Loss of long‐term benefit from VIM‐DBS in essential tremor: A secondary analysis of repeated measurements

1 INTRODUCTION

Essential tremor (ET) is the most common type of pathologic tremor, with a prevalence of nearly 5% in elderly individuals.1-3 Pharmacotherapy is the primary treatment for most patients.4 However, it is only effective in 50% of patients.5-7 Surgical treatment is required for drug-refractory patients.8, 9 The U.S. Food and Drug Administration (FDA) approved the use of ventral intermediate nucleus deep brain stimulation (Vim-DBS) for the treatment of ET in 1997.8 Since then, DBS has been widely accepted for the treatment of ET and has shown promising short-term outcomes. Studies have reported that approximately 60% to 80% reduction in tremor can be realized within 1 year after deep brain stimulation (DBS).10, 11 However, the reported long-term effects have been a topic of debate. Sandoe et al.12 reported that anterior electrode placement of DBS leads to long-term beneficial outcomes over 3 years, while Pahwa et al.13 reported that Vim-DBS was associated with a 65% improvement rate after 5 years of follow-up. However, Shih et al.14 found that the treatment's benefits waned in approximately two-thirds of patients after more than 5 years. Similarly, Lu et al.15 reviewed the literature and reported that the efficacy of Vim-DBS diminished over the long term. Thus, they speculated that the long-term efficacy of Vim-DBS was unreliable.

The reason for the loss of efficacy of DBS has attracted much research attention, with the current debate being centered on two reasons. The first of these is DBS tolerance, in which the brain shows a loss of response to Vim-DBS with the stimulation on (stim-on).16 The mechanism of DBS tolerance may involve attenuation of synchronous inhibition of cerebellar fiber tracts.17 The second reason is disease progression, which is defined by an increase in scores in the stimulation off (stim-off) state. However, the improvement in the stim-on state over the findings in the stim-off remains the same as before. Favilla et al.18 conducted a prospective cohort study, pointing out that the “loss of benefit” is also due to disease progression and cannot be attributed to DBS tolerance alone. Whether the effects of Vim-DBS on ET diminish over the long term is inconclusive, and if so, the reasons for this decrease remain to be explored. In this regard, research accounting for the efficacy reduction of Vim-DBS in detail has remained limited, and a summary of the prognoses of long-term outcomes is needed.

To address this gap in the literature, the present study aimed to evaluate the treatment efficacy and disease progression at different time points in ET and to compare the long-term and short-term efficacy at both stim-off and stim-on statuses. The predictive factors for the long-term efficacy of Vim-DBS were also identified.

2 METHODS 2.1 Literature review

This study followed the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines,19 and the study design was based on the PICOS strategy. We reviewed relevant studies in four databases (PubMed, Embase, World of Science, and the Cochrane Library). The search terms used were “essential tremor” and “deep brain stimulation” in the title, abstract, or keywords. For ET, we searched for the following terms: essential tremor OR idiopathic tremor OR senile tremor OR benign tremor OR ET. For DBS, we searched for the following terms: deep brain stimulation OR electrical stimulation therapy OR neuromodulation OR DBS. The time frame was from January 1, 1999, to August 31, 2019. Only studies published in English and those involving human participants were included. We also cross-referenced some important articles by searching for articles citing and cited by them. Two authors (BYT and YZX) independently reviewed all the studies. We excluded irrelevant articles by scanning the abstracts and then checked the full text of relevant studies to further confirm if they should be included. For studies conducted in the same institution that covered the same group of patients, we only included the latest study with the largest sample size.

2.2 Inclusion and exclusion criteria

The inclusion criteria were as follows: (1) the study participants were patients diagnosed with ET according to the consensus statement of the Movement Disorder Society20; (2) the patients were treated with Vim-DBS; (3) the studies used the Fahn-Tolosa-Marin Tremor Rating Scale (TRS) to evaluate disease severity; and (4) the studies reviewed both preoperative and postoperative clinical data.

The exclusion criteria were as follows: (1) the study participants were also diagnosed with other tremors; (2) the study participants received other surgical treatments prior to Vim-DBS; (3) more than two leads or more than one target nucleus were implanted in the patients; (4) the scale assessment was conducted online; (5) the studies only reported subitem scores, such as right limb posture scores or head scores; and (6) necessary data (mean or SD) were not reported.

2.3 Quality assessment

We used the Meta-analysis Of Observational Studies in Epidemiology (MOOSE) guideline21 to assess the bias of observational studies when assessing the quality of studies with respect to the following six different aspects: (1) clearly defined study population with more than five properly diagnosed patients; (2) clearly defined outcomes and outcome assessment, which included the TRS total score and the motor, hand-function, and activities of daily living (ADL) subscores; (3) outcome parameters assessed independently, with the assessor and the assesses remaining anonymous; (4) a sufficient follow-up period lasting at least for 6 months; (5) no significant selective loss during follow-up, with a loss rate less than 15%; and (6) identification of important confounders or prognostic factors (reporting baseline features). The total score ranged from 0 (lowest quality) to 6 (highest quality). Research scores of more than four were considered to indicate high quality. Details were in Table S2.

2.4 Data extraction

We extracted the following variables: study type (prospective or retrospective study), study institution, age at surgery, unilateral or bilateral DBS, medications, sex, duration, number of patients, preoperative TRS scores (TRS total score and motor, hand-function, and ADL subscores), follow-up time points, the four TRS scores at different postoperative time points, and programming parameters at the last follow-up. The TRS scores were collected under two conditions: with stimulation (stim-on) and without stimulation (stim-off).22 We divided the follow-up time points into four groups: 6 months, 7–12 months, 1–3 years, and >4 years.23 For each period, mean and SD values of the scores were extracted. For studies with no SD reported, we extracted the p value, standard error (SE), and the 95% confidence interval to estimate the SD.24 Two authors (BYT and YZX) extracted the data independently, and consensus was reached through discussion when disagreements occurred. If no consensus could be reached through discussion, the final decision was made by the corresponding author (ZJG).

