Scott E. Krahl

VNS therapy in treatment-resistant depression: clinical evidence and putative neurobiological mechanisms.

Currently available therapeutic interventions for treatment-resistant depression, including switch, combination, and augmentation strategies, are less than ideal. Observations of mood elevation during vagus nerve stimulation (VNS) therapy for pharmacoresistant epilepsy suggested a role for VNS therapy in refractory major depression and prompted clinical investigation of this neurostimulation modality. The VNS Therapy System™ has been available for treatment of pharmacoresistant epilepsy since 1997 and was approved by the US Food and Drug Administration for treatment-resistant depression in July, 2005. The physiology of the vagus nerve, mechanics of the VNS Therapy System™, and efficacy and safety in pharmacoresistant epilepsy are reviewed. Promising results of VNS therapy for treatment-resistant depression have been forthcoming from both acute and long-term studies, evidenced in part by progressive improvements in depression rating scale scores during the 1st year of treatment with maintenance of response thereafter. VNS therapy is well tolerated in patients with either pharmacoresistant epilepsy or treatment-resistant depression. As in epilepsy, the mechanisms of VNS therapy of treatment-resistant depression are incompletely understood. However, evidence from neuroimaging and other studies suggests that VNS therapy acts via innervation of the nucleus tractus solitarius, with secondary projections to limbic and cortical structures that are involved in mood regulation, including brainstem regions that contain serotonergic (raphe nucleus) and noradrenergic (locus ceruleus) perikarya that project to the forebrain. Mechanisms that mediate the beneficial effects of VNS therapy for treatment-resistant depression remain obscure. Suggestions for future research directions are described.

Destruction of Peripheral C‐Fibers Does Not Alter Subsequent Vagus Nerve Stimulation‐Induced Seizure Suppression in Rats

Summary:  Purpose: Early animal studies of the therapeutic mechanisms of vagus nerve stimulation (VNS) suggested that seizure suppression requires maximal activation of small, unmyelinated vagal C fibers. However, effective therapeutic stimulation parameters appear to be subthreshold for these fibers in humans, and there are no clinical reports of the autonomic side effects that would be expected if these fibers were maximally activated. We report here that selective destruction of C fibers with capsaicin does not affect VNS‐induced seizure suppression in rats.

Deep Brain Stimulation of the Subthalamic Nucleus as Adjunct Treatment for Refractory Epilepsy

Summary:  Purpose: We studied the efficacy and safety of bilateral subthalamic deep brain stimulation (DBS) for refractory partial‐onset epilepsy in two cases.

Deep brain stimulation of the amygdala alleviates post-traumatic stress disorder symptoms in a rat model

Post-traumatic stress disorder (PTSD) is an anxiety disorder triggered by a life-threatening event causing intense fear. Recently, functional neuroimaging studies have suggested that amygdala hyperactivity is responsible for the symptoms of PTSD. Deep brain stimulation (DBS) can functionally reduce the activity of a cerebral target by delivering an electrical signal through an electrode. We tested whether DBS of the amygdala could be used to treat PTSD symptoms. Rats traumatized by inescapable shocks, in the presence of an unfamiliar object, develop the tendency to bury the object when re-exposed to it several days later. This behavior mimics the symptoms of PTSD. 10 Sprague-Dawley rats underwent the placement of an electrode in the right basolateral nucleus of the amygdala (BLn). The rats were then subjected to a session of inescapable shocks while being exposed to a conspicuous object (a ball). Five rats received DBS treatment while the other 5 rats did not. After 7 days of treatment, the rats were re-exposed to the ball and the time spent burying it under the bedding was recorded. Rats treated with BLn DBS spent on average 13 times less time burying the ball than the sham control rats. The treated rats also spent 18 times more time exploring the ball than the sham control rats. In conclusion, the behavior of treated rats in this PTSD model was nearly normalized. We argue that these results have direct implications for patients suffering from treatment-resistant PTSD by offering a new therapeutic strategy.

Modulation of food intake following deep brain stimulation of the ventromedial hypothalamus in the vervet monkey: Laboratory investigation

OBJECT Deep brain stimulation (DBS) has become an effective therapy for an increasing number of brain disorders. Recently demonstrated DBS of the posterior hypothalamus as a safe treatment for chronic intractable cluster headaches has drawn attention to this target, which is involved in the regulation of diverse autonomic functions and feeding behavior through complex integrative mechanisms. In this study, the authors assessed the feasibility of ventromedial hypothalamus (VMH) DBS in freely moving vervet monkeys to modulate food intake as a model for the potential treatment of eating disorders. METHODS Deep brain stimulation electrodes were bilaterally implanted into the VMH of 2 adult male vervet monkeys by using the stereotactic techniques utilized in DBS in humans. Stimulators were implanted subcutaneously on the upper back, allowing ready access to program stimulation parameters while the animal remained conscious and freely moving. In anesthetized animals, intraoperatively and 6-10 weeks postsurgery, VMH DBS parameters were selected according to minimal cardiovascular and autonomic nervous system responses. Thereafter, conscious animals were subjected to 2 cycles of VMH DBS for periods of 8 and 3 days, and food intake and behavior were monitored. Animals were then killed for histological verification of probe placement. RESULTS During VMH DBS, total food consumption increased. The 3-month bilateral implant of electrodes and subsequent periods of high-frequency VMH stimulation did not result in significant adverse behavioral effects. CONCLUSIONS This is the first study in which techniques of hypothalamic DBS in humans have been applied in freely moving nonhuman primates. Future studies can now be conducted to determine whether VMH DBS can change hypothalamic responsivity to endocrine signals associated with adiposity for long-term modulation of food intake.

