Managing spine surgery referrals: The consultation of neurosurgery and its nuances.

INTRODUCTION: Spinal disorders, particularly low back pain, are among the most common reasons for general practitioner (GP) consultation and can sometimes be a source of professional friction. Despite their frequency and published guidelines, many patients are still mistakenly referred by their GP to specialists for spinal surgery consultation which can create colleague relationship problems, suboptimal or unnessary delayed care, as well as the financial implications for patients. PURPOSE: To assess the management of GP lumbar spine referrals made to 4 neurosurgeons from 3 neurosurgical teams specialized in spinal surgery. METHODS: All patient's medical records relating to 672 primary consultants over a period of two months (January and February 2015) at three institutions were retrospectively reviewed. Medical referral letters, clinical evidence and imaging data were analyzed and the patients were classified according the accuracy of surgical assessment. The final decisions of the surgeons were also considered. RESULTS: Of the 672 patients analyzed, 198 (29.5%) were considered unsuitable for surgical assessment: no spinal pathology=10.6%, no surgical conditions=35.4%, suboptimal medical treatment=31.3%, suboptimal radiology=18.2% and asymptomatic patients=4.5%. CONCLUSION: Unnecessary referrals to our consultation centers highlight the gap between the reason for the consultation and the indications for spinal surgery. Compliance with the guidelines, the creation of effective multidisciplinary teams, as well as the "hands on" involvement of surgeons in primary and continuing education of physicians are the best basis for a reduction in inappropriate referrals and effective patient care management.

Deep brain stimulation of the subthalamic nucleus for Parkinson's disease: methodologic aspects and clinical criteria.

The technique of deep brain stimulation (DBS) for the treatment of Parkinson's disease (PD) is evolving very rapidly. The subthalamic nucleus (STN) has become the preferred target in the past few years since our group demonstrated that high-frequency stimulation in this nucleus improves all cardinal features of PD, including resting tremor. This benefit in the parkinsonian symptoms allows a drastic reduction in daily levodopa requirements. Dyskinesias become drastically attenuated, possibly as a consequence of reduced dopaminergic medication but also because STN DBS may stabilize basal ganglia output activity, thus avoiding the problems associated with standard levodopa replacement therapy. DBS of the STN is associated with a marked improvement of motor function even in patients with advanced PD. Such a large degree of benefit in parkinsonian features relies on two crucial points that must be taken into consideration for achieving the best possible results with this technique: proper selection of patients and accuracy in targeting the STN. From a neurosurgical point of view, we believe that the most precise localization of the STN is obtained by using ventriculography to determine the stereotactic coordinates of the STN. This is complemented with intraoperative neuronal microrecording to define physiologically the sensorimotor region of the nucleus. Future advances in neuroimaging techniques may well lead to modifications of our current methodology.

Effect of subthalamic nucleus stimulation on levodopa-induced dyskinesia in Parkinson's disease.

Article abstract-The authors studied the effect of bilateral subthalamic nucleus stimulation on levodopa-induced dyskinesias in 24 consecutive parkinsonian patients with disabling dyskinesias. The improvement in the three subtypes of levodopa-induced dyskinesias was significant from the third postoperative month and was mainly due to the decrease in the daily dose of levodopa allowed by the stimulation-induced improvement in the motor score.

Implication of the subthalamic nucleus in the pathophysiology and pathogenesis of Parkinson's disease.

The subthalamic nucleus (STN) has been shown to play an important role in the control of movement and has been considered as a key structure in the functional organization of the basal ganglia. Several studies postulated that the STN plays a critical role in the pathophysiology of Parkinson's disease and that its inhibition or its lesioning can reverse the cardinal motor symptoms. Nevertheless, the beneficial effect was accompanied by dyskinetic abnormal movements. In order to avoid unpleasant and irreversible side effects we used high-frequency stimulation (HFS) of the STN instead of lesions. We have shown that parkinsonian motor symptoms, akinesia, rigidity, and tremor can be alleviated by HFS of the STN in the nonhuman primate model. Side effects were controllable and appeared only at intensities higher than that inducing the improvement of motor symptoms. In severe parkinsonian patients, bilateral STN-HFS greatly improved parkinsonian motor symptoms. Motor fluctuations were attenuated and patients became independent in most activities of daily living. It appears that STN-HFS mimics the effects of lesions by inhibiting its neuronal activity. In a rat model of parkinsonism, we studied the implication of the STN in the excitotoxicity of nigral dopamine cells. We showed that kainic acid lesioning of the STN can protect nigral dopaminergic cells against 6-hydroxydopamine-induced toxicity. The evidence reviewed in the present article clearly demonstrates that the STN is implicated in the pathophysiology and pathogenesis of Parkinson's disease.

