Matrix metalloproteinase-3 expression profile differentiates adaptive and maladaptive synaptic plasticity induced by traumatic brain injury.

The interaction between extracellular matrix (ECM) and regulatory matrix metalloproteinases (MMPs) is important in establishing and maintaining synaptic connectivity. By using fluid percussion traumatic brain injury (TBI) and combined TBI and bilateral entorhinal cortical lesion (TBI + BEC), we previously demonstrated that hippocampal stromelysin-1 (MMP-3) expression and activity increased during synaptic plasticity. We now report a temporal analysis of MMP-3 protein and mRNA response to TBI during both degenerative (2 day) and regenerative (7, 15 day) phases of reactive synaptogenesis. MMP-3 expression during successful synaptic reorganization (following unilateral entorhinal cortical lesion; UEC) was compared with MMP-3 expression when normal synaptogenesis fails (after combined TBI + BEC insult). Increased expression of MMP-3 protein and message was observed in both models at 2 days postinjury, and immuohistochemical (IHC) colocalization suggested that reactive astrocytes contribute to that increase. By 7 days postinjury, model differences in MMP-3 were observed. UEC MMP-3 mRNA was equivalent to control, and MMP-3 protein was reduced within the deafferented region. In contrast, enzyme mRNA remained elevated in the maladaptive TBI + BEC model, accompanied by persistent cellular labeling of MMP-3 protein. At 15 days survival, MMP-3 mRNA was normalized in each model, but enzyme protein remained higher than paired controls. When TBI + BEC recovery was enhanced by the N-methyl-D-aspartate antagonist MK-801, 7-day MMP-3 mRNA was significantly reduced. Similarly, MMP inhibition with FN-439 reduced the persistent spatial learning deficits associated with TBI + BEC insult. These results suggest that MMP-3 might differentially affect the sequential phases of reactive synaptogenesis and exhibit an altered pattern when recovery is perturbed.

Elevation of hippocampal MMP-3 expression and activity during trauma-induced synaptogenesis.

The matrix metalloproteinase (MMP) enzyme family contributes to the regulation of a variety of brain extracellular matrix molecules. In order to assess their role in synaptic plasticity following traumatic brain injury (TBI), we compared expression of stromelysin-1 (MMP-3) protein and mRNA in two rodent models of TBI exhibiting different levels of recovery: adaptive synaptic plasticity following central fluid percussion injury and maladaptive synaptic plasticity generated by combined TBI and bilateral entorhinal cortical lesion (TBI + BEC). We sampled the hippocampus at 7 days postinjury, targeting a selectively vulnerable brain region and a survival interval exhibiting rapid synaptogenesis. We report elevated expression of hippocampal MMP-3 mRNA and protein after TBI. MMP-3 immunohistochemical staining showed increased protein levels relative to sham-injured controls, primarily localized to cell bodies within the deafferented dendritic laminae. Injury-related differences in MMP-3 protein were also observed. TBI alone elevated MMP-3 immunobinding over the stratum lacunosum moleculare (SLM), inner molecular layer and hilus, while TBI + BEC generated more robust increases in MMP-3 reactivity within the deafferented SLM and dentate molecular layer (DML). Double labeling with GFAP confirmed the presence of MMP-3 within reactive astrocytes induced by each injury model. Semi-quantitative RT-PCR revealed that MMP-3 mRNA also increased after each injury, however, the combined insult induced a much greater elevation than fluid percussion alone: 1.9-fold vs. 79%, respectively. In the TBI + BEC model, MMP-3 up-regulation was spatio-temporally correlated with increased enzyme activity, an effect which was attenuated with the neuroprotective compound MK-801. These results show that distinct pathological conditions elicited by TBI can differentially affect MMP-3 expression during reactive synaptic plasticity. Notably, these effects are both transcriptional and translational and are correlated with functionally active enzyme.

Traumatic brain injury-induced changes in gene expression and functional activity of mitochondrial cytochrome C oxidase.

