Hari Shanker Sharma

Nanoparticles aggravate heat stress induced cognitive deficits, blood-brain barrier disruption, edema formation and brain pathology.

Our knowledge regarding the influence of nanoparticles on brain function in vivo during normal or hyperthermic conditions is still lacking. Few reports indicate that when nanoparticles enter into the central nervous system (CNS) they may induce neurotoxicity. On the other hand, nanoparticle-induced drug delivery to the brain enhances neurorepair processes. Thus, it is likely that the inclusion of nanoparticles in body fluid compartments alters the normal brain function and/or its response to additional stress, e.g., hyperthermia. New data from our laboratory show that nanoparticles derived from metals (e.g., Cu, Ag or Al, approximately 50-60nm) are capable of inducing brain dysfunction in normal animals and aggravating the brain pathology caused by whole-body hyperthermia (WBH). Thus, normal animals treated with nanoparticles (for 1 week) exhibited mild cognitive impairment and cellular alterations in the brain. Subjection of these nanoparticle-treated rats to WBH resulted in profound cognitive and motor deficits, exacerbation of blood-brain barrier (BBB) disruption, edema formation and brain pathology compared with naive animals. These novel observations suggest that nanoparticles enhance brain pathology and cognitive dysfunction in hyperthermia. The possible mechanisms of nanoparticle-induced exacerbation of brain damage in WBH and its functional significance in relation to our current knowledge are discussed in this review.

Pathophysiology of brain edema and cell changes following hyperthermic brain injury

Publisher Summary This chapter focuses on brain edema formation in heat stress and its contribution to cell injury. In addition, the basic concepts of brain edema formation, including various biomechanical and biophysical factors, and chemical mediators involved in this mechanism are reviewed. Based on the experimental observations, a new pharmacological approach to reduce edema formation and cell injury by modifying the breakdown of the blood–brain barrier in heat stress is discussed. Brain edema is a serious complication of various neurological diseases following traumatic, ischemic, or hypoxic injuries to the central nervous system. The early clinical symptoms of brain edema comprise signs of headache, nausea, vomiting, disturbances of consciousness, and occasionally coma. Progression of edema leads to brain herniation and vascular infarction that are common causes of death. The effects of hyperthermia on brain dysfunction is reduced by advancing age, anaesthesia, or prior heat experience indicating that the age and physiological states of the animals before heat exposure are important determining factors for the outcome of thermal brain damage.

Influence of Nanoparticles on Blood–Brain Barrier Permeability and Brain Edema Formation in Rats

Nanoparticles are small sized (1-100 nm) particles derived from transition metals, silver, copper, aluminum, silicon, carbon and metal oxides that can easily cross the blood-brain barrier (BBB) and/or produce damage to the barrier integrity by altering endothelial cell membrane permeability. However, the influence of nanoparticles on BBB integrity is still not well-known. In this investigation, effect of nanoparticles derived from Ag, Al and Cu (50-60 nm) on BBB permeability in relation to brain edema formation was examined in a rat model. Intravenous (30 mg/kg), intraperitoneal (50 mg/kg) or intracerebral (20 microg in 10 microL) administration of Ag, Cu or Al nanoparticles disrupted the BBB function to Evans blue albumin (EBA) and radioiodine in rats 24 h after administration and induced brain edema formation. The leakage of Evans blue dye was observed largely in the ventral surface of brain and in the proximal frontal cortex. The dorsal surfaces of cerebellum showed mild to moderate EBA staining. These effects were most pronounced in animals that received Ag or Cu nanoparticles compared to Al nanoparticles through intravenous routes. These observations are the first to suggest that nanoparticles can induce brain edema formation by influencing BBB breakdown in vivo.

Alterations in Blood–Brain Barrier Function by Morphine and Methamphetamine

Abstract:  The possibility that stress associated with morphine and amphetamine administration or withdrawal will influence the blood–brain barrier (BBB) and brain dysfunction was examined in a rodent model. Repeated daily administration of morphine (10 mg/kg, i.p.) resulted in drug dependence in rats on the sixth day and onwards. Measurement of the BBB permeability to large molecule tracers normally bound to proteins, e.g., Evans blue albumin and radioiodine ([131]Iodine) did not show any leakage on the 12th day of drug dependence. On the other hand, spontaneous withdrawal of morphine on day 1 resulted in profound stress symptoms. These symptoms were much more intense on the second day of morphine withdrawal. Alterations in the BBB to protein tracers were seen in several regions of the brain. This increase in BBB to protein tracers was most pronounced on the second day of morphine withdrawal. These rats also exhibited abnormal neuronal, glial and stress protein, the heat‐shock protein 72 kD (HSP‐72 kD) response. On the other hand, acute administration of methamphetamine (40 mg/kg, i.p.) in mice resulted in marked extravasation of endogenous serum protein as seen with increased expression of albumin immunohistochemistry. These observations suggest that psychostimulants and associated stress are capable to influence the brain function, probably through modifying the BBB function, not reported earlier.