Deep brain stimulation in the treatment of severe dystonia.

A retrospective study of a consecutive series of 19 patients with medically intractable dystonia treated with uni- or bilateral deep brain stimulation (DBS) is reported. A minimal follow-up of 6 months was available, up to eleven years in one patient. The first twelve consecutive patients (4 with primary and 8 with secondary dystonia) were treated with chronic stimulation of the posterior part of the ventrolateral thalamic nucleus (VLp). In this group global functional outcome was improved in 8 patients, although dystonia movement and disability scale scores did not show significant improvement. Of the 12 patients treated first by VLp DBS, three (1 primary and 2 secondary dystonia) underwent pallidal (GPi) DBS after the VLp DBS failed to improve their symptoms. The last seven consecutive patients (5 primary and 2 secondary dystonia) were treated directly with GPi DBS. Extracranial infection prevented chronic GPi DBS in one patient. In another GPi patient, preliminary negative tests with the electrodes discouraged implantation of the stimulators, and the patient was not treated with chronic DBS. In the remaining group of eight patients including those previously treated with VLp DBS, chronic GPi DBS resulted in a significant improvement in the dystonia movement scale and disability scores. Although this is a retrospective study dealing with dystonia of heterogeneous etiology, the results strongly suggest that GPi DBS has a better outcome than VLp DBS.

Chronic subthalamic nucleus stimulation and striatal D2 dopamine receptors in Parkinson's disease--A [(11)C]-raclopride PET study.

CONTEXT: Subthalamic nucleus (STN) stimulation mechanism of action remains a matter for debate. In animals, an increased striatal dopamine (DA) release due to STN stimulation has been reported. OBJECTIVE: To determine in Parkinson's disease (PD) patients using positron emission tomography (PET) and [11C]-Raclopride, whether STN stimulation induces a striatal DA release. METHODS: Nine PD patients with bilateral STN stimulation were enrolled and underwent two [11C]-Raclopride PET scans. The scans were randomly performed in off and on stimulation conditions. Striatal [11C]-Raclopride binding potential (BP) was calculated using regions of interest and statistical parametric mapping. RESULTS: For PD patients, the mean [(11C]-Raclopride BP (+/- SD) were, in Off stimulation condition: 1.7 +/- 0.3 for the right caudate nucleus, 1.8 +/- 0.4 for the left caudate nucleus, 2.6 +/- 0.5 for the right putamenand 2.6 +/- 0.5 for the left putamen. In On stimulation condition: 1.7 +/- 0.4 for the right caudate nucleus, 1.9 +/- 0.5 for the left caudate nucleus, 2.8 +/- 0.7 for the right putamen and 2.7 +/- 0.8 for the left putamen. No significant difference of BP related to the stimulation was noted. CONCLUSION: STN stimulation does not produce significant variations of striatal DA release as assessed by PET and [11C]-Raclopride.

Deep brain stimulation of the corpus luysi (subthalamic nucleus) and other targets in Parkinson's disease. Extension to new indications such as dystonia and epilepsy.