Traumatic brain injury (TBI) is documented to have detrimental effects on CNS metabolism, including alterations in glucose utilization and the depression of mitochondrial oxidative phosphorylation. Studies on mitochondrial metabolism have also provided evidence for reduced activity of the cytochrome oxidase complex of the electron transport chain (complex IV) after TBI and an immediate (lhr) reduction in mitochondrial state 3 respiratory rate, which can persist for up to 14 days postinjury. Using differential display methods to screen for differences in gene expression, we have found that cytochrome c oxidase II (COII), a mitochondrial encoded subunit of complex IV, is upregulated following TBI. Since COII carries a binding site for cytochrome c in the respiratory chain, and since it is required for the passage of chain electrons to molecular oxygen, driving the production of ATP, we hypothesized that metabolic dysfunction resulting from TBI alters COII gene expression directly, perhaps influencing the synaptic plasticity that occurs during postinjury recovery processes. To test this hypothesis, we documented COII mRNA expression and complex IV (cytochrome c oxidase) functional activity at 7 days postinjury, focusing on the long-term postinjury period most closely associated with synaptic reorganization. Both central fluid percussion TBI and combined TBI and bilateral entorhinal cortical lesion were examined. At 7 days survival, differential display, RT-PCR, and Northern blot analysis of hippocampal RNA from both TBI and combined insult models showed a significant induction of COII mRNA. This long-term elevation in COII gene expression was supported by increases in COII immunobinding. By contrast, cytochrome oxidase histochemical activity within tissue sections from injured brains suggested a reduction of complex IV activity within the TBI cases, but not within animals subjected to the combined insult. These differences in cytochrome c oxidase activity were supported by in vitro assay of complex IV using cerebral cortical and hippocampal tissues. Our present results support the hypothesis that COII is selectively vulnerable to TBI and that COII differences may indicate the degree of metabolic dysfunction induced by different pathologies. Taken together, such data will better define the role of metabolic function in long-term recovery after TBI.

Subtle alterations in NMDA-stimulated cyclic GMP levels following lateral fluid percussion brain injury.

This study examined whether NMDA-stimulated cyclic GMP levels were altered at two different time points following lateral fluid percussion injury. At 60 min and 15 days postinjury, the left and right hippocampi were dissected and chopped into mini-prisms. Each hippocampus was divided into five equal parts and incubated with either the phosphodiesterase inhibitor IBMX (3-isobutyl-1-methylxanthine, 500 microM) alone, IBMX and N-methyl-D-aspartic acid (NMDA) OR IBMX, NMDA, and glycine (10 MM). Two concentrations of NMDA were used: 500 or 1,000 microM. Tissues were then assayed for levels of cyclic GMP. Results indicated that there were no changes in basal levels of cyclic GMP at either postinjury time point. At 60 min postinjury, there were no significant main effects for injury or drug concentration. There was a significant injury x side interaction effect with increased levels of NMDA-stimulated cyclic GMP in the hippocampus ipsilateral to the injury impact and decreased cyclic GMP levels in the contralateral hippocampus. There were no significant alterations in NMDA-stimulated cyclic GMP levels at 15 days postinjury. The data from this study indicated that NMDA-stimulated cyclic GMP accumulation is differentially altered in the hippocampus ipsilateral and contralateral to the site of the injury at 1 h after injury, but is normalized by 15 days postinjury. These findings implicate NMDA-mediated intracellular signaling processes in the acute excitotoxic response to injury.

Interactive pathology following traumatic brain injury modifies hippocampal plasticity.

Hippocampal afferents terminate in well-defined laminae, with a morphological segregation of input which has facilitated the interpretation of structural and functional synaptic reorganization observed after deafferentiation. Historically, most studies have induced hippocampal plasticity using single deafferentiation paradigms, however recent evidence indicates that sequential lesions or models based on combined injuries alter the pattern of dendritic structural reorganization and axonal sprouting. A better understanding of the interaction between deafferentiation-induced structural remodeling and other pathological mechanisms, which commonly coexist in central nervous system trauma, will require the use of combined injury paradigms where such plasticity can be systematically manipulated. In the context of traumatic brain injury, we have developed an injury model that combines the excessive neuroexcitation of concussive brain insult with the targeted hippocampal deafferentation of entorhinal cortical lesion. This review discusses the role of such an approach in defining posttraumatic hippocampal vulnerability, out- lining the effects of combined pathology on hippocampal circuitry, and considers the greater clinical relevance inherent in the combined injury approach. Experimental evidence obtained with the combined concussive plus deafferentation model is presented, detailing the interaction of injury components and highlighting structural, behavioral and electrophysiological evidence for maladaptive hippocampal plasticity. Subsequent studies utilizing pharmacological methods to manipulate this maladaptive plasticity are described, first targeting glutamate, acetylcholine and dopamine receptor pathways, and then applying select drugs to explore how various molecular mechanisms underlying combined neuroexcitation and deafferentation pathology might affect regenerative plasticity. Evidence implicating postinjury neurotransmitter modulation of exeitatory/inhibitory homeostasis, metalloproteinase regulation of extracellular matrix, and mitochondrial metabolic vulnerability is presented. Finally, the effect of age on outcome after combined neuroexcitation plus deafferentation insult is considered, as well as how future studies in such combined injury models will better define the full range of postinjury hippocampal plasticity possible after brain trauma.

