Exercise therapy and recovery after SCI: evidence that shows early intervention improves recovery of function.

STUDY DESIGN: This was designed as an experimental study. OBJECTIVES: Locomotor training is one of the most effective strategies currently available for facilitating recovery of function after an incomplete spinal cord injury (SCI). However, there is still controversy regarding the timing of treatment initiation for maximal recovery benefits. To address this issue, the present study compares the effects of exercise initiated in the acute and secondary phase of SCI. SETTING: Texas A&M University, College Station, TX, USA. METHODS: Rats received a moderate spinal contusion injury and began an exercise program 1 (D1-EX) or 8 days (D8-EX) later. They were individually placed into transparent exercise balls for 60 min per day, for 14 consecutive days. Control rats were placed in exercise balls that were rendered immobile. Motor and sensory recovery was assessed for 28 days after injury. RESULTS: The D1-EX rats recovered significantly more locomotor function (BBB scale) than controls and D8-EX rats. Moreover, analyses revealed that rats in the D8-EX group had significantly lower tactile reactivity thresholds compared with control and D1-EX rats, and symptoms of allodynia were not reversed by exercise. Rats in the D8-EX group also had significantly larger areas of damage across spinal sections caudal to the injury center compared with the D1-EX group. CONCLUSION: These results indicate that implementing an exercise regimen in the acute phase of SCI maximizes the potential for recovery of function.

Timing in the absence of supraspinal input I: variable, but not fixed, spaced stimulation of the sciatic nerve undermines spinally-mediated instrumental learning.

Rats with complete spinal transections are capable of acquiring a simple instrumentally trained response. If rats receive shock to one hind limb when the limb is extended (controllable shock), the spinal cord will learn to hold the leg in a flexed position that minimizes shock exposure. If shock is delivered irrespective of leg position, subjects do not exhibit an increase in flexion duration and subsequently fail to learn when tested with controllable shock (learning deficit). Just 6 min of variable intermittent shock produces a learning deficit that lasts 24 h. Evidence suggests that the neural mechanisms underlying the learning deficit may be related to those involved in other instances of spinal plasticity (e.g. windup, long-term potentiation). The present paper begins to explore these relations by demonstrating that direct stimulation of the sciatic nerve also impairs instrumental learning. Six minutes of electrical stimulation (mono- or biphasic direct current [DC]) of the sciatic nerve in spinally transected rats produced a voltage-dependent learning deficit that persisted for 24 h (experiments 1-2) and was dependent on C-fiber activation (experiment 7). Exposure to continuous stimulation did not produce a deficit, but intermittent burst or single pulse (as short as 0.1 ms) stimulation (delivered at a frequency of 0.5 Hz) did, irrespective of the pattern (fixed or variable) of stimulus delivery (experiments 3-6, 8). When the duration of stimulation was extended from 6 to 30 min, a surprising result emerged; shocks applied in a random (variable) fashion impaired subsequent learning whereas shocks given in a regular pattern (fixed spacing) did not (experiments 9-10). The results imply that spinal neurons are sensitive to temporal relations and that stimulation at regular intervals can have a restorative effect.

The effect of gabapentin and ketorolac on allodynia and conditioned place preference in antibody-induced inflammation.

BACKGROUND: Glucose-6-phosphate isomerase and collagen type II antibody-induced arthritis models (K/BxN and CAIA, respectively) have an inflammatory and a post-inflammatory phase. Both phases display robust tactile allodynia. In previous work, inflammatory phase allodynia was reversed by gabapentin and ketorolac, whereas in late phase only gabapentin was effective. Here, we sought to determine if the effects of these two drugs during the early and late phases of the two arthritis models were observed in the conditioned place preference (CPP) paradigm, indicating a differential drug effect on the aversive state. METHODS: Male C57BL/6 mice received K/BxN serum intraperitoneally, while male BALB/c mice received collagen type II antibody cocktail intravenously. After onset of inflammation and allodynia, we assessed effects of i.p. gabapentin (100 mg/kg) or ketorolac (15 mg/kg) using a CPP paradigm: 2 days adaptation, 2 days conditioning (vehicle in morning and drug in afternoon), preference testing on day 5. RESULTS: Consistent with the effects upon allodynia, both gabapentin and ketorolac produced a preference for the drug-paired compartment in the early phase of the K/BxN model, while gabapentin, but not ketorolac, resulted in a place preference during late phase. In the CAIA model, consistent with differential effects upon allodynia, gabapentin produced a preference in the early phase and a trend in the late phase, whereas ketorolac was ineffective at either time. CONCLUSIONS: CPP validated the aversive state in the inflammatory and post-inflammatory phases of the K/BxN and CAIA arthritis models and correspondence between the anti-hyperpathic pharmacology as defined by thresholds and CPP.

Differences in cisplatin-induced mechanical allodynia in male and female mice.

