Stress-dose hydrocortisone reduces critical illness-related corticosteroid insufficiency associated with severe traumatic brain injury in rats

Chen, Xin; Zhao, Ziqi; Chai, Yan; Luo, Lanlan; Jiang, Rongcai; Dong, Jing‐fei; Zhang, Jianning

doi:10.1186/cc13067

Cited by 32 publications

(20 citation statements)

References 56 publications

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“…Supplement with hydrocortisone post trauma also improves neurological recovery and leads to beneficial outcomes [35]. Moreover, progesterone, an indirect precursor of cortisol, has shown promise to be a neuroprotective agent, and it is currently under clinical trials for the treatment of TBI [36, 37].…”

Section: Discussionmentioning

confidence: 99%

Cortisol-induced immune suppression by a blockade of lymphocyte egress in traumatic brain injury

Dong

Liu

Bhayana

et al. 2016

J Neuroinflammation

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BackgroundAcute traumatic brain injury (TBI) represents one of major causes of mortality and disability in the USA. Neuroinflammation has been regarded both beneficial and detrimental, probably in a time-dependent fashion.MethodsTo address a role for neuroinflammation in brain injury, C57BL/6 mice were subjected to a closed head mild TBI (mTBI) by a standard controlled cortical impact, along with or without treatment of sphingosine 1-phosphate (S1P) or rolipram, after which the brain tissue of the impact site was evaluated for cell morphology via histology, inflammation by qRT-PCR and T cell staining, and cell death with Caspase-3 and TUNEL staining. Circulating lymphocytes were quantified by flow cytometry, and plasma hydrocortisone was analyzed by LC-MS/MS. To investigate the mechanism whereby cortisol lowered the number of peripheral T cells, T cell egress was tracked in lymph nodes by intravital confocal microscopy after hydrocortisone administration.ResultsWe detected a decreased number of circulating lymphocytes, in particular, T cells soon after mTBI, which was inversely correlated with a transient and robust increase of plasma cortisol. The transient lymphocytopenia might be caused by cortisol in part via a blockade of lymphocyte egress as demonstrated by the ability of cortisol to inhibit T cell egress from the secondary lymphoid tissues. Moreover, exogenous hydrocortisone severely suppressed periphery lymphocytes in uninjured mice, whereas administering an egress-promoting agent S1P normalized circulating T cells in mTBI mice and increased T cells in the injured brain. Likewise, rolipram, a cAMP phosphodiesterase inhibitor, was also able to elevate cAMP levels in T cells in the presence of hydrocortisone in vitro and abrogate the action of cortisol in mTBI mice. The investigation demonstrated that the number of circulating T cells in the early phase of TBI was positively correlated with T cell infiltration and inflammatory responses as well as cell death at the cerebral cortex and hippocampus beneath the impact site.ConclusionsDecreases in intracellular cAMP might be part of the mechanism behind cortisol-mediated blockade of T cell egress. The study argues strongly for a protective role of cortisol-induced immune suppression in the early stage of TBI.

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Section: Discussionmentioning

confidence: 99%

Cortisol-induced immune suppression by a blockade of lymphocyte egress in traumatic brain injury

Dong

Liu

Bhayana

et al. 2016

J Neuroinflammation

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“…However, a clinical trail (MRC CRSAH) involved 10008 patients conducted in more than 40 countries demonstrated that corticosteroids does not have any therapeutic effect on TBI patients in spite of the time of administration post-injury [7] . Our previous research also proved that high-dose methylprednisolone can aggravate cellular apoptosis and BBB damage in hypothalamus, which can exacerbate the acute critical illness-related corticosteroid insufficiency associated with TBI [8][9] . Molecular therapy for TBI has become the research hotspot in recent years.…”

Section: Research Highlightmentioning

confidence: 79%

miR-21, a potential therapeutic target of alleviating blood-brain barrier damage after traumatic brain injury

Lei

Zhang

2015

RNA Dis

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Traumatic brain injury (TBI)is a disease with high morbidity and leads to high rate of disability and mortality. The blood-brain barrier (BBB) damage is an important pathological change in brain after TBI, which impacts the development and prognosis of the disease. In our previous research, we have reported that miR-21-5p in neurons can exert an anti-apoptosis effect, and promote the restoration of injured BBB after TBI. Up-regulation of miR-21-5p level in brain can amplify the above functions of miR-21-5p, thus alleviate BBB damage and improve the neurological prognosis of TBI. miR-21-3p, which is generated from pre-miR-21 at the same time with miR-21-5p, has been reported to play significant roles in regulating cellular apoptosis, immuno-inflammatory responses and the expression of angiogenic factors in various diseases. We made a summary of previous research on miR-21-3p and inferred that miR-21-3p could exert an important impact on BBB damage after TBI. Taken together, miR-21 is a vital miRNA that impacts the restoration of injured BBB, thus it could be a potential therapeutic target for interventions in TBI.

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“…Nevertheless, the pathophysiology of TBI is a complex process, and we recognize that it is highly susceptible to several extrinsic factors, including those that are aversive or rehabilitative in nature (Griesbach et al, ; M.F. Chen et al, ; Klemenhagen et al, ). Although future studies examining physiology in the absence of behavioral testing would be informative, it is important to note that our findings may be more clinically relevant given that the majority of TBI patients undergo cognitive behavioral testing following injury.…”

Section: Discussionmentioning

confidence: 99%

Opposing effects of traumatic brain injury on excitatory synaptic function in the lateral amygdala in the absence and presence of preinjury stress

Klein

Acheson

Dawson

et al. 2015

J of Neuroscience Research

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Traumatic brain injury (TBI) is a leading cause of death and disability among young adults and is highly prevalent among recently deployed military personnel. Survivors of TBI often experience cognitive and emotional deficits, suggesting that long-term effects of injury may disrupt neuronal function in critical brain regions, including the amygdala, which is involved in emotion and fear memory. Amygdala hyperexcitability has been reported in both TBI and posttraumatic stress disorder patients, yet little is known regarding the effects of combined stress and TBI on amygdala structure and function at the neuronal level. The present study seeks to determine how the long-term effects of preinjury foot-shock stress and TBI interact to influence synaptic plasticity in the lateral amygdala (LA) of adult male C57BL/6J mice by using whole-cell patch clamp electrophysiology 2-3 months postinjury. In the absence of stress, TBI resulted in a significant increase in membrane excitability and spontaneous excitatory postsynaptic currents (sEPSCs) in LA pyramidal-like neurons. Foot-shock stress in the absence of TBI also resulted in increased sEPSC activity. In contrast, when preinjury stress and TBI occurred in combination, sEPSC activity was significantly decreased compared with either condition alone. There were no significant differences in inhibitory activity or total dendritic length among any of the treatment groups. These results demonstrate that stress and TBI may be contributing to amygdala hyperexcitability via different mechanisms and that these pathways may counterbalance each other with respect to long-term pathophysiology in the LA.

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Stress-dose hydrocortisone reduces critical illness-related corticosteroid insufficiency associated with severe traumatic brain injury in rats

Cited by 32 publications

References 56 publications

Cortisol-induced immune suppression by a blockade of lymphocyte egress in traumatic brain injury

Cortisol-induced immune suppression by a blockade of lymphocyte egress in traumatic brain injury

miR-21, a potential therapeutic target of alleviating blood-brain barrier damage after traumatic brain injury

Opposing effects of traumatic brain injury on excitatory synaptic function in the lateral amygdala in the absence and presence of preinjury stress

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