Postinjury administration of L-deprenyl improves cognitive function and enhances neuroplasticity after traumatic brain injury.

The rat model of combined central fluid percussion traumatic brain injury (TBI) and bilateral entorhinal cortical lesion (BEC) produces profound, persistent cognitive deficits, sequelae associated with human TBI. In contrast to percussive TBI alone, this combined injury induces maladaptive hippocampal plasticity. Recent reports suggest a potential role for dopamine in CNS plasticity after trauma. We have examined the effect of the dopamine enhancer l-deprenyl on cognitive function and neuroplasticity following TBI. Rats received fluid percussion TBI, BEC alone, or combined TBI + BEC lesion and were treated once daily for 7 days with l-deprenyl, beginning 24 h after TBI alone and 15 min after BEC or TBI + BEC. Postinjury motor assessment showed no effect of l-deprenyl treatment. Cognitive performance was assessed on days 11-15 postinjury and brains from the same cases examined for dopamine beta-hydroxylase immunoreactivity (DBH-IR) and acetylcholinesterase (AChE) histochemistry. Significant cognitive improvement relative to untreated injured cases was observed in both TBI groups following l-deprenyl treatment; however, no drug effects were seen with BEC alone. l-Deprenyl attenuated injury-induced loss in DBH-IR over CA1 and CA3 after TBI alone. However, after combined TBI + BEC, l-deprenyl was only effective in protecting CA1 DBH-IR. AChE histostaining in CA3 was significantly elevated with l-deprenyl in both injury models. After TBI + BEC, l-deprenyl also increased AChE in the dentate molecular layer relative to untreated injured cases. These results suggest that dopaminergic/noradrenergic enhancement facilitates cognitive recovery after brain injury and that noradrenergic fiber integrity is correlated with enhanced synaptic plasticity in the injured hippocampus.

Presynaptic excitability changes following traumatic brain injury in the rat.

Pathological processes affecting presynaptic terminals may contribute to morbidity following traumatic brain injury (TBI). Posttraumatic widespread neuronal depolarization and elevated extracellular potassium and glutamate are predicted to alter the transduction of action potentials in terminals into reliable synaptic transmission and postsynaptic excitation. Evoked responses to orthodromic single- and paired-pulse stimulation were examined in the CA1 dendritic region of hippocampal slices removed from adult rats following fluid percussion TBI. The mean duration of the extracellularly recorded presynaptic volley (PV) increased from 1.08 msec in controls to 1.54 msec in slices prepared at 1 hr postinjury. There was a time-dependent recovery of this injury effect, and PV durations at 2 and 7 days postinjury were not different from controls. In slices removed at 1 hr postinjury, the initial slopes of field excitatory postsynaptic potentials (fEPSPs) were reduced to 36% of control values, and input/output plots revealed posttraumatic deficits in the transfer of excitation from pre- to postsynaptic elements. Manipulating potassium currents with 1.0 mM tetraethylammonium or elevating potassium ion concentration to 7.5 mM altered evoked responses but did not replicate the injury effects to PV duration. Paired-pulse facilitation of fEPSP slopes was significantly elevated at all postinjury survivals: 1 hr, 2 days, and 7 days. These results suggest two pathological processes with differing time courses: 1) a transient impairment of presynaptic terminal functioning affecting PV durations and the transduction of afferent activity in the terminals to reliable synaptic excitation and 2) a more protracted deficit to the plasticity mechanisms underlying paired-pulse facilitation.

Metabotropic glutamate receptor protein alterations after traumatic brain injury in rats.