BACKGROUND: Chemotherapeutic agents, such as cisplatin, are known to induce a persistent polyneuropathy. The mechanisms underlying the development of this pain are complex, and have only been investigated rodent models using male animals, despite an equivalent presentation of neuropathy between the sexes, clinically. METHODS: Male and female C57Bl/6, Tlr3(-/-) Tlr4(-/-) , Myd88(-/-) , Trif(lps2) and Myd88(-/-) /Trif(lps2) mice received 6 i.p. injections of cisplatin (2.3 mg/kg/day) every other day over the course of 2 weeks. Changes in tactile threshold were monitored during this time, continuing through day 23, using von Frey filaments. RESULTS: Male WT mice develop a persistent tactile allodynia resulting from cisplatin administration. Female mice develop an initial allodynia, but thresholds return to baseline by day 23. Deletion of TLR3, TLR4, MyD88 and Trif/MyD88 protects animals from the development of cisplatin-induced polyneuropathy, and there are no sex differences. Trif(lps2) male mice show a persistent tactile allodynia following cisplatin administration, while female mice show a reduced allodynia, and remain higher in threshold than their male counterparts. On day 18, animals were given the analgesic gabapentin, and thresholds were tested 45 min after. Gabapentin was effective in transiently reversing mechanical allodynia in those mice with lowered thresholds. CONCLUSIONS: It is important to continue examining both sexes in various pain models, as a mononeuropathy and polyneuropathy show sex differences in pain development and the role of TLR signalling.

Temporal regularity determines the impact of electrical stimulation on tactile reactivity and response to capsaicin in spinally transected rats.

Nociceptive plasticity and central sensitization within the spinal cord depend on neurobiological mechanisms implicated in learning and memory in higher neural systems, suggesting that the factors that impact brain-mediated learning and memory could modulate how stimulation affects spinal systems. One such factor is temporal regularity (predictability). The present paper shows that intermittent hindleg shock has opposing effects in spinally transected rats depending upon whether shock is presented in a regular or irregular (variable) manner. Variable intermittent legshock (900 shocks) enhanced mechanical reactivity to von Frey stimuli (hyperreactivity), whereas 900 fixed-spaced legshocks produced hyporeactivity. The impact of fixed-spaced shock depended upon the duration of exposure; a brief exposure (36 shocks) induced hyperreactivity whereas an extended exposure (900 shocks) produced hyporeactivity. The enhanced reactivity observed after variable shock was most evident 60-180 min after treatment. Fixed and variable intermittent stimulation applied to the sciatic nerve, or the tail, yielded a similar pattern of results. Stimulation had no effect on thermal reactivity. Exposure to fixed-spaced shock, but not variable shock, attenuated the enhanced mechanical reactivity (EMR) produced by treatment with hindpaw capsaicin. The effect of fixed-spaced stimulation lasted 24h. Treatment with fixed-spaced shock also attenuated the maintenance of capsaicin-induced EMR. The results show that variable intermittent shock enhances mechanical reactivity, while an extended exposure to fixed-spaced shock has the opposite effect on mechanical reactivity and attenuates capsaicin-induced EMR.

Intermittent noxious stimulation following spinal cord contusion injury impairs locomotor recovery and reduces spinal brain-derived neurotrophic factor-tropomyosin-receptor kinase signaling in adult rats.

Intermittent nociceptive stimulation following a complete transection or contused spinal cord injury (SCI) has been shown to exert several short- and long-lasting negative consequences. These include maladaptive spinal plasticity, enhanced mechanical allodynia, and impaired functional recovery of locomotor and bladder functions. The neurotrophin, brain-derived neurotrophic factor (BDNF) has been shown to play an important role in adaptive plasticity and also to restore functions following SCI. This suggests that the negative behavioral effects of shock are most likely related to corresponding changes in BDNF spinal levels. In this study, we investigated the cellular effects of nociceptive stimulation in contused adult rats focusing on BDNF, its receptor, tropomyosin-receptor kinase (TrkB), and the subsequent downstream signaling system. The goal was to determine whether the behavioral effect of stimulation is associated with concomitant cellular changes induced during the initial post-injury period. Quantitative real-time polymerase chain reaction (qRT-PCR) and Western blotting were used to assess changes in the mRNA and/or protein levels of BDNF, TrkB, and the downstream signaling proteins calcium-calmodulin kinase II (CaMKII) and extracellular related kinase 1/2 (ERK1/2) at 1 h, 24 h, and 7 days following administration of intermittent noxious shock to the tail of contused subjects. In addition, recovery of locomotor function (Basso, Beattie, and Bresnahan [BBB] score) was assessed daily for the first week after injury. The results showed that, although nociceptive stimulation failed to induce any changes in gene expression at 1 h, it significantly reduced the expression of BDNF, TrkB, ERK2, and CaMKII at 24 h. In general, changes in gene expression were spatially localized to the dorsal spinal cord. In addition, locomotor recovery was impaired by shock. Evidence is also provided suggesting that shock engages a neuronal circuitry without having any negative effects on neuronal survival at 24 h. These results suggest that nociceptive activity following SCI decreases BDNF and TrkB levels, which may significantly contribute to diminished functional recovery.