Anesthetic and physiologic effects of tiletamine, zolazepam, ketamine, and xylazine combination (TKX) in feral cats undergoing surgical sterilization

Tiletamine (12.5 mg), zolazepam (12.5 mg), ketamine (20 mg), and xylazine (5 mg) (TKX; 0.25 ml, IM) combination was evaluated as an anesthetic in 22 male and 67 female adult feral cats undergoing sterilization at high-volume sterilization clinics. Cats were not intubated and breathed room air. Oxygen saturation (SpO2), mean blood pressure (MBP), heart rate (HR), respiration rate (RR), and core body temperature were recorded. Yohimbine (0.25 ml, 0.5 mg, IV) was administered at the completion of surgery. TKX produced rapid onset of lateral recumbency (4±1 min) and surgical anesthesia of sufficient duration to complete surgical procedures in 92% of cats. SpO2 measured via a lingual pulse oximeter probe averaged 92±3% in male cats and 90±4% in females. SpO2 fell below 90% at least once in most cats. MBP measured by oscillometry averaged 136±30 mm Hg in males and 113±29 mm Hg in females. MBP increased at the onset of surgical stimulation suggesting incomplete anti-nociceptive properties. HR averaged 156±19 bpm, and RR averaged 18±8 bpm. Neither parameter varied between males and females or over time. Body temperature decreased significantly over time, declining to 38.0±0.8 °C at the time of reversal in males and 36.6±0.8 °C at the time of reversal in females. Time from anesthetic reversal to sternal recumbency was prolonged (72±42 min). Seven cats (8%) required an additional dose of TKX to maintain an adequate plane of anesthesia at the onset of surgery, and this was associated with significantly longer recovery times (108±24 min).

Identification and Characterization of GAL-021 as a Novel Breathing Control Modulator

BACKGROUND

The authors describe the preclinical pharmacological properties of GAL-021, a novel peripheral chemoreceptor modulator.

METHODS

The ventilatory effects of GAL-021 were characterized using tracheal pneumotachometry (n = 4 to 6), plethysmography (n = 5 to 6), arterial blood gas analyses (n = 6 to 11), and nasal capnography (n = 3 to 4) in naive animals and those subjected to morphine-induced respiratory depression. Morphine analgesia in rats was evaluated by tail-flick test (n = 6). Carotid body involvement in GAL-021 ventilatory effects was assessed by comparing responses in intact and carotid sinus nerve-transected rats. Hemodynamic effects of GAL-021 were evaluated in urethane-anesthetized rats (n = 7). The pharmacological profile of GAL-021 in vitro was investigated using radioligand binding, enzyme inhibition, and cellular electrophysiology assays.

RESULTS

GAL-021 given intravenously stimulated ventilation and/or attenuated opiate-induced respiratory depression in rats, mice, and nonhuman primates, without decreasing morphine analgesia in rats. GAL-021 did not alter mean arterial pressure but produced a modest increase in heart rate. Ventilatory stimulation in rats was attenuated by carotid sinus nerve transection. GAL-021 inhibited KCa1.1 in GH3 cells, and the evoked ventilatory stimulation was attenuated in Slo1 mice lacking the pore-forming α-subunit of the KCa1.1 channel.

CONCLUSIONS

GAL-021 behaved as a breathing control modulator in rodents and nonhuman primates and diminished opioid-induced respiratory depression without compromising opioid analgesia. It acted predominantly at the carotid body, in part by inhibiting KCa1.1 channels. Its preclinical profile qualified the compound to enter clinical trials to assess effects on breathing control disorders such as drug (opioid)-induced respiratory depression and sleep apnea.

