses on the TBI pathobiology as well as on the recent developments in advanced diagnostics and acute management. The presented topics encompass personal experience and visions of the chapter contributors as well as an extensive analysis of the TBI literature. The book is addressed to a broad audience of readers from students to practicing clinicians.

22. Behavioral Performance Characterization of the Putative Neuroinflammation Inhibitor 1-Methyl-Tryptophan Following Acute Traumatic Stress in Rats

Author

Rachel M. Taylor, Fred L. Johnson, Emily M. Scott, Aurian Naderi, Kacie M. McKinney, Kilana D. Coachman, Laurence P. Simmons, James C. DeMar, Peethambaran Arun, Joseph B. Long, Liana M. Matson, and Emily G. Lowery-Gionta

Published

2023

23. Soft-armor Vest Effectiveness and Intrathoracic Biomechanics in Rodents Exposed to Primary Blast

Author

Elizabeth M. McNeil, Michael J. Reilly, Donna M. Wilder, Meghan A. Benton, Joseph B. Long, and Venkata Siva Sai S. Sajja

Subjects

Biomedical Engineering

Published

2023

24. Phosphorylated Neurofilament Heavy Chain in the Cerebrospinal Fluid Is a Suitable Biomarker of Acute and Chronic Blast-Induced Traumatic Brain Injury

Author

Joseph B. Long, Ondine Eken, Ying Wang, Donna M. Wilder, Franco Rossetti, and Peethambaran Arun

Subjects

Male, Pathology, medicine.medical_specialty, Blast induced traumatic brain injury, Traumatic brain injury, Rats, Sprague-Dawley, Cerebrospinal fluid, Blast Injuries, Neurofilament Proteins, Brain Injuries, Traumatic, medicine, Animals, Phosphorylation, Neurofilament heavy chain, business.industry, Neurodegeneration, Brain, medicine.disease, Immunohistochemistry, Rats, Disease Models, Animal, Treatment Outcome, Biomarker (medicine), Neurology (clinical), Animal studies, business, Biomarkers

Abstract

Blast-induced traumatic brain injury (bTBI) has been documented as a significant concern for both military and civilian populations in response to the increased use of improvised explosive devices. Identifying biomarkers that could aid in the proper diagnosis and assessment of both acute and chronic bTBI is in urgent need since little progress has been made towards this goal. Addressing this knowledge gap is especially important in military veterans who are receiving assessment and care often years after their last blast exposure. Neuron-specific phosphorylated neurofilament heavy chain protein (pNFH) has been successfully evaluated as a reliable biomarker of different neurological disorders, as well as brain trauma resulting from contact sports and acute stages of brain injury of different origin. In the present study, we have evaluated the utility of pNFH levels measured in the cerebrospinal fluid (CSF) as an acute and chronic biomarker of brain injury resulting from single and tightly coupled repeated blast exposures using experimental rats. The pNFH levels increased at 24 h, returned to normal levels at 1 month, but increased again at 6 months and 1 year post-blast exposures. No significant changes were observed between single and repeated blast-exposed groups. To determine whether the observed increase of pNFH in CSF corresponded with its levels in the brain, we performed fluorescence immunohistochemistry in different brain regions at the four time-points evaluated. We observed decreased pNFH levels in those brain areas at 24 h, 6 months, and 1 year. The results suggest that blast exposure causes axonal degeneration at acute and chronic stages resulting in the release of pNFH, the abundant neuronal cytoskeletal protein. Moreover, the changes in pNFH levels in the CSF negatively correlated with the neurobehavioral functions in the rats, reinforcing suggestions that CSF levels of pNFH can be a suitable biomarker of bTBI.

Published

2021

25. Semimechanistic Modeling of the Effects of Blast Overpressure Exposure on Cefazolin Pharmacokinetics in Mice

Author

Daniel J. Selig, Stuart D. Tyner, Jesse P. DeLuca, Alexander G. Bobrov, Jeffrey R. Livezey, Brett E. Swierczewski, Derese Getnet, Geoffrey C. Chin, Venkatasivasai Sujith Sajja, Vlado Antonic, and Joseph B. Long

Subjects

Male, medicine.drug_class, Antibiotics, Cefazolin, Pharmacology, Models, Biological, Mice, Pharmacokinetics, Blast Injuries, Pressure, medicine, Animals, In patient, Dosing, Liver injury, Mice, Inbred BALB C, business.industry, Area under the curve, medicine.disease, Chemotherapy, Antibiotics, and Gene Therapy, Confidence interval, Anti-Bacterial Agents, Molecular Medicine, Chemical and Drug Induced Liver Injury, business, medicine.drug

Abstract

Cefazolin is a first-line antibiotic to treat infection related to deployment-associated blast injuries. Prior literature demonstrated a 331% increase cefazolin liver area under the curve (AUC) in mice exposed to a survivable blast compared with controls. We repeated the experiment, validated the findings, and established a semimechanistic two-compartment pharmacokinetic (PK) model with effect compartments representing the liver and skin. We found that blast statistically significantly increased the pseudo–partition coefficient to the liver by 326% (95% confidence interval: 76–737%), which corresponds to the observed 331% increase in cefazolin liver AUC described previously. To a lesser extent, plasma AUC in blasted mice increased 14–45% compared with controls. Nevertheless, the effects of blast on cefazolin PK were transient, normalizing by 10 hours after the dose. It is unclear as to how this blast effect t emporally translates to humans; however, given the short-lived effect on PK, there is insufficient evidence to recommend cefazolin dosing changes based on blast overpressure injury alone. Clinicians should be aware that cefazolin may cause drug-induced liver injury with a single dose and the risk may be higher in patients with blast overpressure injury based on our findings. SIGNIFICANCE STATEMENT Blast exposure significantly, but transiently, alters cefazolin pharmacokinetics in mice. The questions of whether other medications or potential long-term consequences in humans need further exploration.

Published

2021

26. Investigation of the direct and indirect mechanisms of primary blast insult to the brain

Author

Joseph B. Long, Venkata Siva Sai Sujith Sajja, Aravind Sundaramurthy, Jose E. Rubio, Maciej Skotak, Jaques Reifman, Eren Alay, Stephen Van Albert, Ginu Unnikrishnan, Dhananjay Radhakrishnan Subramaniam, Namas Chandra, and Franco Rossetti

Subjects

Male, Pathology, medicine.medical_specialty, Traumatic brain injury, Science, Blast exposure, Brain tissue, Brain injuries, Article, Rats, Sprague-Dawley, Silver stain, Blast Injuries, Brain Injuries, Traumatic, Pressure, medicine, Animals, Multidisciplinary, biology, Chemistry, Mechanism (biology), Brain, medicine.disease, Rats, Staining, Disease Models, Animal, biology.protein, Immunohistochemistry, Medicine, sense organs, NeuN, Neuroscience

Abstract

The interaction of explosion-induced blast waves with the head (i.e., a direct mechanism) or with the torso (i.e., an indirect mechanism) presumably causes traumatic brain injury. However, the understanding of the potential role of each mechanism in causing this injury is still limited. To address this knowledge gap, we characterized the changes in the brain tissue of rats resulting from the direct and indirect mechanisms at 24 h following blast exposure. To this end, we conducted separate blast-wave exposures on rats in a shock tube at an incident overpressure of 130 kPa, while using whole-body, head-only, and torso-only configurations to delineate each mechanism. Then, we performed histopathological (silver staining) and immunohistochemical (GFAP, Iba-1, and NeuN staining) analyses to evaluate brain-tissue changes resulting from each mechanism. Compared to controls, our results showed no significant changes in torso-only-exposed rats. In contrast, we observed significant changes in whole-body-exposed (GFAP and silver staining) and head-only-exposed rats (silver staining). In addition, our analyses showed that a head-only exposure causes changes similar to those observed for a whole-body exposure, provided the exposure conditions are similar. In conclusion, our results suggest that the direct mechanism is the major contributor to blast-induced changes in brain tissues.