Involvement of nitric oxide in acute spinal cord injury: an immunocytochemical study using light and electron microscopy in the rat

The possibility that nitric oxide participates in the pathophysiology of spinal cord injury was examined using a constitutive isoform of neuronal nitric oxide synthase immunoreactivity in a rat model. Spinal cord trauma was produced by making an incision into the right dorsal horn of the T10-11 segments. Five h after trauma, a marked upregulation of NOS-immunostained neurons was seen in the perifocal T9 and T12 segments of the cord. The immunolabelling was most pronounced in the dorsal horn of the ipsilateral side. Topical application of an antiserum to nitric oxide synthase (NOS) 2 min after injury prevented the trauma-induced upregulation of NOS-immunoreactivity. In contrast, application of preabsorbed serum or L-NAME, an inhibitor to NOS, was ineffective in reducing the induction of NOS-immunoreactivity. Trauma caused a marked expansion of the cord and resulted in marked cell changes. This expansion and cell reaction was significantly reduced following application of NOS antiserum but it was not seen after application of preabsorbed antiserum or L-NAME. Our results for the first time show that a focal trauma to the spinal cord has the capacity to upregulate neuronal NOS immunoreactivity and that application of NOS antiserum has a neuro protective effect. This indicates that nitric oxide is somehow involved in the pathogenesis of secondary injuries after spinal cord trauma.

Permeability of the blood-brain barrier depends on brain temperature.

Increased permeability of the blood-brain barrier (BBB) has been reported in different conditions accompanied by hyperthermia, but the role of brain temperature per se in modulating brain barrier functions has not been directly examined. To delineate the contribution of this factor, we examined albumin immunoreactivity in several brain structures (cortex, hippocampus, thalamus and hypothalamus) of pentobarbital-anesthetized rats (50 mg/kg i.p.), which were passively warmed to different levels of brain temperature (32-42 degrees C). Similar brain structures were also examined for the expression of glial fibrillary acidic protein (GFAP), an index of astrocytic activation, water and ion content, and morphological cell abnormalities. Data were compared with those obtained from drug-free awake rats with normal brain temperatures (36-37 degrees C). The numbers of albumin- and GFAP-positive cells strongly correlate with brain temperature, gradually increasing from approximately 38.5 degrees C and plateauing at 41-42 degrees C. Brains maintained at hyperthermia also showed larger content of brain water and Na(+), K(+) and Cl(-) as well as structural abnormalities of brain cells, all suggesting acute brain edema. The latter alterations were seen at approximately 39 degrees C, gradually progressed with temperature increase, and peaked at maximum hyperthermia. Temperature-dependent changes in albumin immunoreactivity tightly correlated with GFAP immunoreactivity, brain water, and numbers of abnormal cells; they were found in each tested area, but showed some structural specificity. Notably, a mild BBB leakage, selective glial activation, and specific cellular abnormalities were also found in the hypothalamus and piriform cortex during extreme hypothermia (32-33 degrees C); in contrast to hyperthermia these changes were associated with decreased levels of brain water, Na(+) and K(+), suggesting acute brain dehydration. Therefore, brain temperature per se is an important factor in regulating BBB permeability, alterations in brain water homeostasis, and subsequent structural abnormalities of brain cells.

Brain edema and breakdown of the blood-brain barrier during methamphetamine intoxication : critical role of brain hyperthermia

To clarify the role of brain temperature in permeability of the blood–brain barrier (BBB), rats were injected with methamphetamine (METH 9 mg/kg) at normal (23 °C) and warm (29 °C) environmental conditions and internal temperatures were monitored both centrally (nucleus accumbens, NAcc) and peripherally (skin and nonlocomotor muscle). Once NAcc temperatures peaked or reached 41.5 °C (a level suggesting possible lethality), animals were administered Evans blue dye (protein tracer that does not normally cross the BBB), rapidly anaesthetized, perfused and had their brains removed. All METH‐treated animals showed brain and body hyperthermia associated with relative skin hypothermia, suggesting metabolic activation coupled with peripheral vasoconstriction. While METH‐induced NAcc temperature elevation varied from 37.60 to 42.46 °C (or 1.2–5.1 °C above baseline), it was stronger at 29 °C (+4.13 °C) than 23 °C (+2.31 °C). Relative to control, METH‐treated animals had significantly higher brain levels of water, Na+, K+ and Cl–, suggesting brain edema, and intense immunostaining for albumin, indicating breakdown of the BBB. METH‐treated animals also showed strong immunoreactivity for glial fibrillary acidic protein (GFAP), possibly suggesting acute abnormality or damage of astrocytes. METH‐induced changes in brain water, albumin and GFAP correlated linearly with NAcc temperature (r = 0.93, 0.98 and 0.98, respectively), suggesting a key role of brain hyperthermia in BBB permeability, development of brain edema and subsequent functional and structural neural abnormalities. Therefore, along with a direct destructive action on neural cells and functions, brain hyperthermia, via breakdown of the BBB, may be crucial for both decompensation of brain functions and cell injury following acute METH intoxication, possibly contributing to neurodegeneration resulting from chronic drug use.