Effects of intraperitoneal administration of gabapentin on the minimum alveolar concentration of isoflurane in adult male rats

Gabapentin has been used to treat a variety of conditions in both human and veterinary medicine, including seizures, neuropathies and chronic pain. However, little information is known about the effects of gabapentin on the minimum alveolar concentration (MAC) of volatile anaesthetics. In this study, we investigated the effect of intraperitoneal administration of gabapentin on isoflurane MAC in adult male rats and hypothesized that gabapentin would decrease MAC in a dose-dependent manner. Using a standard MAC study protocol, we compared five treatment groups (G) receiving 0 (G(0)), 30 (G(30)), 100 (G(100)), 300 (G(300)) and 1000 (G(1000)) mg/kg gabapentin intraperitoneally and compared post-drug MAC values among groups and with corresponding baseline MAC values determined in each group prior to drug testing. The average baseline isoflurane MAC value was 1.45 ± 0.17%, which did not differ significantly between groups (1.47 ± 0.23% [G(30)], 1.46 ± 0.23% [G(100)], 1.48 ± 0.18% [G(300)] and 1.42 ± 0.2% [G(1000)]). In the G(300) and G(1000) groups, the isoflurane MAC value decreased significantly by 19% and 18%, respectively, from corresponding baseline values (P< 0.05, when compared with G(0)). Linear regression analysis revealed a negative correlation between blood gabapentin concentration and percent change in MAC (R(2) = 0.43; P< 0.05) but not dose. In conclusion, high-dose intraperitoneal gabapentin decreased isoflurane MAC. However, the effect was small and not dose-dependent, and is unlikely to be clinically significant.

Breathing patterns after mid-cervical spinal contusion in rats

Respiratory failure is the leading cause of death after cervical spinal injury. We hypothesized that incomplete cervical spinal injuries would alter respiratory pattern and initiate plasticity in the neural control of breathing. Further, we hypothesized that the severity of cervical spinal contusion would correlate with changes in breathing pattern. Fourteen days after C4-C5 contusions, respiratory frequency and tidal volume were measured in unanesthetized Sprague Dawley rats in a whole body plethysmograph. Phrenic motor output was monitored in the same rats which were anesthetized, vagotomized, paralyzed and ventilated to eliminate and/or control sensory feedback that could alter breathing patterns. The extent of spinal injury was approximated histologically by measurements of the injury-induced cyst area in transverse sections; cysts ranged from 2 to 28% of spinal cross-sectional area, and had a unilateral bias. In unanesthetized rats, the severity of spinal injury correlated negatively with tidal volume (R(2)=0.85; p<0.001) and positively with breathing frequency (R(2)=0.65; p<0.05). Thus, the severity of C4-C5 spinal contusion dictates post-injury breathing pattern. In anesthetized rats, phrenic burst amplitude was decreased on the side of injury, and burst frequency correlated negatively with contusion size (R(2)=0.51; p<0.05). A strong correlation between unanesthetized breathing pattern and the pattern of phrenic bursts in anesthetized, vagotomized and ventilated rats suggests that changes in respiratory motor output after spinal injury reflect, at least in part, intrinsic neural mechanisms of CNS plasticity initiated by injury.

Suspected acute meperidine toxicity in a dog

OBSERVATIONS

A 22-month-old male neutered Coton De Tulear dog was presented for upper gastrointestinal endoscopy under general anesthesia. The anesthetic plan included premedication with intramuscular meperidine (4 mg kg(-1)) but meperidine was inadvertently administered at ten-fold this dose. Within 5 minutes, the dog was unresponsive to external stimulation, and by 10 minutes post-injection developed generalized signs of central nervous system (CNS) excitement. Initial therapy included inspired oxygen supplementation, and single intravenous (IV) doses of diazepam (0.68 mg kg(-1)) and naloxone (0.03 mg kg(-1)) to no effect. A second dose of diazepam (0.46 mg kg(-1), IV) abolished most of the signs of CNS excitement. General anesthesia was induced and the endoscopy performed. Time to extubation was initially prolonged, but administering naloxone (final dose 0.1 mg kg(-1), IV) to effect enabled extubation. After naloxone, the dog became agitated, noise sensitive, and had leg and trunk muscle twitches. Diazepam (0.30 mg kg(-1), IV) abolished these signs and the dog became heavily sedated and laterally recumbent. Naloxone administration was continued as a constant rate infusion (0.02 mg kg(-1) hour(-1), IV) until approximately 280 minutes post-meperidine injection, at which time the dog suddenly sat up. Occasional twitches of the leg and trunk muscles were observed during the night. The dog was discharged the next day appearing clinically normal.