Published

2021

27. Long-Term Effects of Blast Exposure: A Functional Study in Rats Using an Advanced Blast Simulator

Author

Ying Wang, Stephen Van Albert, Peethambaran Arun, Sujith Sajja, Rodrigo Urioste, Irene D. Gist, Ondine Eken, Donna M. Wilder, Joseph B. Long, and Andrew Batuure

Subjects

Male, 030506 rehabilitation, medicine.medical_specialty, Injury control, Blast exposure, Poison control, Suicide prevention, Occupational safety and health, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Blast Injuries, Memory, Brain Injuries, Traumatic, Injury prevention, Animals, Medicine, Maze Learning, Behavior, Animal, business.industry, Human factors and ergonomics, Rats, Term (time), Disease Models, Animal, Rotarod Performance Test, Emergency medicine, Exploratory Behavior, Neurology (clinical), 0305 other medical science, business, 030217 neurology & neurosurgery

Abstract

Anecdotal observations of blast victims indicate that significant neuropathological and neurobehavioral defects may develop at later stages of life. To pre-clinically model this phenomenon, we have examined neurobehavioral changes in rats up to 1 year after exposure to single and tightly coupled repeated blasts using an advanced blast simulator. Neurobehavioral changes were monitored at acute, sub-acute, and chronic time-points using Morris water maze test of spatial learning and memory, novel object recognition test of short-term memory, open field exploratory activity as a test of anxiety/depression, a rotating pole test for vestibulomotor function, and a rotarod balance test for motor coordination. Single and repeated blasts resulted in significant functional deficits at both acute and chronic time-points. In most functional tests, rats exposed to repeated blasts performed more poorly than rats exposed to single blast. Interestingly, several functional deficits post-blast were most pronounced at 6 months and beyond. Significant neuromotor impairments occurred at early stages after blast exposure and the severity increased with repeated exposures. The novel object recognition testing revealed short-term memory deficits at 6 and 12 months post-blast. The water maze test revealed impairments at acute and chronic stages after blast exposure. The most substantial changes in the blast-exposed rats were observed with the center time and margin time legacies in the open field exploration test at 6, 9, and 12 months post-blast. Notably, these two outcome measures were minimally altered acutely, recovered during sub-acute stages, and were markedly affected during the chronic stages after blast exposures and may implicate development of chronic anxiety and depressive-like behaviors.

Published

2020

28. Evaluation of Blast Overpressure Exposure Effects on Concentration of Antibiotics in Mice

Author

Brittany I Garry, Joseph B. Long, Brittney Potter, Jason C. Sousa, Jonathan P. Shearer, Venkatasivasaisujith Sajja, Vlado Antonic, Ken Nguyen, Chad C. Black, Maria Medina-Rojas, Yonas Alamneh, Samandra T. Demons, Chau Vuong, Daniel V. Zurawski, Donna M. Wilder, and Stuart D. Tyner

Subjects

medicine.drug_class, Antibiotics, Cefazolin, Explosions, Context (language use), Pharmacology, Mice, Pharmacokinetics, Blast Injuries, In vivo, Pressure, medicine, Animals, Mice, Inbred BALB C, business.industry, Basic Local Alignment Search Tool, Public Health, Environmental and Occupational Health, General Medicine, IV injection, Anti-Bacterial Agents, Disease Models, Animal, ROC Curve, Area Under Curve, Pharmacodynamics, business, medicine.drug

Abstract

Objective Infection as sequelae to explosion-related injury is an enduring threat to our troops. There are limited data on the effects of blast on antibiotic pharmacokinetics (PK), pharmacodynamics (PD), and efficacy. The observational study presented here is our Institute’s first attempt to address this issue by combining our existing interdepartmental blast, infection modeling, and in vivo PK/PD capabilities and was designed to determine the PK effects of blast on the first-line antibiotic, cefazolin, in an in vivo mouse model. Methods A total of 160 male BALB/c mice were divided to sham and blast (exposed to blast overpressure of 19 psi) in two biological replicates. At 1 hour after blast/sham exposure, the animals received IV injection of cefazolin (328 mg/kg). Animals were euthanized at 3 minutes, 10 minutes, 15 minutes, 30 minutes, 1 hour, 3 hours, 6 hours, or 10 hours after the injection. Plasma and liver were analyzed for concentration of cefazolin using mass-spectrometry. Results We observed increases in the concentration of cefazolin in the plasma and liver of blast exposed animals at later time points and increase in elimination half-life. Conclusion Our results indicate that blast-induced physiologic changes significantly influence cefazolin PK and suggest that efficacy could be affected in the context of the blast; assessment of efficacy and PD effects require further investigation. Metabolic changes resulting from blast may influence other classes of antibiotics and other therapeutics used with these injuries. Therefore, this may have important treatment considerations in other areas of military medicine.

Published

2020

29. The Neurobehavioral Effects of Buprenorphine and Meloxicam on a Blast-Induced Traumatic Brain Injury Model in the Rat

Author

Donna M. Wilder, Joseph B. Long, Marisela Lara, Ondine Eken, Sridhar Samineni, Rodrigo Urioste, Laura M Anderson, and Peethambaran Arun

Subjects

Traumatic brain injury, Analgesic, Neuroprotection, Open field, Medicine, RC346-429, meloxicam, Original Research, business.industry, traumatic brain injury, neurobehavioral effects, analgesic, medicine.disease, blast exposure, buprenorphine, Meloxicam, Isoflurane, Neurology, Anesthesia, Anxiety, Neurology (clinical), Neurology. Diseases of the nervous system, medicine.symptom, business, medicine.drug, Buprenorphine

Abstract

Previous findings have indicated that pain relieving medications such as opioids and non-steroidal anti-inflammatory drugs (NSAIDs) may be neuroprotective after traumatic brain injury in rodents, but only limited studies have been performed in a blast-induced traumatic brain injury (bTBI) model. In addition, many pre-clinical TBI studies performed in rodents did not use analgesics due to the possibility of neuroprotection or other changes in cognitive, behavioral, and pathology outcomes. To examine this in a pre-clinical setting, we examined the neurobehavioral changes in rats given a single pre-blast dose of meloxicam, buprenorphine, or no pain relieving medication and exposed to tightly-coupled repeated blasts in an advanced blast simulator and evaluated neurobehavioral functions up to 28 days post-blast. A 16.7% mortality rate was recorded in the rats treated with buprenorphine, which might be attributed to the physiologically depressive side effects of buprenorphine in combination with isoflurane anesthesia and acute brain injury. Rats given buprenorphine, but not meloxicam, took more time to recover from the isoflurane anesthesia given just before blast. We found that treatment with meloxicam protected repeated blast-exposed rats from vestibulomotor dysfunctions up to day 14, but by day 28 the protective effects had receded. Both pain relieving medications seemed to promote short-term memory deficits in blast-exposed animals, whereas vehicle-treated blast-exposed animals showed only a non-significant trend toward worsening short-term memory by day 27. Open field exploratory behavior results showed that blast exposed rats treated with meloxicam engaged in significantly more locomotor activities and possibly a lesser degree of responses thought to reflect anxiety and depressive-like behaviors than any of the other groups. Rats treated with analgesics to alleviate possible pain from the blast ate more than their counterparts that were not treated with analgesics, which supports that both analgesics were effective in alleviating some of the discomfort that these rats potentially experienced post-blast injury. These results suggest that meloxicam and, to a lesser extent buprenorphine alter a variety of neurobehavioral functions in a rat bTBI model and, because of their impact on these neurobehavioral changes, may be less than ideal analgesic agents for pre-clinical studies evaluating these neurobehavioral responses after TBI.