Evidence for physiologically active axonal adenosine receptors in the rat corpus callosum

Several neurotransmitter receptors have been identified on axons, and emerging evidence suggests that central axonal conduction may be modulated by neurotransmitters. We have recently demonstrated the presence of extra-synaptic adenosine Al receptors along rat hippocampal axons. We now present immunocytochemical evidence for Al receptors on rat corpus callosum axons and show that these receptors actively modulate axon physiology. Using rat brain coronal slices, we stimulated the corpus callosum and recorded the evoked extracellular compound action potential. The lipid-soluble, Al-specific adenosine receptor agonist cyclopentyladenosine, dose-dependently decreased the compound action potential amplitude, an effect reversed by the specific Al antagonist 8-cyclopentyl-1, 3-dipropylxanthine. These data provide the first direct evidence that axonal Al adenosine receptors modulate axon physiology in the adult mammalian brain. Influencing axonal transmission is a potentially powerful mechanism of altering information processing in the nervous system.

Reduction of Hippocampal-Kindled Seizure Activity in Rats by Stereotactic Radiosurgery ☆

Radiosurgery may provide an alternative therapy for intractable epilepsy by eliminating or modifying abnormally active pacemaker neurons in epileptic foci. In the present study, the effect of radiosurgery on rat hippocampal kindling was examined. Rats received daily hippocampal stimulus trains until they were fully kindled. They then underwent radiosurgery of the kindled focus, receiving a single-dose of 0-, 10-, or 40-Gy. The 40-Gy group demonstrated an acute decrease in seizure threshold (3-5 days). Three months after radiosurgery, the threshold for seizures increased and the duration of afterdischarges decreased in the 40-Gy radiosurgery group compared to controls. The changes to both seizure threshold and afterdischarge duration were not significant in the 10-Gy group. These data suggest that radiosurgery is an effective means of reducing the epileptogenic activity of seizure foci.

Right-sided vagus nerve stimulation reduces generalized seizure severity in rats as effectively as left-sided

As currently utilized, vagus nerve stimulation (VNS) is applied to the cervical trunk of the left vagus nerve to suppress seizures clinically. Demonstration that VNS can also reduce seizure severity when electrodes are placed on the right cervical vagus nerve in rats would provide empirical evidence that the antiepileptic effects of VNS are not an exclusive property of the left vagus nerve. Rats were implanted with a custom cuff electrode on either the left or right cervical vagus nerve. Two days later, continuous VNS was begun in half the rats with left-sided and half with right-sided electrodes. The remaining rats were connected to the stimulator, but did not receive VNS. After 30s, pentylenetetrazole (PTZ) was administered systemically and seizures were rated by a blinded observer. The PTZ test was repeated two days later, with VNS administered to the previously unstimulated rats, while the others received no stimulation. VNS significantly reduced the severity of PTZ-induced seizures in rats regardless of the side of stimulation as compared to their no-VNS (control condition) seizure severity. No significant differences in efficacy existed based on the side of stimulation. These results indicate that right-sided VNS in rats is just as effective as left-sided VNS, suggesting that fibers necessary for seizure suppression are not unique to the left vagus nerve.

Amygdala deep brain stimulation is superior to paroxetine treatment in a rat model of posttraumatic stress disorder.

BACKGROUND Posttraumatic stress disorder (PTSD) is a very debilitating disease refractory to current treatment with selective serotonin reuptake inhibitors (SSRIs) in up to 30 percent of patients, illustrating the need for new treatments of PTSD. Neuroimaging studies have shown increased activity of the amygdala of patients with PTSD. OBJECTIVE/HYPOTHESIS To investigate amygdala deep brain stimulation (DBS) as a possible novel treatment for PTSD and compare it to current treatment with a commonly used SSRI, paroxetine, in a rat PTSD model. METHODS A PTSD model was created by subjecting rats to inescapable foot shocks in the presence of a conspicuous ball. Response to treatment was measured as a decreased burying behavior when presented with the same ball 1 and 2 weeks after the shocks. Rats were treated with either daily intraperitoneal paroxetine injections or amygdala DBS via an electrode implanted 1 week prior to shocks. Generalized anxiety was assessed using an elevated plus maze. RESULTS Animals treated with amygdala DBS showed less ball burying at 2 weeks relative to the animals treated with paroxetine. The animals treated with paroxetine, however, had a lower general anxiety level compared to the DBS-treated group. CONCLUSIONS In this PTSD model, paroxetine was found to decrease the measured general anxiety level of rats that underwent the PTSD protocol, but did not counteract shock-induced hyper-vigilance toward the trauma-associated object (ball). Amygdala DBS, however, did decrease shock-induced hyper-vigilance as measured by a lower burying time, but had no effect on general anxiety assessed in the elevated plus maze. By attenuating amygdala function, DBS may act to treat the cause of PTSD, hyperactive amygdala function, and may be a promising novel alternative in cases of PTSD refractory to current pharmacological treatments.

Seizure suppression by systemic epinephrine is mediated by the vagus nerve

The present study investigated the seizure-suppressing effects of systemic epinephrine. Rats were injected with epinephrine, and seizures induced with pentylenetetrazol. Seizure severities were significantly reduced 15 min after 1 mg/kg of epinephrine. Severing the subdiaphragmatic vagus nerves abolished this effect, demonstrating that epinephrine-induced seizure suppression is mediated by subdiaphragmatic vagal afferents. The development of novel anti-epileptic drugs that exploit this peripheral pathway may yield new seizure treatments.