Chronic high frequency (130 Hz) stimulation (HFS) of the thalamic target Vim, first used in our group in 1987 as a treatment of tremor of various origins, has been used over the last ten years in 137 patients. Since 1993, this method has been extended to two other targets (subthalamic nucleus (STN): 137 patients and the medial pallidum (GPi): 12 patients), based on recent experimental data in rats and monkeys. STN appears to be a target of major interest, able to control the three cardinal symptoms and to allow the decrease or suppression of levodopa treatment, which then also suppresses levodopa induced dyskinesias. The stereotactic technique is based on the determination of the target using ventriculography, MRI and electrophysiology, with both microrecording of single neuron activity and microstimulation inducing therapeutic symptom suppression and side effects. Chronic electrodes are then placed bilaterally at the best physiologically defined location and then connected to implantable stimulators (either 2 Itrel II or the new double channel Kinetra), operated at 130-185 Hz, 60 ms pulse width, 2.5 to 3.5 volts. There was no operative mortality and permanent morbidity was observed in 3 patients. The mechanisms of action of HFS are not fully understood, but are definitely related to high frequency and are probably different depending on the target. Inhibition of cellular activity or of neural network functions could be induced, by jamming of a retroactive loop for tremor, or by shutdown of neurotransmitter release in STN. Mechanisms within an individual target are also probably different for tremor or for other symptom alleviation. All cardinal symptoms are alleviated from tremor to akinesia and rigidity. This strong improvement allows the decrease of the drug dosage to approximately 30% of the preoperative level, which suppresses the levodopa-induced dyskinesias. The off period dystonias are also suppressed as well as freezings and falls. The effects remain stable over more than 5 years and in the same period, the off stimulation-off medication UPDRS remains stable and does not increase at the usual rate The low rate of permanent complications, the minor side effects and their immediate reversibility, the possibility of bilateral implantation in one session and the long-term persistence of symptom relief are strong arguments which support chronic HFS of STN as the method of choice when a surgical procedure is indicated for the treatment of Parkinson's disease and even more when a bilateral procedure is necessary. Recent data show that STN stimulation could be useful in the treatment of dystonia as well as some forms of epilepsy. It is therefore possible that DBS in STN as well as in other targets could become a potent therapeutic tool in the near future for neurological disorders.

Subthalamic stimulation for Parkinson's disease.

Deep brain stimulation by high frequency (HFS) has been developed starting in the thalamic target (Vim) from pragmatic observations and subsequently followed by other targets, such as the subthalamic nucleus (STN) and pallidum as an application of current knowledge from basic preclinical research in neuroscience. The mechanism involved by this neurosurgical approach is not completely solved. For Vim we have formed the hypothesis that HFS induces a jamming of sensory-motor loops but for the STN, from our experimental research in rats we have shown that HFS induces functional inhibition of cell activity in the target nuclei. In our patients the implantation of the stimulation electrodes was carried out stereotactically, under local anesthesia, using ventriculography, MRI, microrecordings and clinical evaluation of the effects of stimulation on rigidity. When the stimulation is turned ON in the STN area a significant decrease in rigidity was determined by the neurologists. Stimulation or even penetration of the electrode may be responsible for transient dyskinesias. The average location of the clinically efficient contact of the chronic stimulating electrodes is statistically located at 5.02 +/- 0.71 1/12 degrees of AC-PC in the AP direction, at -1.5 +/- 0.66 1/8 degrees of the height of the thalamus in the ventricle direction, with laterality at 11.98 +/- 1.12 mm in the lateral direction. The beneficial effects of STN stimulation are significant providing that the electrodes are correctly placed into the target. There is strong improvement of the symptoms of the triad in which akinesia, rigidity, and tremor are reduced on average to 41. 6, 48.6, and 27%, respectively, when compared with the previous preoperative level. From our experience, HFS of the STN could be considered the surgical therapy of choice at advanced stages of Parkinson's disease.

Future prospects of brain stimulation.

Chronic high frequency (130 Hz) stimulation (HFS) of the thalamic target Vim has replaced thalamotomy as a treatment of tremor of various origins and was extended to two other targets (Subthalamic nucleus (STN) and the medial pallidus (GPi)), since 1993 based on recent experimental data in rats and monkeys. STN appears to be a target of major interest, able to control the three cardinal symptoms and to allow the decrease or suppression of levodopa treatment, which then suppresses also levodopa induced dyskinesias. The mechanisms of action of HFS are not fully understood, but are definitely related to high frequency and are probably different depending on the target. Inhibition of cellular activity or of network functions could be induced, by jamming of a retroactive loop for tremor, or by shutdown of neurotransmitter release in STN. All cardinal symptoms are alleviated from tremor to akinesia and rigidity. The effects remain stable over more than five years chronic HFS of STN, as the method of choice when a surgical procedure is indicated for the treatment of Parkinson's disease and even more when a bilateral procedure is necessary. Recent data show that STN stimulation could be useful in the treatment of dystonia as well as some forms of epilepsies. It is therefore possible that DAS in STN as well as in other targets could become a potent therapeutic tool in the future for neurological disorders. The future of brain stimulation will depend on new technologies (new circuits, electrodes, web based programmers), waveforms (alternatives to square waves, random distribution), targets (hypothalamic nuclei, locus coeruleus) and indications (dystonia, epilepsy, eating disorders.