Published

2021

30. A Methodology to Compare Biomechanical Simulations With Clinical Brain Imaging Analysis Utilizing Two Blunt Impact Cases

Author

Amit Bagchi, Maria M D'Souza, Venkata Siva Sai Sujith Sajja, Raj K. Gupta, Ajay Kumar Singh, X. Gary Tan, and Joseph B. Long

Subjects

medicine.medical_specialty, magnetic resonance imaging (MRI), Histology, Traumatic brain injury, modeling and prediction, Biomedical Engineering, Bioengineering, traffic accidents, Head trauma, 03 medical and health sciences, 0302 clinical medicine, Physical medicine and rehabilitation, Neuroimaging, Methods, medicine, diffusion weighted imaging (DWI), apparent diffusion coefficient (ADC), injury assessment, Medical diagnosis, traumatic brain injury (TBI), 030304 developmental biology, 0303 health sciences, computational, Modalities, Modality (human–computer interaction), medicine.diagnostic_test, business.industry, Head injury, Bioengineering and Biotechnology, Magnetic resonance imaging, medicine.disease, business, TP248.13-248.65, 030217 neurology & neurosurgery, Biotechnology

Abstract

According to the US Defense and Veterans Brain Injury Center (DVBIC) and Centers for Disease Control and Prevention (CDC), mild traumatic brain injury (mTBI) is a common form of head injury. Medical imaging data provides clinical insight into tissue damage/injury and injury severity, and helps medical diagnosis. Computational modeling and simulation can predict the biomechanical characteristics of such injury, and are useful for development of protective equipment. Integration of techniques from computational biomechanics with medical data assessment modalities (e.g., magnetic resonance imaging or MRI) has not yet been used to predict injury, support early medical diagnosis, or assess effectiveness of personal protective equipment. This paper presents a methodology to map computational simulations with clinical data for interpreting blunt impact TBI utilizing two clinically different head injury case studies. MRI modalities, such as T1, T2, diffusion-weighted imaging (DWI) and apparent diffusion coefficient (ADC), were used for simulation comparisons. The two clinical cases have been reconstructed using finite element analysis to predict head biomechanics based on medical reports documented by a clinician. The findings are mapped to simulation results using image-based clinical analyses of head impact injuries, and modalities that could capture simulation results have been identified. In case 1, the MRI results showed lesions in the brain with skull indentation, while case 2 had lesions in both coup and contrecoup sides with no skull deformation. Simulation data analyses show that different biomechanical measures and thresholds are needed to explain different blunt impact injury modalities; specifically, strain rate threshold corresponds well with brain injury with skull indentation, while minimum pressure threshold corresponds well with coup–contrecoup injury; and DWI has been found to be the most appropriate modality for MRI data interpretation. As the findings from these two cases are substantiated with additional clinical studies, this methodology can be broadly applied as a tool to support injury assessment in head trauma events and to improve countermeasures (e.g., diagnostics and protective equipment design) to mitigate these injuries.

Published

2021

31. Animal Orientation Affects Brain Biomechanical Responses to Blast-Wave Exposure

Author

Jose E. Rubio, Jaques Reifman, Dhananjay Radhakrishnan Subramaniam, Ginu Unnikrishnan, Stephen Van Albert, Haojie Mao, Joseph B. Long, Aravind Sundaramurthy, and Venkata Siva Sai Sujith Sajja

Subjects

Strain (chemistry), Traumatic brain injury, Chemistry, Biomedical Engineering, Biomechanics, Anatomy, medicine.disease, Sagittal plane, Cerebral circulation, medicine.anatomical_structure, Blast Injuries, Ventricle, Orientation (mental), Physiology (medical), medicine, Blast wave

Abstract

In this study, we investigated how animal orientation within a shock tube influences the biomechanical responses of the brain and cerebral vasculature of a rat when exposed to a blast wave. Using three-dimensional finite element (FE) models, we computed the biomechanical responses when the rat was exposed to the same blast-wave overpressure (100 kPa) in a prone (P), vertical (V), or head-only (HO) orientation. We validated our model by comparing the model-predicted and the experimentally measured brain pressures at the lateral ventricle. For all three orientations, the maximum difference between the predicted and measured pressures was 11%. Animal orientation markedly influenced the predicted peak pressure at the anterior position along the midsagittal plane of the brain (P = 187 kPa; V = 119 kPa; and HO = 142 kPa). However, the relative differences in the predicted peak pressure between the orientations decreased at the medial (21%) and posterior (7%) positions. In contrast to the pressure, the peak strain in the prone orientation relative to the other orientations at the anterior, medial, and posterior positions was 40–88% lower. Similarly, at these positions, the cerebral vasculature strain in the prone orientation was lower than the strain in the other orientations. These results show that animal orientation in a shock tube influences the biomechanical responses of the brain and the cerebral vasculature of the rat, strongly suggesting that a direct comparison of changes in brain tissue observed from animals exposed at different orientations can lead to incorrect conclusions.

Published

2021

32. Blast Exposure Causes Long-Term Degeneration of Neuronal Cytoskeletal Elements in the Cochlear Nucleus: A Potential Mechanism for Chronic Auditory Dysfunctions

Author

Franco Rossetti, Joseph B. Long, Irene D. Gist, Ying Wang, Peethambaran Arun, and Donna M. Wilder

Subjects

Medial geniculate nucleus, Inferior colliculus, business.industry, Lateral lemniscus, Degeneration (medical), auditory dysfunction, Auditory cortex, blast exposure, cochlear nucleus, Cochlear nucleus, lcsh:RC346-429, medicine.anatomical_structure, Neurology, degeneration of neuronal cytoskeletal elements, medicine, otorhinolaryngologic diseases, Auditory system, Neurology (clinical), medicine.symptom, tinnitus, business, Neuroscience, Tinnitus, lcsh:Neurology. Diseases of the nervous system, Original Research

Abstract

Blast-induced auditory dysfunctions including tinnitus are the most prevalent disabilities in service members returning from recent combat operations. Most of the previous studies were focused on the effect of blast exposure on the peripheral auditory system and not much on the central auditory signal-processing regions in the brain. In the current study, we have exposed rats to single and tightly coupled repeated blasts and examined the degeneration of neuronal cytoskeletal elements using silver staining in the central auditory signal-processing regions in the brain at 24 h, 14 days, 1 month, 6 months, and 1 year. The brain regions evaluated include cochlear nucleus, lateral lemniscus, inferior colliculus, medial geniculate nucleus, and auditory cortex. The results obtained indicated that a significant increase in degeneration of neuronal cytoskeletal elements was observed only in the left and right cochlear nucleus. A significant increase in degeneration of neuronal cytoskeletal elements was observed in the cochlear nucleus at 24 h and persisted through 1 year, suggesting acute and chronic neuronal degeneration after blast exposure. No statistically significant differences were observed between single and repeated blasts. The localized degeneration of neuronal cytoskeletal elements in the cochlear nucleus suggests that the damage could be caused by transmission of blast shockwaves/noise through the ear canal and that use of suitable ear protection devices can protect against acute and chronic central auditory signal processing defects including tinnitus after blast exposure.