CONCLUSIONS

Given that the CNS excitatory effects of normeperidine are not a mu opioid receptor effect, the use of naloxone should be considered carefully when normeperidine excitotoxicity is suspected. Benzodiazepines may be beneficial in ameliorating clinical signs of normeperidine excitotoxicity.

Extended anaesthesia and nasotracheal intubation of a red kangaroo (Macropus rufus)

Anaesthesia requires maintenance of a patent airway. Nasotracheal intubation of a red kangaroo (Macropus rufus) was performed when the inability to open the animal’s mouth prevented orotracheal intubation. Nasotracheal intubation was easy to perform, secured the airway and permitted delivery of supplemental oxygen, isoflurane and intermittent positive pressure ventilation.

The effects of urethane on the isoflurane minimum alveolar concentration in rats

Urethane is often used as a sole anaesthetic agent for non-recovery studies in laboratory animals. However, the use of urethane is controversial, in part, because the electroencephalogram after urethane administration is similar to the electroencephalogram recorded from unanaesthetized animals. Here, we assessed the minimum alveolar concentration (MAC)-sparing effects of urethane by measuring the effect of two doses of urethane on the MAC of isoflurane in male Sprague Dawley rats. Isoflurane MAC was measured before and after intravenous administration of urethane at 1.0 g/kg (Group G1, n = 6) and 1.5 g/kg (Group G1.5, n = 6), or an equal volume of 0.9% saline (Group Gs, n = 6). Baseline isoflurane MAC was not statistically different between groups (isoflurane concentration: 1.47 ± 0.08%, 1.40 ± 0.19% and 1.42 ± 0.12% for G1, G1.5 and Gs, respectively). Intravenous injection of saline did not alter isoflurane MAC (post-saline MAC: 1.43 ± 0.11%). After urethane administration, isoflurane MAC decreased in a dose-dependent manner (new MAC G1: 0.19 ± 0.06%; G1.5: 0.03 ± 0.01%; P < 0.05). The isoflurane MAC after 1.5 g/kg urethane was not significantly different from room air isoflurane concentrations (0.01 ± 0.01%), demonstrating a 100% MAC reduction at this dose. In conclusion, high-dose urethane (1.5 g/kg intravenously) was suitable as a sole anaesthetic agent to prevent gross purposeful movement during the conditions of the study, whereas low-dose urethane (1.0 g/kg intravenously) was not.

Neuronal hyperexcitability in the dorsal horn after painful facet joint injury

Excessive cervical facet capsular ligament stretch has been implicated as a cause of whiplash-associated disorders following rear-end impacts, but the pathophysiological mechanisms that produce chronic pain in these cases remain unclear. Using a rat model of C6-C7 cervical facet joint capsule stretch that produces sustained mechanical hyperalgesia, the presence of neuronal hyperexcitability was characterized 7 days after joint loading. Extracellular recordings of spinal dorsal horn neuronal activity between C6 and C8 (117 neurons) were obtained from anesthetized rats, with both painful and non-painful behavioral outcomes established by the magnitude of capsule stretch. The frequency of neuronal firing during noxious pinch (p<0.0182) and von Frey filaments applications (4-26g) to the forepaw was increased (p<0.0156) in the painful group compared to the non-painful and sham groups. In addition, the incidence and frequency of spontaneous and after discharge firing were greater in the painful group (p<0.0307) relative to sham. The proportion of cells in the deep laminae that responded as wide dynamic range neurons also was increased in the painful group relative to non-painful or sham groups (p<0.0348). These findings suggest that excessive facet capsule stretch, while not producing visible tearing, can produce functional plasticity of dorsal horn neuronal activity. The increase in neuronal firing across a range of stimulus magnitudes observed at day 7 post-injury provides the first direct evidence of neuronal modulation in the spinal cord following facet joint loading, and suggests that facet-mediated chronic pain following whiplash injury is driven, at least in part, by central sensitization.