Glutamate toxicity, mediated via ion channel-linked receptors, plays a key role in traumatic brain injury (TBI) pathophysiology. Excessive glutamate release after TBI also activates protein G-linked metabotropic glutamate receptors (mGluRs). We performed Western blot and immunohistochemical analysis with antibodies for group 1 and 2 mGluRs in hippocampal and cortex tissue at 7 and 15 days after lateral fluid-percussion TBI in rats. Protein homogenates of brain tissue were separated on 7.5% sodium dodecyl sulfate (SDS)-polyacrylamide gels, transferred to nitrocellulose, and incubated with either antibodies recognizing both mGluR2 and mGluR3 or antibodies against mGluR5. Equivalent protein loading of lanes was confirmed by using beta-actin antibody. Immunoreactive proteins were revealed with enhanced chemiluminescence and relative optical density of Western blots quantified by computerized image analysis. At 7 days after TBI, mGluR2/3 immunobinding ipsilateral to the fluid-percussion injury was reduced by 28% in hippocampus and 25% in cortex in comparison with the contralateral hemisphere (p < .05). mGluR5 immunobinding ipsilateral to the fluid-percussion injury was reduced by 20% in hippocampus and 27% in cortex (p < .05). At 15 days after TBI, the decreases in immunobinding were no longer significant. Immunohistochemical staining with the same antibodies revealed density changes congruent with the Western blot results. These data suggest that TBI produces an alteration in receptor protein expression that spontaneously recovers by 15 days after injury.

Glutamate antagonism during secondary deafferentation enhances cognition and axo-dendritic integrity after traumatic brain injury.

The combination of central fluid percussion traumatic brain injury (TBI) followed 24 h later by a bilateral entorhinal cortical deafferentation (BEC) produces profound cognitive morbidity. We recently showed that MK-801 given prior to TBI in this insult improved spatial memory for up to 15 days. In the present study we examine whether MK-801 treatment of the BEC component in the combined insult model affects cognitive recovery. Two strategies for drug treatment were tested. Fifteen minutes prior to the BEC lesion in the combined insult, rats were given i.p. doses of either 3 mg/kg (acute group) or 1 mg/kg (chronic group) MK-801. The acute group received no further injections, whereas the chronic group received 1 mg/kg MK-801 i.p. twice a day for 2 days post-BEC lesion. Two additional groups of animals received BEC lesion alone and either acute or chronic MK-801 treatment identical with the combined insult cases. Each group was then assessed for spatial memory deficits with the Morris water maze at days 11-15 and 60-64 postinjury. Both acute and chronic MK-801 treatment in the combined insult group significantly reduced spatial memory deficits at 15 days postinjury relative to untreated injured cases (P < .01). This reduction appeared more robust at 15 days and persisted for up to 64 days in the chronically treated group (P < .05). By contrast, neither acute nor chronic MK-801 treatment affected memory performance with the BEC insult alone. Immunocytochemical localization of parvalbumin showed that chronic administration of MK-801 in the combined insult cases attenuated the injury-induced dendritic atrophy of inhibitory neurons in the dentate gyrus and area CA1. Synaptophysin immunobinding revealed that chronic MK-801 treatment of the BEC component of the combined insult normalized the distribution of presynaptic terminals within the dentate gyrus. These results suggest that cognitive deficits produced by head trauma involving both neuroexcitation and deafferentation can be attenuated with chronic application of glutamatergic antagonists during the period of deafferentation injury and that this attenuation is correlated with axo-dendritic integrity.

Managing the pain of bone metastases in the home environment.

This article presents an in-depth review of the medical, pharmacological and nursing interventions needed to relieve the pain experienced with bone metastases. Covered areas include: Pathophysiology. Clinical presentation of bone pain. Treatment options. Therapeutic interventions. The hospice nurse as an agent of hope. In addition, a comprehensive presentation of nonopioid medications used in managing bone pain is provided in table format.

Antiproliferative effect of c-myc antisense phosphorothioate oligodeoxynucleotides in malignant glioma cells.