Published

2021

33. Repeated Low-Level Blast Acutely Alters Brain Cytokines, Neurovascular Proteins, Mechanotransduction, and Neurodegenerative Markers in a Rat Model

Author

Stephen T. Ahlers, Rania Abutarboush, Venkatasivasai Sujith Sajja, Donna M. Wilder, Lanier Heyburn, Samantha Y. Goodrich, Joseph B. Long, Andrew Batuure, Rodrigo Urioste, Peethambaran Arun, and Jaimena Wheel

Subjects

0301 basic medicine, medicine.medical_specialty, Piezo2 channel, TAR DNA-bindingprotein 43 (TDP-43), Inflammation, Blood–brain barrier, Occludin, lcsh:RC321-571, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Mechanosensitive ion channel, Internal medicine, medicine, Mechanotransduction, Receptor, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research, Tight junction, business.industry, blood-brain barrier, medicine.disease, Astrogliosis, repetitive blast, 030104 developmental biology, medicine.anatomical_structure, Endocrinology, Cellular Neuroscience, blast wave-induced neurotrauma, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

Exposure to the repeated low-level blast overpressure (BOP) periodically experienced by military personnel in operational and training environments can lead to deficits in behavior and cognition. While these low-intensity blasts do not cause overt changes acutely, repeated exposures may lead to cumulative effects in the brain that include acute inflammation, vascular disruption, and other molecular changes, which may eventually contribute to neurodegenerative processes. To identify these acute changes in the brain following repeated BOP, an advanced blast simulator was used to expose rats to 8.5 or 10 psi BOP once per day for 14 days. At 24 h after the final BOP, brain tissue was collected and analyzed for inflammatory markers, astrogliosis (GFAP), tight junction proteins (claudin-5 and occludin), and neurodegeneration-related proteins (Aβ40/42, pTau, TDP-43). After repeated exposure to 8.5 psi BOP, the change in cytokine profile was relatively modest compared to the changes observed following 10 psi BOP, which included a significant reduction in several inflammatory markers. Reduction in the tight junction protein occludin was observed in both groups when compared to controls, suggesting cerebrovascular disruption. While repeated exposure to 8.5 psi BOP led to a reduction in the Alzheimer’s disease (AD)-related proteins amyloid-β (Aβ)40 and Aβ42, these changes were not observed in the 10 psi group, which had a significant reduction in phosphorylated tau. Finally, repeated 10 psi BOP exposures led to an increase in GFAP, indicating alterations in astrocytes, and an increase in the mechanosensitive ion channel receptor protein, Piezo2, which may increase brain sensitivity to injury from pressure changes from BOP exposure. Overall, cumulative effects of repeated low-level BOP may increase the vulnerability to injury of the brain by disrupting neurovascular architecture, which may lead to downstream deleterious effects on behavior and cognition.

Published

2021

34. Blast Exposure Leads to Accelerated Cellular Senescence in the Rat Brain

Author

Ying Wang, Donna M. Wilder, Irene D. Gist, Franco Rossetti, Joseph B. Long, Sujith Sajja, Peethambaran Arun, and Stephen Van Albert

Subjects

0301 basic medicine, Senescence, medicine.medical_specialty, senescence, Traumatic brain injury, SMP-30, Hippocampus, Biology, Auditory cortex, lcsh:RC346-429, 03 medical and health sciences, 0302 clinical medicine, Internal medicine, Cortex (anatomy), medicine, SA-β-gal, lcsh:Neurology. Diseases of the nervous system, Original Research, p21, Superior colliculus, traumatic brain injury, Neurodegeneration, aging, medicine.disease, blast exposure, 030104 developmental biology, Endocrinology, medicine.anatomical_structure, Neurology, Neurology (clinical), Nucleus, 030217 neurology & neurosurgery

Abstract

Blast-induced traumatic brain injury (bTBI) is one of the major causes of persistent disabilities in Service Members, and a history of bTBI has been identified as a primary risk factor for developing age-associated neurodegenerative diseases. Clinical observations of several military blast casualties have revealed a rapid age-related loss of white matter integrity in the brain. In the present study, we have tested the effect of single and tightly coupled repeated blasts on cellular senescence in the rat brain. Isoflurane-anesthetized rats were exposed to either a single or 2 closely coupled blasts in an advanced blast simulator. Rats were euthanized and brains were collected at 24 h, 1 month and 1 year post-blast to determine senescence-associated-β-galactosidase (SA-β-gal) activity in the cells using senescence marker stain. Single and repeated blast exposures resulted in significantly increased senescence marker staining in several neuroanatomical structures, including cortex, auditory cortex, dorsal lateral thalamic nucleus, geniculate nucleus, superior colliculus, ventral thalamic nucleus and hippocampus. In general, the increases in SA-β-gal activity were more pronounced at 1 month than at 24 h or 1 year post-blast and were also greater after repeated than single blast exposures. Real-time quantitative RT-PCR analysis revealed decreased levels of mRNA for senescence marker protein-30 (SMP-30) and increased mRNA levels for p21 (cyclin dependent kinase inhibitor 1A, CDKN1A), two other related protein markers of cellular senescence. The increased senescence observed in some of these affected brain structures may be implicated in several long-term sequelae after exposure to blast, including memory disruptions and impairments in movement, auditory and ocular functions.

Published

2020

35. Blast-induced hearing impairment in rats is associated with structural and molecular changes of the inner ear

Author

Peethambaran Arun, Irene D. Gist, Yanling Wei, Venkatasivasaisujith Sajja, Ying Wang, Tracy S. Fitzgerald, Rodrigo Urioste, Joseph B. Long, Donna M. Wilder, Matthew W. Kelley, and Weise Chang

Subjects

0301 basic medicine, Male, Pathology, medicine.medical_specialty, Perforation (oil well), Otoacoustic Emissions, Spontaneous, lcsh:Medicine, Ear, Middle, Otoscopy, Molecular neuroscience, Mechanotransduction, Cellular, Trauma, Article, Rats, Sprague-Dawley, 03 medical and health sciences, Myelin, 0302 clinical medicine, Hearing, Blast Injuries, medicine, otorhinolaryngologic diseases, Evoked Potentials, Auditory, Brain Stem, Animals, Inner ear, Mechanotransduction, Axon, lcsh:Science, Hearing Loss, Cochlea, Multidisciplinary, business.industry, lcsh:R, Auditory Threshold, Rats, 030104 developmental biology, medicine.anatomical_structure, Ear, Inner, Middle ear, Audiometry, Pure-Tone, Auditory system, lcsh:Q, Brainstem, sense organs, business, 030217 neurology & neurosurgery

