Combined magnetic field results in higher fusion rates than pulsed electromagnetic field bone stimulation after thoracolumbar fusion surgery

BackgroundBone growth stimulators have been used as an adjunct to spinal fusion surgery in efforts to increase fusion rates.MethodsThe authors retrospectively reviewed the medical records of patients who underwent thoracolumbar fusion surgeries by a single surgeon. Patients were then separated into three groups; pulsed electromagnetic field stimulation (PEMF), combined magnetic field stimulation (CMF) or no stimulation (NS), and computed tomography radiographic results at least 1 year after surgery were compared (solid fusion, stable nonunion, and pseudarthrosis).ResultsA total of 60 patients were included; 16 (26.7%) used PEMF, 24 (40.0%) used CMF, and 20 (33.3%) had NS. There were no significant differences in patient demographics. There was no difference in the mean fusion levels (p = 0. 477). Solid fusion was achieved in 11/16 (68.8%) PEMF, 21/24 (87.5%) CMF, and 20/20 (100.0%) NS patients. Stable nonunion was displayed in 2/24 (8.3%) CMF, and zero PEMF and NS patients. There were 5/16 (31.3%) PEMF, 1/24 (4.2%) CMF, and zero NS patients demonstrating radiologic pseudarthrosis. There was a statistically significant difference between PEMF and CMF (p = 0.017) and between PEMF and NS (p = 0.006) groups. No statistical difference was found between CMF and NS (p = 1.000).ConclusionThis is the first study to compare PEMF and CMF bone growth stimulators in patients with degenerative pathologies who underwent thoracolumbar spinal fusions. Overall, the addition of these bone growth stimulators does not improve fusion outcomes, although CMF appears superior to PEMF.     

Characteristics of globus pallidus internus local field potentials in generalized dystonia patients with TWNK mutation

ObjectiveWe focused on a rare gene mutation causing dystonia in two siblings who received globus pallidus internus deep brain stimulation (GPi-DBS). The aim was to characterize the relationship between neuronal activity patterns and clinical syndromes.MethodsWhole exome sequencing was applied to identify the TWNK (previous symbol C10orf2) mutation; Two siblings with TWNK mutation presented as generalized dystonia with rigidity and bradykinesia; four other sporadic generalized dystonia patients underwent GPi-DBS and local field potentials (LFPs) were recorded. Oscillatory activities were illustrated with power spectra and temporal dynamics measured by the Lempel-Ziv complexity (LZC).ResultsNormalized power spectra of GPi LFPs differed between patients with TWNK mutation and dystonia over the low beta bands. Patients with TWNK mutation had higher low beta power (15–27 Hz, unpaired t-test, corrected P < 0.0022) and lower LZC (15–27 Hz, unpaired t-test, P < 0.01) than other patients with generalized dystonia. On the other hand, the TWNK mutation patients showed decreased low frequency and beta oscillation in the GPi after DBS, as well as improved movement performance.ConclusionThe LFPs were different in TWNK mutation dystonia siblings than other patients with generalized dystonia, which indicate the abnormal LFPs were related to symptoms rather than specific disease. In addition, the inhibited effect on oscillations also provided a potential evidence for DBS treatment on rare movement disorders.SignificanceThis study could potentially aid in the future development of adaptive DBS via rare disease LFPs comparison.     

经颅磁刺激的多尺度建模仿真研究

经颅磁刺激是一种无创无痛的电磁刺激手段，被广泛应用于神经调控，在临床上对多种精神疾病和神经类疾病有明显的治疗效果。本文从电磁场建模仿真，细胞跨膜电位建模仿真，以及神经元响应建模仿真3个方面对经颅磁刺激多尺度建模仿真研究进行了详细的综述，并提出现阶段存在的问题以及对未来的展望。经颅磁刺激的多尺度建模仿真对磁刺激仪的设计开发具有指导意义，对磁刺激的导航系统提供重要的理论基础，有助于我们更好的理解电磁刺激的神经调控机制。     

Glimepiride prevents paraquat‐induced Parkinsonism in mice: involvement of oxidative stress and neuroinflammation

There is a growing number of epidemiological and molecular studies which suggest that diabetes is associated with an increased risk of Parkinson's disease (PD). Hence, in this study, the effect of glimepiride (GPD), a sulphonylurea (antidiabetic) on paraquat (PQT)‐induced Parkinsonism was evaluated in mice. Thirty‐six mice were randomly divided into six groups (n = 6) and treated orally for 21 consecutive days as follows: Group 1: vehicle (10 mL/kg), Group 2: PQT (10 mg/kg, i.p., twice per week for 3 weeks), Group 3–5: GPD (1, 2 or 4 mg/kg) + PQT (10 mg/kg, i.p., twice per week for 3 weeks), Group 6: GPD (4 mg/kg, p.o.). The effects of the treatment on motor coordination were evaluated using the rotarod performance, bar and open field tests while working memory was assayed using Y‐maze test. Paraquat injection induced significant decrease in falling time, number of crosses and percentage alternation behaviour with a concomitant increase in the duration of cataleptic behaviour in the rotarod, open field, Y‐maze and bar tests, respectively, which was ameliorated by GPD treatment. PQT also increased lipid peroxidation, peroxynitrite and TNF‐α generations as well as deficit in superoxide dismutase and GSH activities in the midbrain. PQT‐induced oxidative stress and neuroinflammation was attenuated by GPD treatment. Findings from this study showed that GPD prevents PQT‐induced motor dysfunction, memory impairment, oxidative stress and neuroinflammation through enhancement of antioxidant defense system and inhibition of pro‐inflammatory cytokine release. Thus, GPD could be a potential adjunct in the management of Parkinsonism.     