OBJECTIVE: To improve the prognosis for primary malignant tumors of the central nervous system, new therapeutic strategies are needed. Antisense oligodeoxynucleotides (ODNs) offer the potential to block the expression of specific genes within cells. The proto-oncogene c-myc has long been implicated in the control of normal cell growth and its deregulation in the development of neoplasia. We therefore reasoned that a strategy using ODNs complementary to c-myc messenger ribonucleic acid would be a potent inhibitor of glioma cell proliferation. METHODS: A variety of antisense, sense, and scrambled (15-mer) phosphorothioate ODNs targeted to rat and human c-myc messenger ribonucleic acid were synthesized and added to the media of cultured RT-2 cells (a rat glioblastoma cell line). Cell growth was assessed by 3-[4,5-dimethylthiazol-2yl]-2,5-diphenyltetrazolium bromide dye assay 1 to 5 days after adding the ODNs. c-Myc protein expression was analyzed by Western blot analysis. The stability of the ODNs was confirmed by gel electrophoresis. RESULTS: Compared with cultures containing standard media, two of three antisense ODNs significantly inhibited the growth of glioma cells, whereas sense and scrambled sequence ODNs did not significantly affect cell growth at the concentrations tested. A human c-myc antisense sequence, which differed from the rat sequence by one base substitution, also had an inhibitory effect on RT-2 cells. Western blot analysis demonstrated that expression of immunoreactive c-Myc protein was also greatly reduced in the rat antisense ODN-treated cells (and not in sense-, scrambled-, or control-treated cells). The degree of reduction of c-Myc protein expression correlated well with the decrease in cell growth observed with several antisense ODNs. Phosphorothioate ODNs were stable in cell culture media for at least 5 days. CONCLUSION: These results suggest that c-Myc plays a critical role in glioma cell proliferation and demonstrate that antisense ODNs can suppress proto-oncogene expression and inhibit the proliferation of glioma cells. Our results indicate that the antiproliferative activity of these ODNs was mediated predominantly through sequence-specific antisense mechanisms, but that sequence-specific nonantisense effects may also contribute to the strongest effects demonstrated. These findings support a potential role for antisense strategies designed to inhibit c-myc expression in the treatment of malignant gliomas.

Effect of prior receptor antagonism on behavioral morbidity produced by combined fluid percussion injury and entorhinal cortical lesion.

We have used an animal model of traumatic brain injury (TBI) that incorporates both the neurotransmitter toxicity of fluid percussion TBI and deafferentation of bilateral entorhinal cortical (BEC) lesion to explore whether administration of muscarinic cholinergic or N-methyl-D-aspartate glutamatergic antagonists prior to injury ameliorates cognitive morbidity. Fifteen minutes prior to moderate central fluid percussion TBI, rats were given intraperitoneal injections of either scopolamine (1.0 mg/kg) or MK-801 (0.3 mg/kg) and 24 hr later underwent BEC lesion. Body weight was followed for 5 days postinjury, as was beam balance and beam walk performance to assure motor recovery prior to spatial memory testing. Each group was assessed for spatial memory deficits with the Morris water maze at short term (days 11-15) and long-term (60-64 days) postinjury intervals and then compared with untreated combined insult and sham-injured controls. Results showed that each drug significantly elevated body weight relative to untreated injured cases. Both scopolamine and MK-801 reduced beam balance deficits, whereas neither drug had a significant effect on beam walk deficits. Interestingly, short-term cognitive deficits assessed on days 11-15 were differentially affected by the two drugs: MK-801 pretreatment enhanced the recovery of spatial memory performance, whereas scopolamine pretreatment did not. Long-term (days 60-64) deficits in spatial memory were not altered by pretreatment with either drug. Our results suggest that, unlike fluid percussion TBI alone, behavioral impairment may require more select intervention when deafferentation is part of the head trauma pathology.

The effects of traumatic brain injury on inhibition in the hippocampus and dentate gyrus.

Changes in inhibitory neuronal functioning may contribute to morbidity following traumatic brain injury (TBI). Evoked responses to orthodromic paired-pulse stimulation were examined in the hippocampus and dentate gyrus at 2 and 15 days following lateral fluid percussion TBI in adult rats. The relative strength of inhibition was estimated by measuring evoked paired pulses in three afferent systems: the CA3 commissural input to the CA1 region of the hippocampus; the entorhinal cortical input to the ipsilateral CA1 area (temporoammonic system); and the entorhinal input to the ipsilateral dentate gyrus (perforant path). In addition to quantitative electrophysiological estimates of inhibitory efficacy, levels of gamma-aminobutyric acid (GABA) were qualitatively examined with immunohistochemical techniques. Effects of TBI on paired-pulse responses were pathway-specific, and dependent on time postinjury. At 2 days following TBI, inhibition of population spikes was significantly reduced in the CA3 commissural input to CA1, which contrasted with injury-induced increases in inhibition in the dentate gyrus seen at both 2 and 15 days postinjury. Low-level stimulation, subthreshold for population spikes, also revealed changes in paired-pulse facilitation of field extracellular postsynaptic potentials (fEPSPs), which depended on fiber pathway and time postinjury. Significant injury-induced electrophysiological changes were almost entirely confined to the hemisphere ipsilateral to injury. Intensity of GABA immunobinding exhibited a regional association with electrophysiological indices of inhibition, with the most pronounced increases in GABA levels and inhibition found in the dentate gyrus. TBI-induced effects showed a regional pattern within the hippocampus which corresponds closely to inhibitory changes reported to follow ischemia and kindling. This degree of similarity in outcome following dissimilar injuries may indicate common mechanisms in the nervous system response to injury.