Abstract

Auditory dysfunction is the most prevalent injury associated with blast overpressure exposure (BOP) in Warfighters and civilians, yet little is known about the underlying pathophysiological mechanisms. To gain insights into these injuries, an advanced blast simulator was used to expose rats to BOP and assessments were made to identify structural and molecular changes in the middle/inner ears utilizing otoscopy, RNA sequencing (RNA-seq), and histopathological analysis. Deficits persisting up to 1 month after blast exposure were observed in the distortion product otoacoustic emissions (DPOAEs) and the auditory brainstem responses (ABRs) across the entire range of tested frequencies (4–40 kHz). During the recovery phase at sub-acute time points, low frequency (e.g. 4–8 kHz) hearing improved relatively earlier than for high frequency (e.g. 32–40 kHz). Perforation of tympanic membranes and middle ear hemorrhage were observed at 1 and 7 days, and were restored by day 28 post-blast. A total of 1,158 differentially expressed genes (DEGs) were significantly altered in the cochlea on day 1 (40% up-regulated and 60% down-regulated), whereas only 49 DEGs were identified on day 28 (63% up-regulated and 37% down-regulated). Seven common DEGs were identified at both days 1 and 28 following blast, and are associated with inner ear mechanotransduction, cytoskeletal reorganization, myelin development and axon survival. Further studies on altered gene expression in the blast-injured rat cochlea may provide insights into new therapeutic targets and approaches to prevent or treat similar cases of blast-induced auditory damage in human subjects.

Published

2020

36. Pulmonary injury risk curves and behavioral changes from blast overpressure exposures of varying frequency and intensity in rats

Author

Venkatasivasai Sujith Sajja, Jonathan K. Statz, Joseph B. Long, Lcdr Peter B Walker, Irene D. Gist, Stephen T. Ahlers, and Donna M. Wilder

Subjects

Male, Risk, Time Factors, H&E stain, lcsh:Medicine, Explosions, Lung injury, Trauma, Open field, Article, Pressure range, Rats, Sprague-Dawley, 03 medical and health sciences, 0302 clinical medicine, Explosive Agents, Blast Injuries, Pressure, Medicine, Animals, lcsh:Science, Multidisciplinary, business.industry, lcsh:R, 030208 emergency & critical care medicine, Lung Injury, Overpressure, Intensity (physics), Disease Models, Animal, Anesthesia, Pulmonary Injury, lcsh:Q, Risk curves, business, Biomedical engineering, 030217 neurology & neurosurgery

Abstract

At present, there are no set guidelines establishing cumulative limits for blast exposure numbers and intensities in military personnel, in combat or training operations. The objective of the current study was to define lung injury, pathology, and associated behavioral changes from primary repeated blast lung injury under appropriate exposure conditions and combinations (i.e. blast overpressure (BOP) intensity and exposure frequency) using an advanced blast simulator. Male Sprague Dawley rats were exposed to BOP frontally and laterally at a pressure range of ~ 8.5–19 psi, for up to 30 daily exposures. The extent of lung injury was identified at 24 h following BOP by assessing the extent of surface hemorrhage/contusion, Hematoxylin and Eosin staining, and behavioral deficits with open field activity. Lung injury was mathematically modeled to define the military standard 1% lung injury threshold. Significant levels of histiocytosis and inflammation were observed in pressures ≥ 10 psi and orientation effects were observed at pressures ≥ 13 psi. Experimental data demonstrated ~ 8.5 psi is the threshold for hemorrhage/contusion, up to 30 exposures. Modeling the data predicted injury risk up to 50 exposures with intensity thresholds at 8 psi for front exposure and 6psi for side exposures, which needs to be validated further.

Published

2020

37. Sphingolipids and microRNA Changes in Blood following Blast Traumatic Brain Injury: An Exploratory Study

Author

Miroslaw Janowski, Venkata Siva Sai Sujith Sajja, Anna Jablonska, Jeff W.M. Bulte, Norman J. Haughey, Robert Stevens, Piotr Walczak, and Joseph B. Long

Subjects

Male, 0301 basic medicine, Pathology, medicine.medical_specialty, Traumatic brain injury, Lipid composition, Biology, Bioinformatics, Mice, 03 medical and health sciences, 0302 clinical medicine, Blast Injuries, Brain Injuries, Traumatic, microRNA, Plasma lipids, medicine, Animals, Mice, Inbred BALB C, Sphingolipids, medicine.disease, Sphingolipid, MicroRNAs, 030104 developmental biology, Murine model, Neurology (clinical), Biomarkers, 030217 neurology & neurosurgery

Abstract

At present, accurate and reliable biomarkers to ascertain the presence, severity, or prognosis of blast traumatic brain injury (bTBI) are lacking. There is an urgent need to establish accurate and reliable biomarkers capable of mbTBI detection. Currently, there are no studies that identify changes in miRNA and lipids at varied severities of bTBI. Various biological components such as lipids, circulating mRNA, and miRNA, could potentially be detected using advanced techniques such as next-generation sequencing and mass spectroscopy. Therefore, plasma analysis is an attractive approach with which to diagnose and treat brain injuries. Subacute changes in plasma microRNA (miRNA) and lipid composition for sphingolipids were evaluated in a murine model of mild-to-moderate bTBI using next-generation sequencing and mass spectroscopy respectively. Animals were exposed at 17, 17 × 3, and 20 psi blast intensities using a calibrated blast simulator. Plasma lipid profiling demonstrated decreased C18 fatty acid chains of sphingomyelins and increased ceramide levels when compared with controls. Plasma levels of brain-enriched miRNA, miR-127 were increased in all groups while let-7a, b, and g were reduced in the 17 × 3 and 20 psi groups, but let 7d was increased in the 17 psi group. The majority of the miRs and lipids are highly conserved across different species, making them attractive to explore and potentially employ as diagnostic markers. It is tempting to speculate that sphingolipids, miR-128, and the let-7 family could predict mTBI, while a combination of miR-484, miR-122, miR-148a, miR-130a, and miR-223 could be used to predict the overall status of injury following blast injury.

Published

2018

38. Assessment of auditory and vestibular damage in a mouse model after single and triple blast exposures

Author

Talah T Wafa, Ying Wang, Tracy S. Fitzgerald, Rodrigo Urioste, Irene D. Gist, Yanling Wei, Tara Balasubramanian, Venkata Siva Sai Sujith Sajja, Peethambaran Arun, Alan G. Cheng, Beatrice Mao, Kamren Edwards-Hollingsworth, Matthew W. Kelley, Donna M. Wilder, Joseph B. Long, Scott J. Haraczy, and Zahra N. Sayyid

Subjects

0301 basic medicine, medicine.medical_specialty, Traumatic brain injury, Hearing loss, Otoacoustic Emissions, Spontaneous, Audiology, Vestibular System, Article, 03 medical and health sciences, 0302 clinical medicine, hemic and lymphatic diseases, Evoked Potentials, Auditory, Brain Stem, otorhinolaryngologic diseases, Animals, Medicine, Inner ear, Hearing Loss, Spiral ganglion, Balance (ability), Vestibular system, business.industry, Auditory Threshold, medicine.disease, Sensory Systems, Hair Cells, Auditory, Outer, 030104 developmental biology, medicine.anatomical_structure, Quality of Life, Middle ear, sense organs, Brainstem, medicine.symptom, business, 030217 neurology & neurosurgery