Differential expression of respiratory long-term facilitation among inbred rat strains

We tested the hypotheses that: (1) long-term facilitation (LTF) following acute intermittent hypoxia (AIH) varies among three inbred rat strains: Fischer 344 (F344), Brown Norway (BN) and Lewis rats and (2) ventral cervical spinal levels of genes important for phrenic LTF (pLTF) vary in association with pLTF magnitude. Lewis and F344, but not BN rats exhibited significant increases in phrenic and hypoglossal burst amplitude 60min post-AIH that were significantly greater than control experiments without AIH, indicating strain differences in phrenic (98%, 56% and 20%, respectively) and hypoglossal LTF (66%, 77% and 5%, respectively). Ventral spinal 5-HT(2A) receptor mRNA and protein levels were higher in F344 and Lewis versus BN, suggesting that higher 5-HT(2A) receptor levels are associated with greater pLTF. More complex relationships were found for 5-HT(7), BDNF and TrkB mRNA. BN had higher 5-HT(7) and TrkB mRNA versus F344; BN and Lewis had higher BDNF mRNA levels versus F344. Genetic variations in serotonergic function may underlie strain differences in AIH-induced pLTF.

Spinal adenosine A2(A) receptor inhibition enhances phrenic long term facilitation following acute intermittent hypoxia

Phrenic long term facilitation (pLTF) is a form of respiratory plasticity induced by acute intermittent hypoxia. pLTF requires spinal serotonin receptor activation, new BDNF synthesis and TrkB receptor activation. Spinal adenosine 2A (A(2A)) receptor activation also elicits phrenic motor facilitation, but by a distinct mechanism involving new TrkB synthesis. Because extracellular adenosine increases during hypoxia, we hypothesized that A(2A) receptor activation contributes to acute intermittent hypoxia (AIH)-induced pLTF. A selective A(2A) receptor antagonist (MSX-3, 8 microg kg(-1), 12 microl) was administered intrathecally (C4) to anaesthetized, vagotomized and ventilated male Sprague-Dawley rats before AIH (three 5 min episodes, 11% O(2)). Contrary to our hypothesis, pLTF was greater in MSX-3 versus vehicle (aCSF) treated rats (97 +/- 6% vs. 49 +/- 4% at 60 min post-AIH, respectively; P < 0.05). MSX-3 and aCSF treated rats did not exhibit facilitation without AIH (time controls; 7 +/- 5% and 9 +/- 9%, respectively; P > 0.05). A second A(2A) receptor antagonist (ZM2412385, 7 microg kg(11), 7 microl) enhanced pLTF (85 +/- 11%, P < 0.05), but an adenosine A(1) receptor antagonist (DPCPX, 3 microg kg(-1), 10 microl) had no effect (51% +/- 8%, P > 0.05), indicating specific A(2A) receptor effects. Intrathecal methysergide (306 microg kg(-1), 15 microl) blocked AIH-induced pLTF in both MSX-3 and aCSF treated rats, confirming that enhanced pLTF is serotonin dependent. Intravenous MSX-3 (140 microg kg(-1), 1 ml) enhanced both phrenic (104 +/- 7% vs. 57 +/- 5%, P < 0.05) and hypoglossal LTF (46 +/- 13% vs. 28 +/- 10%; P < 0.05). In conclusion, A(2A) receptors constrain the expression of serotonin-dependent phrenic and hypoglossal LTF following AIH. A(2A) receptor antagonists (such as caffeine) may exert beneficial therapeutic effects by enhancing the capacity for AIH-induced respiratory plasticity.

Spinal NMDA receptor activation is necessary for de novo, but not the maintenance of, A2a receptor-mediated phrenic motor facilitation

