Brain shift during bur hole–based procedures using interventional MRI

Ivan, Michael E.; Yarlagadda, Jay; Saxena, Archana; Martin, Alastair J.; Starr, Philip A.; Sootsman, W. Keith; Larson, Paul

doi:10.3171/2014.3.jns121312

Cited by 93 publications

(76 citation statements)

References 38 publications

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“…Quantification of shift of these structures is important; the correlation between shift in cortical surface and deep brain structures per se is weak [31], but other studies have shown that this correlation is statistically significant [17]. The focus of this study, however, was largely on the incidence of air in aDBS versus wkDBS, with the contention that reducing the incidence of pneumocephalus should mitigate its adverse effects.…”

Section: Discussionmentioning

confidence: 80%

Asleep Deep Brain Stimulation Reduces Incidence of Intracranial Air during Electrode Implantation

Magown

Ozpinar

Hamzaoğlu

et al. 2018

Stereotact Funct Neurosurg

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Background: Asleep deep brain stimulation (aDBS) implantation replaces microelectrode recording for image-guided implantation, shortening the operative time and reducing cerebrospinal fluid egress. This may decrease pneumocephalus, thus decreasing brain shift during implantation. Objective: To compare the incidence and volume of pneumocephalus during awake (wkDBS) and aDBS procedures. Methods: A retrospective review of bilateral DBS cases performed at Oregon Health & Science University from 2009 to 2017 was undertaken. Postimplantation imaging was reviewed to determine the presence and volume of intracranial air and measure cortical brain shift. Results: Among 371 patients, pneumocephalus was noted in 66% of wkDBS and 15.6% of aDBS. The average volume of air was significantly higher in wkDBS than aDBS (8.0 vs. 1.8 mL). Volumes of air greater than 7 mL, which have previously been linked to brain shift, occurred significantly more frequently in wkDBS than aDBS (34 vs 5.6%). wkDBS resulted in significantly larger cortical brain shifts (5.8 vs. 1.2 mm). Conclusions: We show that aDBS reduces the incidence of intracranial air, larger air volumes, and cortical brain shift. Large volumes of intracranial air have been correlated to shifting of brain structures during DBS procedures, a variable that could impact accuracy of electrode placement.

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Section: Discussionmentioning

confidence: 80%

Asleep Deep Brain Stimulation Reduces Incidence of Intracranial Air during Electrode Implantation

Magown

Ozpinar

Hamzaoğlu

et al. 2018

Stereotact Funct Neurosurg

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“…ClearPoint uses real-time MRI to perform target selection and monitor lead placement; it does not rely on MR images obtained preoperatively, which cannot account for intraoperative brain shift due to pneumocephalus, or CT images obtained intraoperatively, which must be fused with preoperative image sets and are therefore subject to potential fusion errors. 13,14 It therefore has the advantage of detecting lead placement errors as well as other intraoperative complications such as hemorrhages in real time, with shorter operative times than awake surgery. Finally, because iMRI DBS can be safely done under general anesthesia and does not require withholding of parkinsonian medications, it may broaden the accessibility to those who might not otherwise be able to tolerate awake surgery.…”

Section: Summary Of Resultsmentioning

confidence: 99%

Clinical outcomes using ClearPoint interventional MRI for deep brain stimulation lead placement in Parkinson’s disease

Ostrem

Ziman

Galifianakis

et al. 2016

JNS

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120

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(DBS) has been shown to be a highly effective treatment option for medicationrefractory Parkinson's disease (PD) patients experiencing motor fluctuations and dyskinesia. 5,15,18,21,22,26,31 Clinical outcomes with DBS are critically dependent on the exact lead placement in the intended brain target (dorsal lateral subthalamic nucleus [STN] or posterior [motor] area of the internal globus pallidus [GPi]), but surgical methods to achieve acceptable placement are not standardized. The traditional method for DBS lead implantation involves the use of preoperative brain images registered in a stereotactic coordinate system, and physiological localization using microelectrode-guided mapping of the target regions while patients are awake.28 This method poses challenges when patients are not able to tolerate and/or cooperate with awake surgery (severe "off" medication symptoms, anxiety, pain).Recently a new method has been developed for implan- obJective The ClearPoint real-time interventional MRI-guided methodology for deep brain stimulation (DBS) lead placement may offer advantages to frame-based approaches and allow accurate implantation under general anesthesia. In this study, the authors assessed the safety and efficacy of DBS in Parkinson's disease (PD) using this surgical method. methods This was a prospective single-center study of bilateral DBS therapy in patients with advanced PD and motor fluctuations. Symptom severity was evaluated at baseline and 12 months postimplantation using the change in Unified Parkinson's Disease Rating Scale (UPDRS) Part III "off" medication score as the primary outcome variable. results Twenty-six PD patients (15 men and 11 women) were enrolled from 2010 to 2013. Twenty patients were followed for 12 months (16 with a subthalamic nucleus target and 4 with an internal globus pallidus target). The mean UPDRS Part III "off" medication score improved from 40.75 ± 10.9 to 24.35 ± 8.8 (p = 0.001). "On" medication time without troublesome dyskinesia increased 5.2 ± 2.6 hours per day (p = 0.0002). UPDRS Parts II and IV, total UPDRS score, and dyskinesia rating scale "on" medication scores also significantly improved (p < 0.01). The mean levodopa equivalent daily dose decreased from 1072.5 ± 392 mg to 828.25 ± 492 mg (p = 0.046). No significant cognitive or mood declines were observed. A single brain penetration was used for placement of all leads, and the mean targeting error was 0.6 ± 0.3 mm. There were 3 serious adverse events (1 DBS hardware-related infection, 1 lead fracture, and 1 unrelated death). coNclusioNs DBS leads placed using the ClearPoint interventional real-time MRI-guided method resulted in highly accurate lead placement and outcomes comparable to those seen with frame-based approaches.Clinical trial registration no.: NCT00792532 (clinicaltrials.gov)

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“…Thus, STN DBS is typically performed under local anesthesia to allow MER and physiologic testing in an awake patient. Finally, brain shift due to loss of CSF from the dural opening should be minimized with the use of dural sealants [37].…”

Section: Target Selectionmentioning

confidence: 99%

Improving outcomes of subthalamic nucleus deep brain stimulation in Parkinson’s disease

Bari

Fasano

Munhoz

et al. 2015

Expert Review of Neurotherapeutics

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The subthalamic nucleus (STN) has been a major target of deep brain stimulation (DBS) for Parkinson's disease (PD) over the past 20 years. The benefits of DBS of the STN include: decreased motor fluctuations and bradykinesia, tremor reduction and a reduction in dopaminergic drug requirements and dyskinesias. Despite these overall positive effects, the outcomes of STN DBS can be variable, contributing to the debate over the best DBS target for PD. Here, the authors review the current practice of STN DBS and also review both the existing and emerging technologies that are likely to improve the accuracy and effectiveness of STN DBS for PD. The authors emphasize patient selection, accuracy of electrode placement within the brain and the selection of appropriate stimulation parameters to optimize clinical benefits.

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Brain shift during bur hole–based procedures using interventional MRI

Cited by 93 publications

References 38 publications

Asleep Deep Brain Stimulation Reduces Incidence of Intracranial Air during Electrode Implantation

Asleep Deep Brain Stimulation Reduces Incidence of Intracranial Air during Electrode Implantation

Clinical outcomes using ClearPoint interventional MRI for deep brain stimulation lead placement in Parkinson’s disease

Improving outcomes of subthalamic nucleus deep brain stimulation in Parkinson’s disease

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