Abstract

The use of explosive devices in war and terrorism has increased exposure to concussive blasts among both military personnel and civilians, which can cause permanent hearing and balance deficits that adversely affect survivors' quality of life. Significant knowledge gaps on the underlying etiology of blast-induced hearing loss and balance disorders remain, especially with regard to the effect of blast exposure on the vestibular system, the impact of multiple blast exposures, and long-term recovery. To address this, we investigated the effects of blast exposure on the inner ear using a mouse model in conjunction with a high-fidelity blast simulator. Anesthetized animals were subjected to single or triple blast exposures, and physiological measurements and tissue were collected over the course of recovery for up to 180 days. Auditory brainstem responses (ABRs) indicated significantly elevated thresholds across multiple frequencies. Limited recovery was observed at low frequencies in single-blasted mice. Distortion Product Otoacoustic Emissions (DPOAEs) were initially absent in all blast-exposed mice, but low-amplitude DPOAEs could be detected at low frequencies in some single-blast mice by 30 days post-blast, and in some triple-blast mice at 180 days post-blast. All blast-exposed mice showed signs of Tympanic Membrane (TM) rupture immediately following exposure and loss of outer hair cells (OHCs) in the basal cochlear turn. In contrast, the number of Inner Hair Cells (IHCs) and spiral ganglion neurons was unchanged following blast-exposure. A significant reduction in IHC pre-synaptic puncta was observed in the upper turns of blast-exposed cochleae. Finally, we found no significant loss of utricular hair cells or changes in vestibular function as assessed by vestibular evoked potentials. Our results suggest that (1) blast exposure can cause severe, long-term hearing loss which may be partially due to slow TM healing or altered mechanical properties of healed TMs, (2) traumatic levels of sound can still reach the inner ear and cause basal OHC loss despite middle ear dysfunction caused by TM rupture, (3) blast exposure may result in synaptopathy in humans, and (4) balance deficits after blast exposure may be primarily due to traumatic brain injury, rather than damage to the peripheral vestibular system.

Published

2021

39. Cerebrospinal Fluid Chemokine (C-C Motif) Ligand 2 Is an Early-Response Biomarker for Blast-Overpressure-Wave–Induced Neurotrauma in Rats

Author

Joseph B. Long, Yan Su, Irene D. Gist, Peethambaran Arun, Donna M. Wilder, Ying Wang, Yanling Wei, Samuel Oguntayo, and Lawrence Tong

Subjects

Male, 0301 basic medicine, Chemokine, Traumatic brain injury, Central nervous system, Rats, Sprague-Dawley, Brain ischemia, Pathogenesis, 03 medical and health sciences, 0302 clinical medicine, Cerebrospinal fluid, Blast Injuries, Brain Injuries, Traumatic, medicine, Animals, Receptor, Chemokine CCL2, biology, Monocyte, medicine.disease, Rats, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Immunology, biology.protein, Neurology (clinical), Biomarkers, 030217 neurology & neurosurgery

Abstract

Chemokines and their receptors are of great interest within the milieu of immune responses elicited in the central nervous system in response to trauma. Chemokine (C-C motif)) ligand 2 (CCL2), which is also known as monocyte chemotactic protein-1, has been implicated in the pathogenesis of traumatic brain injury (TBI), brain ischemia, Alzheimer's disease, and other neurodegenerative diseases. In this study, we investigated the time course of CCL2 accumulation in cerebrospinal fluid (CSF) after exposures to single and repeated blast overpressures of varied intensities along with the neuropathological changes and motor deficits resulting from these blast conditions. Significantly increased concentrations of CCL2 in CSF were evident by 1 h of blast exposure and persisted over 24 h with peak levels measured at 6 h post-injury. The increased levels of CCL2 in CSF corresponded with both the number and intensities of blast overpressure and were also commensurate with the extent of neuromotor impairment and neuropathological abnormalities resulting from these exposures. CCL2 levels in CSF and plasma were tightly correlated with levels of CCL2 messenger RNA in cerebellum, the brain region most consistently neuropathologically disrupted by blast. In view of the roles of CCL2 that have been implicated in multiple neurodegenerative disorders, it is likely that the sustained high levels of CCL2 and the increased expression of its main receptor, CCR2, in the brain after blast may similarly contribute to neurodegenerative processes after blast exposure. In addition, the markedly elevated concentration of CCL2 in CSF might be a candidate early-response biomarker for diagnosis and prognosis of blast-induced TBI.

Published

2017

40. The Role of Very Low Level Blast Overpressure in Symptomatology

Author

Jonathan E. Salib, Alejandro N. Ramos, Michael J. Egnoto, Anthony Misistia, Christina R. LaValle, Venkata Siva Sai Sujith Sajja, Meron Y. Ghebremedhin, Gary H. Kamimori, and Joseph B. Long

Subjects

medicine.medical_specialty, Lightheadedness, Post exposure, overpressure, 0211 other engineering and technologies, blast, 02 engineering and technology, Audiology, Irritability, lcsh:RC346-429, 03 medical and health sciences, 0302 clinical medicine, mTBI, Medicine, sound pressure, lcsh:Neurology. Diseases of the nervous system, 021110 strategic, defence & security studies, business.industry, Brief Research Report, Overpressure, Neurology, Neurology (clinical), medicine.symptom, business, bTBI, symptomology, 030217 neurology & neurosurgery

Abstract

Blast overpressure exposure has been linked to transient, but measurably deteriorated performance and symptomatologies in law enforcement and military personnel. Overlapping sub-concussive symptomatology associated with the very low level blast overpressures (vLLB) but high sound pressure (

Published

2019

41. Repeated Low-Level Blast Overpressure Leads to Endovascular Disruption and Alterations in TDP-43 and Piezo2 in a Rat Model of Blast TBI

Author

Venkata Siva Sai Sujith Sajja, Rania Abutarboush, Donna M. Wilder, Jonathan K. Statz, Andrew Batuure, Joseph B. Long, Samantha Y. Goodrich, Stephen T. Ahlers, Lanier Heyburn, and Rodrigo Urioste

Subjects

0301 basic medicine, low-level blast, cumulative effects, Traumatic brain injury, TDP-43, Blood–brain barrier, Occludin, lcsh:RC346-429, Blast injury, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, hemic and lymphatic diseases, medicine, training relevant, lcsh:Neurology. Diseases of the nervous system, Neuroinflammation, Original Research, business.industry, Neurodegeneration, Piezo2, blood-brain barrier, medicine.disease, Pathophysiology, blast-induced neurotrauma, Vascular endothelial growth factor, 030104 developmental biology, medicine.anatomical_structure, chemistry, Neurology, Immunology, repeated exposures, Neurology (clinical), business, 030217 neurology & neurosurgery