Adenosine 2a (A2a) receptor agonists elicit persistent increases in phrenic nerve activity by transactivating the neurotrophin receptor, TrkB, near phrenic motoneurons. Our working model proposes that A2a receptor-mediated TrkB receptor activation strengthens glutamatergic synapses onto phrenic motoneurons. Activation of glutamate N-methyl d-aspartate (NMDA) receptors has been implicated in other models of phrenic motor plasticity. Thus we hypothesized that NMDA receptor activation also would contribute to A2a receptor-mediated phrenic motor facilitation. Adult male Sprague-Dawley rats were anesthetized with urethane, mechanically ventilated, neuromuscularly paralyzed, and bilaterally vagotomized. The A2a receptor agonist CGS-21680 and the NMDA receptor-channel blocker MK-801 were administered intrathecally over the C4 spinal segment. Phrenic nerve activity was recorded before, during, and after drug administration. MK-801 (concentration range 0.1, 1.0, 10.0, and 100 microM) was administered 30 min before CGS-21680 (50 microM). MK-801 dose-dependently blocked A2a receptor-mediated phrenic motor facilitation. When administered at 60 min post-CGS-21680, MK-801 prevented further increases in phrenic nerve activity compared with the CGS-21680 alone (CGS-21680 alone at 120 min: 114 +/- 19%; CGS-21680 and MK-801 at 60 min post-CGS-21680: 61 +/- 11%, above baseline, P < 0.05) but did not return phrenic motor output to baseline values. Our data suggest that NMDA receptor activation is necessary for de novo A2a receptor-mediated phrenic motor facilitation and that the maintenance of preexisting phrenic motor facilitation does not involve NMDA receptor-dependent mechanisms.

Spinal synaptic enhancement with acute intermittent hypoxia improves respiratory function after chronic cervical spinal cord injury

Respiratory insufficiency is the leading cause of death after high-cervical spinal cord injuries (SCIs). Although respiratory motor recovery can occur with time after injury, the magnitude of spontaneous recovery is limited. We hypothesized that partial respiratory motor recovery after chronic cervical SCI could be strengthened using a known stimulus for spinal synaptic enhancement, intermittent hypoxia. Phrenic motor output was recorded before and after intermittent hypoxia from anesthetized, vagotomized, and pump-ventilated control and C2 spinally hemisected rats at 2, 4, and 8 weeks after injury. Weak spontaneous phrenic motor recovery was present in all C2-injured rats via crossed spinal synaptic pathways that convey bulbospinal inspiratory premotor drive to phrenic motoneurons on the side of injury. Intermittent hypoxia augmented crossed spinal synaptic pathways [phrenic long-term facilitation; pLTF] for up to 60 min after hypoxia at 8 weeks, but not 2 weeks, after injury. Ketanserin, a serotonin 2A receptor antagonist, administered before intermittent hypoxia at 8 weeks after injury prevented pLTF. Serotonergic innervation near phrenic motoneurons was assessed after injury. The limited magnitude of pLTF at 2 weeks was associated with an injury-induced reduction in serotonin-containing nerve terminals in the vicinity of phrenic motoneurons ipsilateral to C2 hemisection. Thereafter, pLTF magnitude progressively increased with the recovery of serotonergic innervation in the phrenic motor nucleus. Intermittent hypoxia (or pLTF) has intriguing possibilities as a therapeutic tool, because its greatest efficacy may be in patients with chronic SCI, a time when most patients have already achieved maximal spontaneous functional recovery.

Recovery of phrenic activity and ventilation after cervical spinal hemisection in rats

We tested two hypotheses: 1) that the spontaneous enhancement of phrenic motor output below a C2 spinal hemisection (C2HS) is associated with plasticity in ventrolateral spinal inputs to phrenic motoneurons; and 2) that phrenic motor recovery in anesthetized rats after C2HS correlates with increased capacity to generate inspiratory volume during hypercapnia in unanesthetized rats. At 2 and 4 wk post-C2HS, ipsilateral phrenic nerve activity was recorded in anesthetized, paralyzed, vagotomized, and ventilated rats. Electrical stimulation of the ventrolateral funiculus contralateral to C2HS was used to activate crossed spinal synaptic pathway phrenic motoneurons. Inspiratory phrenic burst amplitudes ipsilateral to C2HS were larger in the 4- vs. 2-wk groups ( P < 0.05); however, no differences in spinally evoked compound phrenic action potentials could be detected. In unanesthetized rats, inspiratory volume and frequency were quantified using barometric plethysmography at inspired CO2 fractions between 0.0 and 0.07 (inspired O2 fraction 0.21, balance N2) before and 2, 3, and 5 wk post-C2HS. Inspiratory volume was diminished, and frequency enhanced, at 0.0 inspired CO2 fraction ( P < 0.05) 2-wk post-C2HS; further changes were not observed in the 3- and 5-wk groups. Inspiratory frequency during hypercapnia was unaffected by C2HS. Hypercapnic inspiratory volumes were similarly attenuated at all time points post-C2HS ( P < 0.05), thereby decreasing hypercapnic minute ventilation ( P < 0.05). Thus increases in ipsilateral phrenic activity during 4 wk post-C2HS have little impact on the capacity to generate inspiratory volume in unanesthetized rats. Enhanced crossed phrenic activity post-C2HS may reflect plasticity associated with spinal axons not activated by our ventrolateral spinal stimulation.