[Deep brain stimulation]. / La stimulation cérébrale profonde dans la maladie de Parkinson.

The present renewal of the surgical treatment of Parkinson's disease, almost abandoned for twenty Years, arises from two main reasons. The first is the better understanding of the functional organization of the basal ganglia. It was demonstrated in animal models of Parkinson's disease that the loss of dopaminergic neurons within the substantia nigra, at the origin of the striatal dopaminergic defect, induces an overactivity of the excitatory glutamatergic subthalamo-internal pallidum pathway. The decrease in this hyperactivity might lead to an improvement in the pakinsonian symptoms. The second reason is the improvement in stereotactic neurosurgery in relation with the progress in neuroimaging techniques and with intraoperative electrophysiological microrecordings and stimulations, which help determine the location of the deep brain targets. In the 1970s chronic deep brain stimulation in humans was applied to the sensory nucleus of the thalamus for the treatment of intractable pain. In 1987, Benabid and colleagues suggested high frequency stimulation of the ventral intermediate nucleus of the thalamus in order to treat drug-resistant tremors and to avoid the adverse effects of thalamotomies. How deep brain stimulation works is not well known but it has been hypothetized that it could change the neuronal activities and thus avoid disease-related abnormal neuronal discharges. Potential candidates for deep brain stimulation are selected according to exclusion and inclusion criteria. Surgery can be applied to patients in good general and mental health, neither depressive nor demented and who are severely disabled despite all available drug therapies but still responsive to levodopa. The first session of surgery consists in the location of the target by ventriculography and/or brain MRI. The electrodes are implanted during the second session. The last session consists in the implantation of the neurostimulator. The ventral intermediate nucleus of the thalamus was the first target in which chronic deep brain stimulation electrodes were implanted in order to alleviate tremor. This technique can be applied bilaterally without the adverse effects of bilateral thalamotomies. Like pallidotomy, internal globus pallidum stimulation has a dramatic beneficial effect on levodopa-induced dyskinesia but its effects on the parkinsonian triad are less constant and opposite motor effects are sometimes observed in relation with the stimulated contact. The inconstant results, perhaps related to the complexity of the structure led to the development of subthalamic nucleus stimulation. The alleviation of motor fluctuations and the improvement in all motor symptoms allows a significant decrease in levodopa daily dose and in levodopa-induced dyskinesia. Presently, deep brain stimulation is a fashionable neurosurgical technique to treat Parkinson's disease. Subthalamic nucleus stimulation seems to be the most suitable target to control the parkinsonian triad and the motor fluctuations. Because of the possible adverse effects it must be reserved for disabled parkinsonian patients. No large randomized study comparing different targets and different neurosurgical techniques has been performed yet. Such studies, including cost benefit studies would be useful to assess the respective value of these different techniques.

[The robotization of neurosurgery: state of the art and future outlook]. / La robotisation de la neurochirurgie: état actuel et perspectives d'avenir.

Neurosurgery is by excellence a field of application for robots, based on multimodal image guidance. Specific motorized tools have been already developed and routinely applied in stereotaxy to position a probe holder or in conventional neurosurgery to hold a microscope oriented towards a given target. The potentialities of these approaches have triggered industrial developments currently commercially available. These systems use data bases, primarily coming from multimodal numerical images from X-ray radiology to magnetic resonance imaging. These spatially encoded data are transferred through digital networks to workstations where images can be processed and surgical procedures are preplanned, then transferred to the robotic systems to which they are connected. We have been using a stereotactic robot since 1989 and a microscope robot since 1995 in various surgical routine procedures. The future of these applications mainly rely on the technical progress in informatics, about image recognition to adapt the preplanning to the actual surgical situation, to correct brain shifts for instance, about image fusion, integrated knowledge such such as brain atlases, as well as virtual reality. The future developments, covering surgical procedure, research and teaching, will sure be far beyond our wildest expectations.

Dyskinesias and the subthalamic nucleus.