Abstract

Recent evidence linking repeated low-level blast overpressure exposure in operational and training environments with neurocognitive decline, neuroinflammation, and neurodegenerative processes has prompted concern over the cumulative deleterious effects of repeated blast exposure on the brains of service members. Repetitive exposure to low-level primary blast may cause symptoms (subclinical) similar to those seen in mild traumatic brain injury (TBI), with progressive vascular and cellular changes, which could contribute to neurodegeneration. At the cellular level, the mechanical force associated with blast exposure can cause cellular perturbations in the brain, leading to secondary injury. To examine the cumulative effects of repetitive blast on the brain, an advanced blast simulator (ABS) was used to closely mimic “free-field” blast. Rats were exposed to 1–4 daily blasts (one blast per day, separated by 24 h) at 13, 16, or 19 psi peak incident pressures with a positive duration of 4–5 ms, either in a transverse or longitudinal orientation. Blood-brain barrier (BBB) markers (vascular endothelial growth factor (VEGF), occludin, and claudin-5), transactive response DNA binding protein (TDP-43), and the mechanosensitive channel Piezo2 were measured following blast exposure. Changes in expression of VEGF, occludin, and claudin-5 after repeated blast exposure indicate alterations in the BBB, which has been shown to be disrupted following TBI. TDP-43 is very tightly regulated in the brain and altered expression of TDP-43 is found in clinically-diagnosed TBI patients. TDP-43 levels were differentially affected by the number and magnitude of blast exposures, decreasing after 2 exposures, but increasing following a greater number of exposures at various intensities. Lastly, Piezo2 has been shown to be dysregulated following blast exposure and was here observed to increase after multiple blasts of moderate magnitude, indicating that blast may cause a change in sensitivity to mechanical stimuli in the brain and may contribute to cellular injury. These findings reveal that cumulative effects of repeated exposures to blast can lead to pathophysiological changes in the brain, demonstrating a possible link between blast injury and neurodegenerative disease, which is an important first step in understanding how to prevent these diseases in soldiers exposed to blast.

Published

2019

42. The Role of TDP-43 in Military-Relevant TBI and Chronic Neurodegeneration

Author

Joseph B. Long, Lanier Heyburn, and Venkata Siva Sai Sujith Sajja

Subjects

0301 basic medicine, Traumatic brain injury, Mini Review, Disease, Frontotemporal dementia (FTD), lcsh:RC346-429, 03 medical and health sciences, 0302 clinical medicine, mental disorders, TBI, Medicine, Dementia, Amyotrophic lateral sclerosis, lcsh:Neurology. Diseases of the nervous system, business.industry, Neurodegeneration, TDP43 proteinopathy, Frontotemporal lobar degeneration, medicine.disease, nervous system diseases, Chronic traumatic encephalopathy, 030104 developmental biology, Neurology, frontotemporal lobar degeneration, blast-induced brain injuries, Neurology (clinical), business, Neuroscience, 030217 neurology & neurosurgery, Frontotemporal dementia

Abstract

Due largely to the use of improvised explosive devices (IEDs) and other explosives in recent military conflicts, blast-related TBI has emerged as a prominent injury sustained by warfighters. In the recent wars in Iraq and Afghanistan, traumatic brain injury (TBI) has been one of the most common types of injury sustained by soldiers and military personnel; of the ~380,000 TBIs reported in service members from 2000 to 2017, 82.3% were classified as mild (mTBI). While mTBI is associated with normal structural imaging, brief or no loss of consciousness, and rapid recovery of mental state, mTBI can nevertheless lead to persistent behavioral and cognitive effects. As in other cases of mTBI, exposure to low-level blast often does not cause immediate overt neurological effects, but may similarly lead to persistent behavioral and cognitive deficits. These effects are likely to be compounded when multiple exposures to blast and/or impact are sustained, since there is increasing evidence that multiple mTBIs can lead to chronic neurodegeneration. One common form of this deleterious outcome is frontotemporal lobar degeneration (FTLD), which is a progressive neurodegenerative process marked by atrophy of the frontal and temporal lobes, leading to frontotemporal dementia, a common form of dementia affecting behavior, cognition and language. About half of all cases of FTLD are marked by TAR-DNA binding protein (TDP-43)-positive protein inclusions. TDP-43, a DNA/RNA binding protein, controls the expression of thousands of genes and is associated with several neurodegenerative diseases including amyotrophic lateral sclerosis, Alzheimer's disease, Huntington's disease, and chronic traumatic encephalopathy. TDP-43 abnormalities have also been associated with traumatic brain injury in both pre-clinical and clinical studies. The role of TDP-43 in the manifestation of FTLD pathology in military TBI cases is currently unclear, and to date there has been only a limited number of pre-clinical studies addressing the effects of repeated blast-related mild TBI (rbTBI) in relation to FTLD and TDP-43. This review will summarize some of these findings and address the concerns and critical knowledge gaps associated with FTLD manifestation with military populations, as well as clinical findings on other forms of mTBI.

Published

2019

43. Microbiome Signatures Associated with Rodent Model of Traumatic Brain Injury vs. Psychological Stress

Author

Joseph B. Long, Aarti Gautam, Nabarun Chakraborty, Marti Jett, James C. DeMar, and Rasha Hammamieh

Subjects

Traumatic brain injury, business.industry, Rodent model, Bioinformatics, medicine.disease, medicine.disease_cause, Biochemistry, Genetics, medicine, Psychological stress, Microbiome, business, Molecular Biology, Biotechnology

Published

2020

44. A Comparative Study of Two Blast-Induced Traumatic Brain Injury Models: Changes in Monoamine and Galanin Systems Following Single and Repeated Exposure

Author

Tomas Hökfelt, Ulf P. Arborelius, Joseph B. Long, Lizan Kawa, Alaa Kamnaksh, Mårten Risling, and Denes V. Agoston

Subjects

0301 basic medicine, medicine.medical_specialty, dorsal raphe nucleus, Neuropeptide, Biology, lcsh:RC346-429, 03 medical and health sciences, 0302 clinical medicine, Dorsal raphe nucleus, Internal medicine, medicine, transmitter coexistence, Galanin, neuropeptide, lcsh:Neurology. Diseases of the nervous system, Original Research, TPH2, Tyrosine hydroxylase, locus coeruleus, Tryptophan hydroxylase, anxiety, animal models, 030104 developmental biology, Monoamine neurotransmitter, Endocrinology, Neurology, post-traumatic stress disorder, Locus coeruleus, Neurology (clinical), catecholamines, 030217 neurology & neurosurgery

Abstract

Repeated mild blast-induced traumatic brain injury (rmbTBI), caused by recurrent exposure to low levels of explosive blast, is a significant concern for military health systems. However, the pathobiology of rmbTBI is currently poorly understood. Animal models are important tools to identify the molecular changes of rmbTBI, but comparisons across different models can present their own challenges. In this study, we compared two well-established rodent models of mbTBI, the “KI model” and the “USU/WRAIR model.” These two models create different pulse forms, in terms of peak pressure and duration. Following single and double exposures to mild levels of blast, we used in situ hybridization (ISH) to assess changes in mRNA levels of tyrosine hydroxylase (TH), tryptophan hydroxylase (TPH2), and galanin in the locus coeruleus (LC) and dorsal raphe nucleus (DRN). These systems and their transmitters are known to mediate responses to stress and anxiety. We found increased mRNA levels of TH, TPH2 and galanin in the LC and DRN of single-exposed rats relative to sham rats in the KI but not the USU/WRAIR model. Sham mRNA values measured in the USU/WRAIR model were substantially higher than their KI counterparts. Double exposure caused similarly significant increases in mRNA values in the KI model but not the USU/WRAIR model, except TPH2 and galanin levels in the DRN. We detected no cumulative effect of injury in either model at the used inter-injury interval (30 min), and there were no detectable neuropathological changes in any experimental group at 1 day post-injury. The apparent lack of early response to injury as compared to sham in the USU/WRAIR model is likely caused by stressors (e.g., transportation and noise), associated with the experimental execution, that were absent in the KI model. This study is the first to directly compare two established rodent models of rmbTBI, and to highlight the challenges of comparing findings from different animal models. Additional studies are needed to understand the role of stress, dissect the effects of psychological and physical injuries and to identify the window of increased cerebral vulnerability, i.e., the inter-injury interval that results in a cumulative effect following repeated blast exposure.