Cervical spinal cord injury upregulates ventral spinal 5-HT2A receptors

Following chronic C2 spinal hemisection (C2HS), crossed spinal pathways to phrenic motoneurons exhibit a slow, spontaneous increase in efficacy by a serotonin (5-HT)-dependent mechanism associated with 5-HT2A receptor activation. Further, the spontaneous appearance of cross-phrenic activity following C2HS is accelerated and enhanced by exposure to chronic intermittent hypoxia (CIH). We hypothesized that chronic C2HS would increase 5-HT and 5-HT2A receptor expression in ventral cervical spinal segments containing phrenic motoneurons. In addition, we hypothesized that CIH exposure would further increase 5-HT and 5-HT2A receptor density in this region. Control, sham-operated, and C2HS Sprague-Dawley rats were studied following normoxia or CIH (11% O2-air; 5-min intervals; nights 7-14 post-surgery). At 2 weeks post-surgery, ventral spinal gray matter extending from C4 and C5 was isolated ipsilateral and contralateral to C2HS. Neither C2HS nor CIH altered 5-HT concentration measured with an ELISA on either side of the spinal cord. However, 5-HT2A receptor expression assessed with immunoblots increased in ipsilateral gray matter following C2HS, an effect independent of CIH. Immunocytochemistry revealed increased 5-HT2A receptor expression on identified phrenic motoneurons (p<0.05), as well as in the surrounding gray matter. Contralateral to injury, 5-HT2A receptor expression was elevated in CIH, but not normoxic C2HS rats (p<0.05). Our data are consistent with the hypothesis that spontaneous increase in 5-HT2A receptor expression on or near phrenic motoneurons contributes to strengthened crossed-spinal synaptic pathways to phrenic motoneurons following C2HS.

Differences in time-dependent hypoxic phrenic responses among inbred rat strains

Hypoxic ventilatory responses differ between rodent strains, suggesting a genetic contribution to interindividual variability. However, hypoxic ventilatory responses consist of multiple time-dependent mechanisms that can be observed in different respiratory motor outputs. We hypothesized that strain differences would exist in discrete time-dependent mechanisms of the hypoxic response and, furthermore, that there may be differences between hypoglossal and phrenic nerve responses to hypoxia. Hypoglossal and phrenic nerve responses were assessed during and after a 5-min hypoxic episode in anesthetized, vagotomized, and ventilated rats from four inbred strains: Brown Norway (BN), Fischer 344 (FS), Lewis (LW), and Piebald-viral-Glaxo (PVG). During baseline, burst frequency was higher in PVG than LW rats ( P < 0.05), phrenic burst amplitude was higher in PVG vs. other strains ( P < 0.05), and hypoglossal burst amplitude was higher in PVG and BN vs. FS and LW ( P < 0.05). During hypoxia, burst frequency did not change in BN or LW rats, but it increased in PVG and FS rats. The phrenic amplitude response was smallest in PVG vs. other strains ( P < 0.05), and the hypoglossal response was similar among strains. Short-term potentiation posthypoxia was slowest in FS and fastest in LW rats ( P < 0.05). Posthypoxia frequency decline was absent in PVG, but it was observed in all other strains. Augmented breaths were observed during hypoxia in FS rats only. Thus genetic differences exist in the time domains of the hypoxic response, and these are differentially expressed in hypoglossal and phrenic nerves. Furthermore, genetic diversity observed in hypoxic ventilatory responses in unanesthetized rats may arise from multiple neural mechanisms.