Severe dyskinesias or ballism can occur following hemorrhagic events in the subthalamic nucleus (STN), and it has recently been established that the STN plays a major role in the pathophysiology of the motor dysfunction of Parkinson's disease (PD) and that STN inhibition improves parkinsonian dysfunction. Deep brain stimulation of the STN in PD patients is therefore currently being evaluated as a therapy. High-frequency stimulation of the STN in PD patients can induce intense dyskinesias that are similar to those induced by levodopa. These may occur with a variable latency and resemble all types of levodopa-induced dyskinesias (LIDs). They can be decreased by reducing the levodopa dosage, which is permitted by the antiparkinsonian effect of stimulating the STN. STN stimulation has been shown to improve all types of LIDs, with the most dramatic effect being that on off-period dystonia. The improvement in LIDs may relate to the decrease in drug dosage, while the off-period dystonia is likely improved by the simultaneous administration of levodopa and STN stimulation. It is thought that the STN is an important node in a network, which can produce dyskinesias when disturbed by a lesion, and is particularly sensitive for the induction of these abnormal movements.

[Robotics in neurosurgery: current status and future prospects]. / La robotisation de la neurochirurgie: état actuel et perspectives d'avenir.

Neurosurgery is in essence a field of application development for robots, based on multimodal image guidance. Specific motorized tools have already been developed and routinely applied in stereotaxy to position a probe holder or in conventional neurosurgery to hold a microscope oriented towards a given target. The potentialities of these approaches have triggered industrial developments which are now commercially available. These systems use databases, primarily coming from multimodal numerical images from X-ray radiology to magnetic resonance imaging. These spatially encoded data are transferred through digital networks to workstations where images can be processed and surgical procedures are pre-planned, then transferred to the robotic systems to which they are connected. We have been using a stereotaxic robot since 1989 and a microscope robot since 1995 in various surgical routine procedures. The future of these applications rely mainly on the technical progress in informatics, about image recognition to adapt the pre-planning to the actual surgical situation, to correct brain shifts (for instance), about image fusion, integrated knowledge such as brain atlases, as well as virtual reality. The future developments, covering surgical procedure, research and teaching, are sure to be far beyond our wildest expectations.

Opposite motor effects of pallidal stimulation in Parkinson's disease.

We studied the effects--on parkinsonian signs, on levodopa-induced dyskinesias, and on levodopa response--of acute experimental high-frequency stimulation of the internal pallidum (GPi) during off-drug and on-drug phases. Thirteen quadripolar electrodes were evaluated in 8 patients with Parkinson's disease (PD). Stimulation of the most ventral contacts, lying at the ventral margin of or just below the GPi, led to pronounced improvement in rigidity and a complete arrest of levodopa-induced dyskinesias. The antiakinetic effect of levodopa was also blocked and the patients became severely akinetic. Stimulation of the most dorsal contacts, lying at the dorsal border of the GPi or inside the external pallidum, usually led to moderate improvement of off-drug akinesia and could also induce dyskinesias in some patients. When using an intermediate contact for chronic stimulation, a good compromise between these opposite effects was usually obtained, mimicking the effect of pallidotomy. We conclude that there are at least two different functional zones within the globus pallidus, at the basis of a different pathophysiology of the cardinal symptoms of PD. The opposite effects may explain the variable results of pallidal surgery reported in the literature and may also largely explain the paradox of PD surgery. A possible anatomical basis for these differential functional effects could be a functional somatotopy within the GPi, with the segregation of the pallidofugal fibers from the outer portion of the GPi, on one hand, forming the ventral ansa lenticularis and from the inner portion of the GPi, on the other hand, forming the dorsal lenticular fasciculus.

Surgery in severe factor XIII deficiency: report of a case of epilepsy neurosurgery and review.

Factor XIII (FXIII) deficiency is a rare autosomal recessive congenital disorder of haemostasis, associated with a high risk of intracranial haemorrhage. Intracranial haemorrhage can result in neurological sequelae including seizure disorders. In some cases, medically intractable epilepsy led to epilepsy surgery. Little has been reported on the management of FXIII deficiency during surgery, and there is only a few data on the management, safety and efficacy of epilepsy surgery in the patients with haemostatic disorder. We report here an epilepsy neurosurgery in a case of severe FXIII deficiency.