The effect of combined fluid percussion and entorhinal cortical lesions on long-term potentiation.

Among the pathological processes initiated by traumatic brain injury are excessive neuroexcitation and target cell deafferentation. The current study examines the contribution of these injury components, separately as well as their combined effect, on postinjury alterations in the capacity for long-term potentiation and the immunolocalization of N-methyl-D-aspartate receptors and GABA. Adult rats underwent central fluid percussion traumatic brain injury, electrolytic bilateral entorhinal cortex lesions, or a combined injury of both procedures separated by 24 h. At two or 15 days postinjury, the capacity for long-term potentiation of the Schaffer collateral-commissural input to CA1 was measured in acute electrophysiological recordings. Entorhinal cortical lesions resulted in time-dependent increases in the effectiveness of tetanic stimulation to elevate population postsynaptic potentials and population spike amplitudes. These lesions also resulted in a marked intensification in the density of N-methyl-D-aspartate receptors in the CA1 stratum lacunosum-moleculare. All injury conditions that included fluid percussion as a component (alone or in combined injuries) produced a persistent impairment in long-term potentiation of the evoked population postsynaptic potentials. Thus, in combined injuries, the presence of concussion-induced neuroexcitation attenuated deafferentation-induced response increases. Both N-methyl-D-aspartate receptor and GABA immunobinding following combined injuries were also reduced relative to those observed following entorhinal lesions alone. The present results suggest that a process of receptor plasticity, possibly involving reactive synaptogenesis, may contribute to postdeafferentation enhancements of long-term potentiation, and that a traumatic brain insult will attenuate these enhancements. This interaction of different injury components suggests that recovery of function following brain injury may be enhanced by pharmacological reduction of neuroexcitation during postinjury intervals of reactive receptor plasticity.

Increases in protein kinase C gamma immunoreactivity in the spinal cord dorsal horn of rats with painful mononeuropathy.

Eight days after chronic constrictive sciatic nerve injury (CCI), protein kinase C gamma (PKC gamma) immunoreactivity reliably increased in the spinal cord dorsal horn of CCI rats with demonstrable thermal hyperalgesia as compared to sham-operated controls. Such PKC gamma immunostaining was observed primarily in neuronal somata (ipsilateral > contralateral, laminae I-II > III-IV), indicating postsynaptic sites of PKC gamma increases. Both the development of thermal hyperalgesia and the increase in PKC gamma immunoreactivity in CCI rats were prevented by once daily intrathecal administration with 10 nmol MK-801 for 7 days. The present results provide further evidence for a role of PKC in N-methyl-D-aspartate (NMDA) receptor-mediated mechanisms of thermal hyperalgesia.

Impaired gustatory neophobia following traumatic brain injury in rats.

To investigate the function of the amygdala following traumatic brain injury (TBI), rats were tested on a gustatory neophobia task that is sensitive to amygdala and hippocampal damage. Rats were either injured at a moderate level of fluid percussion injury (2.1 atm) or surgically prepared but not injured (sham-injury). Seven days after injury (n = 8) or sham injury (n = 9), rats were habituated to the testing chamber without food items present for 30 min. All rats were then food deprived. Twenty-four hours later, rats were placed in the testing chamber for 30 min and allowed to eat freely from four dishes of different foods: rat chow, raisins, potatoes, and cookies. Results showed that injured and sham-injured rats did not differ in their ability to find hidden food, suggesting that TBI does not produce an enduring impairment of olfaction. There was also no difference in the total amount of food eaten between injured and sham groups (p > 0.05). The percentage of each type of food consumed did differ between the two groups with sham controls consuming more familiar food (rat chow) compared to the unfamiliar foods (p < 0.01). The injured animals distributed their eating evenly among the four foods with no particular preference for any one food (p < 0.05). This pattern of eating behavior in injured animals is similar to animals that have lesions to both the hippocampus and amygdala (Sutherland and McDonald, 1990). Therefore, the results of this experiment suggest that, in addition to the hippocampus, the amygdala may also contribute to the behavioral changes observed following TBI.