Augmented breath phase volume and timing relationships in the anesthetized rat

Augmented breaths (ABs), or sighs, are airway protective reflexes and part of the normal repertoire of respiratory behaviors. ABs consist of two phases, where phase I volume and timing resembles preceding eupnic breaths, and phase II is an augmenting motor pattern and occurs at the end of phase I. Recent evidence suggest multiple respiratory motor patterns can occur following dynamic functional reconfiguration of one respiratory neural network. It follows that the response of the respiratory network to modulatory inputs also may undergo dynamic reconfiguration. We hypothesized that lung-volume related feedback during ABs would alter AB timing differentially during phase I and II. We measured phase I and II volumes and durations in urethane anesthetized rats with decreased lung volume secondary to three models of varying phrenic motor impairment (spinal injury alone, unilateral phrenicotomy, and combined injuries). AB phase I and II inspired volume were decreased after phrenic motor impairment (p<0.05). In contrast, only phase I duration following injury was altered compared to controls. Phase II duration remaining unchanged despite the greatest effect of injury on volume occurring during phase II. Thus, sigh volume-timing relationships differ between phases of an augmented breath suggesting that the response of the respiratory network to modulatory inputs has changed. These data support the hypothesis that multiple respiratory behaviors occur following dynamic reconfiguration of the respiratory neural network.

BDNF is necessary and sufficient for spinal respiratory plasticity following intermittent hypoxia

Intermittent hypoxia causes a form of serotonin-dependent synaptic plasticity in the spinal cord known as phrenic long-term facilitation (pLTF). Here we show that increased synthesis of brain-derived neurotrophic factor (BDNF) in the spinal cord is necessary and sufficient for pLTF in adult rats. We found that intermittent hypoxia elicited serotonin-dependent increases in BDNF synthesis in ventral spinal segments containing the phrenic nucleus, and the magnitude of these BDNF increases correlated with pLTF magnitude. We used RNA interference (RNAi) to interfere with BDNF expression, and tyrosine kinase receptor inhibition to block BDNF signaling. These disruptions blocked pLTF, whereas intrathecal injection of BDNF elicited an effect similar to pLTF. Our findings demonstrate new roles and regulatory mechanisms for BDNF in the spinal cord and suggest new therapeutic strategies for treating breathing disorders such as respiratory insufficiency after spinal injury. These experiments also illustrate the potential use of RNAi to investigate functional consequences of gene expression in the mammalian nervous system in vivo.

Respiratory motor recovery after unilateral spinal cord injury: eliminating crossed phrenic activity decreases tidal volume and increases contralateral respiratory motor output

By 2 months after unilateral cervical spinal cord injury (SCI), respiratory motor output resumes in the previously quiescent phrenic nerve. This activity is derived from bulbospinal pathways that cross the spinal midline caudal to the lesion (crossed phrenic pathways). To determine whether crossed phrenic pathways contribute to tidal volume in spinally injured rats, spontaneous breathing was measured in anesthetized C2 hemisected rats at 2 months after injury with an intact ipsilateral phrenic nerve, or with ipsilateral phrenicotomy performed at the time of the SCI (i.e., crossed phrenic pathways rendered ineffective) (dual injury). Ipsilateral phrenicotomy did not alter the rapid shallow eupneic breathing pattern in C2 injured rats. However, the ability to generate large inspiratory volumes after either vagotomy or during augmented breaths was impaired if crossed phrenic activity was abolished. We also investigated whether compensatory plasticity in contralateral motoneurons would be affected by eliminating crossed phrenic activity. Thus, contralateral phrenic motor output was recorded in anesthetized, vagotomized, and mechanically ventilated rats with dual injury during chemoreceptor stimulation. Hypercapnia, hypoxia, and asphyxia increased contralateral phrenic burst amplitude in the dual injury group more than in rats with SCI alone. Dual injury rats also had elevated baseline burst frequency. Together, these results demonstrate a functional role of crossed phrenic activity after SCI. Moreover, by preventing ipsilateral phrenic motor recovery in rats with unilateral SCI, segmental and supraspinal changes could be induced in contralateral respiratory motor output beyond that seen with SCI alone.