Spinal nerve lesion alters blood–spinal cord barrier function and activates astrocytes in the rat

Abstract Alterations in the spinal cord microenvironment in a neuropathic pain model in rats comprising right L‐4 spinal nerve lesion were examined following 1, 2, 4 and 10 weeks using albumin and glial fibrillary acidic protein (GFAP) immunoreactivity. Rats subjected to nerve lesion showed pronounced activation of GFAP indicating astrocyte activation, and exhibited marked leakage of albumin, suggesting defects of the blood–spinal cord barrier (BSCB) function in the corresponding spinal cord segment. The intensities of these changes were most prominent in the gray matter of the lesioned side compared to the contralateral cord in both the dorsal and ventral horns. The most marked changes in albumin and GFAP immunoreaction were seen after 2 weeks and persisted with mild intensities even after 10 weeks. Distortion of nerve cells, loss of neurons and general sponginess were evident in the gray matter of the spinal cord corresponding to the lesion side. These nerve cell and glial cell changes was mainly evident in the areas showing leakage of endogenous albumin in the spinal cord. These novel observations indicate that chronic nerve lesion has the capacity to induce a selective increase in local BSCB permeability that could be instrumental in nerve cell and glial cell activation. These findings may be relevant to our current understanding on the pathophysiology of neuropathic pain.

Rapid morphological brain abnormalities during acute methamphetamine intoxication in the rat: an experimental study using light and electron microscopy.

This study describes morphological abnormalities of brain cells during acute methamphetamine (METH) intoxication in the rat and demonstrates the role of hyperthermia, disruption of the blood-brain barrier (BBB) and edema in their development. Rats with chronically implanted brain, muscle and skin temperature probes and an intravenous (i.v.) catheter were exposed to METH (9 mg/kg) at standard (23 degrees C) and warm (29 degrees C) ambient temperatures, allowing for the observation of hyperthermia ranging from mild to pathological (38-42 degrees C). When brain temperature peaked or reached a level suggestive of possible lethality (>41.5 degrees C), rats were injected with Evans blue (EB), rapidly anesthetized, perfused, and their brains were taken for further analyses. Four brain areas (cortex, hippocampus, thalamus and hypothalamus) were analyzed for EB extravasation, water and electrolyte (Na(+), K(+), Cl(-)) contents, immunostained for albumin and glial fibrillary acidic protein (GFAP), and examined for neuronal, glial and axonal alterations using standard light and electron microscopy. These examinations revealed profound abnormalities in neuronal, glial, and endothelial cells, which were stronger with METH administered at 29 degrees C than 23 degrees C and tightly correlated with brain and body hyperthermia. These changes had some structural specificity, but in each structure they tightly correlated with increases in EB levels, the numbers of albumin-positive cells, and water and ion contents, suggesting leakage of the BBB, acutely developing brain edema, and serious shifts in brain ion homeostasis as leading factors underlying brain abnormalities. While most of these acute structural and functional abnormalities appear to be reversible, they could trigger subsequent cellular alterations in the brain and accelerate neurodegeneration-the most dangerous complication of chronic amphetamine-like drug abuse.

Prostaglandins modulate alterations of microvascular permeability, blood flow, edema and serotonin levels following spinal cord injury: an experimental study in the rat.

The possibility that prostaglandins influence edema formation, microvascular permeability increase and reduction of blood flow following spinal cord trauma was examined in a rat model. In addition, the influence of prostaglandins on serotonin metabolism of the traumatized spinal cord was evaluated. Trauma to spinal cord (2-mm-deep and 5-mm-long incision in the right dorsal horn of T10-11 segments) resulted in a profound increase of the water content 5 h after injury. At this time, the microvascular permeability to Evans Blue and [131I]sodium was increased by 457 and 394%, respectively. The blood flow was reduced by 30%. The serotonin (5-hydroxytryptamine) content of the spinal cord increased by 205%. The plasma serotonin level rose by 152% in the injured group of rats. Pretreatment with indomethacin (10 mg/kg, i.p.) 30 min before trauma significantly reduced the edema and microvascular permeability increase. The local spinal cord blood flow of traumatized animals was partially restored. The increases of serotonin levels of the spinal cord and plasma were significantly attenuated. These beneficial effects of indomethacin were not present in rats given a lower dose (5 mg/kg). Indomethacin in either dose did not influence these parameters of control rats without trauma to the cord. Since indomethacin is a potential inhibitor of prostaglandins synthesis our observations indicate: (i) that prostaglandins participate in many microvascular responses (permeability changes, edema, blood flow) occurring after a trauma to the spinal cord; (ii) that these effects of the drug seem to be dose dependent, and (iii) that the prostaglandins may influence the serotonin metabolism following trauma to the spinal cord.