Multiparametric classification of sub‐acute ischemic stroke recovery with ultrafast diffusion, 23Na,and MPIO‐labeled stem cell MRI at 21.1 T

MRI leverages multiple modes of contrast to characterize stroke. High‐magnetic‐field systems enhance the performance of these MRI measurements. Previously, we have demonstrated that individually sodium and stem cell tracking metrics are enhanced at ultrahigh field in a rat model of stroke, and we have developed robust single‐scan diffusion‐weighted imaging approaches that utilize spatiotemporal encoding (SPEN) of the apparent diffusion coefficient (ADC) for these challenging field strengths. Here, we performed a multiparametric study of middle cerebral artery occlusion (MCAO) biomarker evolution focusing on comparison of these MRI biomarkers for stroke assessment during sub‐acute recovery in rat MCAO models at 21.1 T. T₂‐weighted MRI was used as the benchmark for identification of the ischemic lesion over the course of the study. The number of MPIO‐induced voids measured by gradient‐recalled echo, the SPEN measurement of ADC, and ²³Na MRI values were determined in the ischemic area and contralateral hemisphere, and relative performances for stroke classification were compared by receiver operator characteristic analysis. These measurements were associated with unique time‐dependent trajectories during stroke recovery that changed the sensitivity and specificity for stroke monitoring during its evolution. Advantages and limitations of these contrasts, and the use of ultrahigh field for multiparametric stroke assessment, are discussed.     

Inherently decoupled 1H antennas and 31P loops for metabolic imaging of liver metastasis at 7 T

High field ³¹P spectroscopy has thus far been limited to diffuse liver disease. Unlike lower field‐strength scanners, there is no body coil in the bore of the 7 T and despite inadequate penetration depth (<10 cm), surface coils are the current state‐of‐the‐art for acquiring anatomical images to support multinuclear studies. We present a system of proton antennas and phosphorus loops for ³¹P spectroscopy and provide the first ultrahigh‐field phosphorus metabolic imaging of a tumor in the abdomen. Herein we characterize the degree to which antennas are isolated from underlying loops. Next, we evaluate the penetration depth of the two antennas available during multinuclear examinations. Finally, we combine phosphorus spectroscopy (two loops) with parallel transmit imaging (eight antennas) in a patient. The loops and antennas are inherently decoupled (no added circuitry, <0.1% power coupling). The penetration depth of two antennas gives twice that of conventional loops. The liver and full axial slice of the abdomen were imaged with eight transmit/receive antennas using parallel transmit B1‐shimming to overcome image voids. Phosphorus spectroscopy from a liver metastasis resolved individual peaks for phosphocholine and phosphoethenalomine. Proton antennas are inherently decoupled from phosphorus loops. By using two proton antennas it is possible to perform region‐of‐interest image‐based shimming in over 80% of the liver volume, thereby enabling phosphorus spectroscopy of localized disease. Shimming of the full extent of the abdominal cross‐section is feasible using a parallel transmit array of eight antennas. A system architecture capable of supporting eight‐channel parallel transmit and multinuclear spectroscopy is optimal for supporting multiparametric body imaging, including metabolic imaging, for monitoring the response of patients with liver metastases to cancer treatments and for patient risk stratification. In the meantime, the existing infrastructure using two antennas is sufficient for preliminary studies in metabolic imaging of tumors in the liver.     

Long-term directional deep brain stimulation: Monopolar review vs. local field potential guided programming

BackgroundDirectional subthalamic stimulation in Parkinson's disease can increase stimulation threshold for adverse effects and widen the therapeutic window. However, selection of programming settings is time consuming, requiring a thorough monopolar clinical review. To overcome this, programming may be guided by intraoperatively recording local field potential beta oscillations (13–35 Hz).Objectives1) Evaluate whether the power of beta oscillations recorded intraoperatively can predict the clinically most effective directional contacts; and 2) assess long-term directional stimulation outcomes between patients programmed based on clinical monopolar review and patients programmed based on beta activity.MethodsWe conducted a non-randomized, prospective study with 24 Parkinson's disease patients divided into two groups. In group A (14 patients, 2016–2018), we investigated whether beta activity in the directional contacts correlated with clinical efficacy. Stimulating parameters were selected according to clinical monopolar review and mean follow-up was 27 months. In group B (10 patients, 2018–2019), stimulating parameters were selected according to beta activity and mean follow-up was 13 months.ResultsNeurophysiological results showed a strong correlation between clinical efficacy and the low-beta sub-band. Contacts with highest beta peaks increased the therapeutic window by 25%. Selecting the two contacts with highest beta peaks provided an 82% probability of selecting the best clinical contact. Clinical results showed similar improvements in group A (motor score, 72% reduction; levodopa-equivalent daily dose, 65% reduction) and B (72% and 63% reduction, respectively), maintained at long-term follow-up.ConclusionsOur results validate the long-term efficacy of directional stimulation guided by intraoperative local field potential beta oscillations.