Cervical spinal cord injury alters the pattern of breathing in anesthetized rats

The mechanisms by which chronic cervical spinal cord injury alters respiratory function and plasticity are not well understood. We speculated that spinal hemisection at C(2) would alter the respiratory pattern controlled by vagal mechanisms. Expired volume (V(E)) and respiratory rate (RR) were measured in anesthetized control and C(2)-hemisected rats at 1 and 2 mo postinjury. C(2) hemisection altered the pattern of breathing at both postinjury time intervals. Injured rats utilized a higher RR and lower V(E) to maintain the same minute ventilation as control rats. After bilateral vagotomy, the pattern of breathing in injured rats was not different from controls. The frequency of augmented breaths was higher in injured rats at 2 mo postinjury before vagotomy; however, the V(E) of augmented breaths was not different between groups. In conclusion, C(2) hemisection alters the pattern of breathing at 1 and 2 mo postinjury via vagal mechanisms.

Altered respiratory motor drive after spinal cord injury: supraspinal and bilateral effects of a unilateral lesion

Because some bulbospinal respiratory premotor neurons have bilateral projections to the phrenic nuclei, we investigated whether changes in contralateral phrenic motoneuron function would occur after unilateral axotomy via C(2) hemisection. Phrenic neurograms were recorded under baseline conditions and during hypercapnic and hypoxic challenge in C(2) hemisected, normal, and sham-operated rats at 1 and 2 months after injury. The rats were anesthetized, vagotomized, and mechanically ventilated. No group differences were seen in contralateral neurograms at 1 month after injury. At 2 months, however, there was a statistically significant decrease in respiratory rate (RR) at normocapnia, an elevated RR during hypoxia, and an attenuated increase in phrenic neurogram amplitude during hypercapnia in the C(2)-hemisected animals. To test whether C(2) hemisection had induced a supraspinal change in respiratory motor drive, we recorded ipsilateral and contralateral hypoglossal neurograms during hypercapnia. As with the phrenic motor function data, no change in hypoglossal output was evident until 2 months had elapsed when hypoglossal amplitudes were significantly decreased bilaterally. Last, the influence of serotonin-containing neurons on the injury-induced change in phrenic motoneuron function was examined in rats treated with the serotonin neurotoxin, 5,7-dihydroxytryptamine. Pretreatment with 5,7-dihydroxytryptamine prevented the effects of C(2) hemisection on contralateral phrenic neurogram amplitude and normalized the change in RR during hypoxia. The results of this study show novel neuroplastic changes in segmental and brainstem respiratory motor output after C(2) hemisection that coincided with the spontaneous recovery of some ipsilateral phrenic function. Some of these effects may be modulated by serotonin-containing neurons.

Anesthetic and cardiorespiratory effects of a 1:1 mixture of propofol and thiopental sodium in dogs

OBJECTIVE

To compare anesthetic and cardiorespiratory effects of a 1:1 (vol:vol) mixture of propofol and thiopental sodium with either drug used alone in dogs.

DESIGN

Randomized crossover study.

ANIMALS

10 healthy Walker Hounds.

PROCEDURE

Dogs received propofol (6 mg/kg [2.7 mg/lb] of body weight), thiopental (15 mg/kg [6.8 mg/lb]), or a mixture of propofol (6 mg/kg) and thiopental (15 mg/kg) at 1-week intervals. Drugs were slowly administered i.v. over 90 seconds or until dogs lost consciousness. Increments of 10% of the initial dose were administered until intubation was possible. Amount of drug required for intubation, quality of induction and recovery, times from induction to intubation and to walking with minimal ataxia, and duration of intubation and lateral recumbency were recorded. Heart and respiratory rates, mean, systolic, and diastolic blood pressure, hemoglobin saturation of oxygen (SpO2), and end-tidal CO2 concentration (ETCO2) were determined before and after intubation.

RESULTS

Amounts of propofol and thiopental required to permit intubation were less, but not significantly so, when administered in combination than when administered alone. Duration of lateral recumbency and time from induction to walking were greater and recovery quality was worse in the thiopental group, compared with the other groups. Dogs in all groups remained normotensive. Respiratory rate, heart rate, ETCO2, and SpO2 did not differ among groups.

CONCLUSIONS AND CLINICAL RELEVANCE

A 1:1 mixture of propofol and thiopental induced anesthesia of similar quality to propofol or thiopental alone. Recovery quality and recovery times were similar to those of propofol and superior to those of thiopental.