Published

2018

45. Pre-Clinical Testing of Therapies for Traumatic Brain Injury

Author

Cameron R. Bass, Helen M. Bramlett, Kathryn E. Saatman, Michelle C. LaPlaca, Liying Zhang, Douglas H. Smith, Linda J. Noble-Haeusslein, Sidney R. Hinds, William M. Armstead, Joseph B. Long, Adam R. Ferguson, Andras Buki, Ronald L. Hayes, C. Edward Dixon, Edward D. Hall, Bridget E. Hawkins, Deborah A. Shear, David F. Meaney, W. Dalton Dietrich, Donald S. Prough, Pamela J. VandeVord, Claudia S. Robertson, Alex B. Valadka, Patrick M. Kochanek, Samuel M. Poloyac, Douglas S. DeWitt, Stefania Mondello, and Sandy R. Shultz

Subjects

0301 basic medicine, Traumatic, medicine.medical_specialty, Drug doses, Physical Injury - Accidents and Adverse Effects, pre-clinical, Traumatic brain injury, Operating procedures, Clinical Sciences, Reviews, Traumatic Brain Injury (TBI), 03 medical and health sciences, 0302 clinical medicine, Brain Injuries, Traumatic, medicine, Animals, Humans, guidelines, Intensive care medicine, Traumatic Head and Spine Injury, Biological therapies, Neurology & Neurosurgery, business.industry, Animal, traumatic brain injury, Neurosciences, medicine.disease, Brain Disorders, Clinical trial, Disease Models, Animal, 030104 developmental biology, Brain Injuries, Disease Models, Neurology (clinical), business, 030217 neurology & neurosurgery, guidelines, pre-clinical, traumatic brain injury

Abstract

Despite the large number of promising neuroprotective agents identified in experimental traumatic brain injury (TBI) studies, none has yet shown meaningful improvements in long-term outcome in clinical trials. To develop recommendations and guidelines for pre-clinical testing of pharmacological or biological therapies for TBI, the Moody Project for Translational Traumatic Brain Injury Research hosted a symposium attended by investigators with extensive experience in pre-clinical TBI testing. The symposium participants discussed issues related to pre-clinical TBI testing including experimental models, therapy and outcome selection, study design, data analysis, and dissemination. Consensus recommendations included the creation of a manual of standard operating procedures with sufficiently detailed descriptions of modeling and outcome measurement procedures to permit replication. The importance of the selection of clinically relevant outcome variables, especially related to behavior testing, was noted. Considering the heterogeneous nature of human TBI, evidence of therapeutic efficacy in multiple, diverse (e.g., diffuse vs. focused) rodent models and a species with a gyrencephalic brain prior to clinical testing was encouraged. Basing drug doses, times, and routes of administration on pharmacokinetic and pharmacodynamic data in the test species was recommended. Symposium participants agreed that the publication of negative results would reduce costly and unnecessary duplication of unsuccessful experiments. Although some of the recommendations are more relevant to multi-center, multi-investigator collaborations, most are applicable to pre-clinical therapy testing in general. The goal of these consensus guidelines is to increase the likelihood that therapies that improve outcomes in pre-clinical studies will also improve outcomes in TBI patients.

Published

2018

46. Traumatic Brain Injury - Pathobiology, Advanced Diagnostics and Acute Management

Author

Nikolai V. Gorbunov and Joseph B. Long

Subjects

medicine.medical_specialty, business.industry, Traumatic brain injury, medicine, Acute management, Intensive care medicine, business, medicine.disease

Published

2018

47. Introduction: Biomedical Challenges and Socioeconomic Burden

Author

Joseph B. Long and Nikolai V. Gorbunov

Subjects

business.industry, Environmental health, Medicine, business, Socioeconomic status

Published

2018

48. Microbiome alteration: Potential signature to discriminate features associated with TBI vs. psychological stress

Author

Allison Hoke, John Rosenberger, Joseph B. Long, Rasha Hammamieh, Donna M. Wilder, David J. Bloodgood, George Dimitrov, Raina Kumar, Nabarun Chakraborty, Aarti Gautam, James C. DeMar, Venkatasivasaisujith Sajja, Andrew Batuure, and Marti Jett

Subjects

business.industry, Genetics, medicine, Psychological stress, Microbiome, medicine.disease_cause, Bioinformatics, business, Signature (topology), Molecular Biology, Biochemistry, Biotechnology

Published

2018

49. Rodent Model of Primary Blast-Induced Traumatic Brain Injury: Guidelines to Blast Methodology

Author

Stephen Van Albert, Peethambaram Arun, Venkatasivasai Sujith Sajja, and Joseph B. Long

Subjects

0301 basic medicine, 03 medical and health sciences, Pathology, medicine.medical_specialty, 030104 developmental biology, 0302 clinical medicine, Blast induced traumatic brain injury, business.industry, medicine, Rodent model, business, 030217 neurology & neurosurgery

Published

2018

50. Acute decrease in alkaline phosphatase after brain injury: A potential mechanism for tauopathy

Author

Madhusoodana P. Nambiar, Samuel Oguntayo, Ying Wang, Joseph B. Long, Irene D. Gist, Peethambaran Arun, and Stephen Van Albert

Subjects

Male, Pathology, medicine.medical_specialty, Time Factors, Traumatic brain injury, Neuroscience(all), Tau protein, tau Proteins, Dephosphorylation, Rats, Sprague-Dawley, Amyloid beta-Protein Precursor, medicine, Amyloid precursor protein, Animals, Phosphorylation, biology, Chemistry, General Neuroscience, Brain, medicine.disease, Alkaline Phosphatase, Cell biology, Chronic traumatic encephalopathy, Brain Injuries, biology.protein, Alkaline phosphatase, Tauopathy

Abstract

Dephosphorylation of phosphorylated Tau (pTau) protein, which is essential for the preservation of neuronal microtubule assemblies and for protection against trauma-induced tauopathy and chronic traumatic encephalopathy (CTE), is primarily achieved in brain by tissue non-specific alkaline phosphatase (TNAP). Paired helical filaments (PHFs) and Tau isolated from Alzheimer's disease (AD) patients' brains have been shown to form microtubule assemblies with tubulin only after treatment with TNAP or protein phosphatase-2A, 2B and -1, suggesting that Tau protein in the PHFs of neurons in AD brain is hyperphosphorylated, which prevents microtubule assembly. Using blast or weight drop models of traumatic brain injury (TBI) in rats, we observed pTau accumulation in the brain as early as 6h post-injury and further accumulation which varied regionally by 24h post-injury. The pTau accumulation was accompanied by reduced TNAP expression and activity in these brain regions and a significantly decreased plasma total alkaline phosphatase activity after the weight drop. These results reveal that both blast- and impact acceleration-induced head injuries cause an acute decrease in the level/activity of TNAP in the brain, which potentially contributes to trauma-induced accumulation of pTau and the resultant tauopathy. The regional changes in the level/activity of TNAP or accumulation of pTau after these injuries did not correlate with the accumulation of amyloid precursor protein, suggesting that the basic mechanism underlying tauopathy in TBI might be distinct from that associated with AD.

Published

2015