Increases in protein kinase C gamma immunoreactivity in the spinal cord of rats associated with tolerance to the analgesic effects of morphine.

Our previous studies have indicated a critical role of protein kinase C (PKC) in intracellular mechanisms of tolerance to morphine analgesia. In the present experiments, we examined (1) the cellular distribution of a PKC isoform (PKC gamma) in the spinal cord dorsal horn of rats associated with morphine tolerance by utilizing an immunocytochemical method and (2) the effects of the N-methyl-D-aspartate receptor antagonist MK-801 on tolerance-associated PKC gamma changes. In association with the development of tolerance to morphine analgesia induced by once daily intrathecal administration of 10 micrograms morphine for eight days, PKC gamma immunoreactivity was clearly increased in the spinal cord dorsal horn of these same rats. Within the spinal cord dorsal horn of morphine tolerant rats, there were significantly more PKC gamma immunostained neurons in laminae I-II than in laminae III-IV and V-VI. Such PKC gamma immunostaining was observed primarily in neuronal somata indicating a postsynaptic site of PKC gamma increases. Moreover, both the development of morphine tolerance and the increase in PKC gamma immunoreactivity were prevented by co-administration of morphine with 10 nmol MK-801 between Day 2 and Day 7 of the eight day treatment schedule. In contrast, PKC gamma immunoreactivity was not increased in rats receiving a single i.t. administration of 10 micrograms morphine on Day 8, nor did repeated treatment with 10 nmol MK-801 alone change baseline levels of PKC gamma immunoreactivity. These results provide further evidence for the involvement of PKC in NMDA receptor-mediated mechanisms of morphine tolerance.

Combined fluid percussion brain injury and entorhinal cortical lesion: a model for assessing the interaction between neuroexcitation and deafferentation.

Laboratory studies suggest that excessive neuroexcitation and deafferentation contribute to long-term morbidity following human head injury. Because no current animal model of traumatic brain injury (TBI) has been shown to combine excessive neuroexcitation and significant levels of deafferentation, we developed a rat model combining the neuroexcitation of fluid percussion TBI with subsequent entorhinal cortical (EC) deafferentation. In this paradigm, moderate fluid percussion TBI was induced in each rat, followed 24 h later by bilateral EC lesion (BEC). Six conditions were examined: (1) fluid percussion TBI followed 24 h later by bilateral EC lesion (TBEC), (2) fluid percussion TBI (TBI), (3) bilateral EC lesion (BEC), (4) sham fluid percussion TBI (SHAM), (5) TBI followed 24 h later by unilateral EC lesion (TUEC), and (6) unilateral EC lesion (UEC). The first four groups were assessed for motor (with beam-balance and beam-walk testing) and cognitive deficits (with the Morris water maze) and hippocampal morphology (with immunocytochemistry and electron microscopy). The TUEC and UEC groups were assessed for cognitive deficits alone. Motor deficits were greater in the TBEC injury than in TBI or sham alone; however, no significant difference was observed between the TBEC and BEC conditions in motor performance. Cognitive deficits were of a greater magnitude in the combined TBEC injury model relative to each individual insult. These cognitive deficits appeared to be additive for the two experimental injuries, BEC deafferentation producing deficits intermediate between TBI and TBEC insults. Morphologic analysis of the dentate gyrus molecular layer at 15 days after TBEC showed that the distribution of synaptophysin-positive presynaptic terminals was distinct from that observed after either TBI or BEC alone. Specifically, the laminar pattern of presynaptic rearrangement induced by BEC lesion did not occur after TBEC injury. The present results show that axonal injury and its attendant deafferentation, when coupled with traumatically induced neuroexcitation, produce an enhancement of the morbidity associated with TBI. Moreover, they indicate that this model can effectively be used to study the interaction between neuroexcitation and synaptic plasticity.