2.5 Analysis process

This study was a meta-analysis of single-arm repeated measurements. We used the all-time-points meta-analysis (ATM) and the change-in-time meta-analysis (CTM) methods to calculate the differences between different time points.25 ATM is used to pool the data from all time points and compare it with the baseline. The advantage of ATM is that it compares the scores over several time points with the preoperative scores. In this study, we obtained data for four postoperative time points, and we used ATM to compare the corresponding scores with the baseline. CTM focuses on the changes between the estimates at successive time points. CTM can be performed in two ways: the differences between successive time points are calculated and combined,26 or the difference from baseline to each time-point is calculated.27 Here, we used the second CTM method to compare the changes in differences between the two time points and the baseline (6 months and 4 years). Specifically, we first calculated the mean difference in TRS scores (TRS total scores, motor scores, hand-function scores, and ADL scores) between different time points in different conditions (stim-on/stim-off) in comparison with the baseline. Then, we pooled the data for each time point (baseline, 6 months, 7–12 months, 1–3 years, and >4 years). Second, we used the TRS scores in the stim-on condition to calculate the improvement rate in comparison with the baseline at different follow-up time points. The TRS scores in the stim-off condition were used to calculate the rate of disease progression, where positive values indicated disease deterioration and negative values indicated continued improvement. Then, we compared the improvement rate and disease progression rate at different time points with the baseline by using the ATM method. More importantly, we compared the long-term outcomes (≥4 years) with short-term outcomes (≤12 months) in the stim-on condition to reveal the stability of DBS in ET by using the CTM method. Finally, we performed a meta-regression to show which factors affected DBS improvement in the long term (4 years).

2.6 Statistical analysis

This study was registered in PROSPERO (CRD42020151511). All statistical analyses were performed using Comprehensive Meta-Analysis Version 3.3 (Biostat). Data displayed only on graphs were extracted by the Web Plot Digitizer (https://automeris.io/WebPlotDigitizer/). To analyze standardized mean differences (SMDs) between FTM-TRS scores at different time points, a corrected effect size (Hedges' g) was calculated for each study, wherein the pooled weighted standard deviations were employed to correct for the small sample size. Heterogeneity was assessed using the standard Cochrane Q and I2 statistics. Because this study involved single-arm analysis, we employed random-effects models. Meta-regression analysis was performed using the maximum likelihood method. Finally, publication bias was assessed using Egger's test. Differences were considered statistically significant at p < 0.05.

3 RESULTS 3.1 Literature review

The literature search yielded a total of 3308 articles from four main databases. Based on the inclusion criteria, 18 studies with 533 patients were included in our study. Figure 1 shows the flow diagram of the literature search. We reviewed all studies and summarized the baseline characteristics in Table 1. The average age of these patients was 67.7 years, and the mean ET duration was 27.5 years. Various methods of electrode positioning were employed in these studies, and the common steps were as follows: localization of the VIM by magnetic resonance imaging (MRI) fused with stereotactic framed head CT superimposed by an anatomic atlas, placement of the lead during the microelectrode recording (MER), and testing of the DBS effect intraoperatively. Approximately, 61% (11/18) of the studies carried out the entire process, while 28% (5/18) omitted the MER step and used MRI to localize the lead and tested the DBS effect by the intraoperative stimulation test (IST) subsequently. Only 11% (2/18) of the studies only reported MRI localization without describing any intraoperative testing. We extracted time points in all studies and sorted them into four groups (Table S1). Since the studies included different subscales of the TRS scores, we evaluated the publication bias and found no significant publication bias (Table S3).

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The flow of the literature search

TABLE 1. Baseline characteristics of the included studies Study Quality Study type Number Age (year) Disease duration (years) MRI MER Macrostimulation Paschen 201928 6 Retrospective 20 67 ± 8 37 ± 17 √ √ √ Klein 201729 4 Retrospective 26 67 ± 9 25 ± 17 √ × × Favilla 201230 6 Retrospective 28 74 ± 11 37 ± 20 √ √ √ Heber 201331 6 Prospective 9 66 ± 9 24 ± 16 √ × √ Blomstedt 200732 6 Retrospective 19 68 ± 7 23 ± 17 √ × √ Rezaei 201733 6 Retrospective 10 70 ± 19 32 ± 19 √ × √ Rodríguez 201634 5 Retrospective 14 61 ± 3 25 ± 11 √ √ √ Sydow 200335 6 Retrospective 19 62 ± 11 38 ± 12 √ √ √ Fields 200336 6 Prospective 40 72 ± 9 18 ± 13 √ × √ Cury 201737 6 Retrospective 38 64 ± 11 21 ± 13 √ √ √ Higuchi 201538 5 Retrospective 44 66 ± 10 22 ± 14 √ √ √ Pahwa 200639 5 Prospective 28 70 ± 5 NA √ √ √ Putzke 200440 6 Prospective 52 72 ± 8 25 ± 16 √ √ √ Rehncrona 200341 5 Retrospective 19 66 ± 11 30 ± 14 √ × √ Ondo 200142 6 Prospective 13 72 ± 5 NA √ NA NA Kumar 199943 6 Retrospective 9 69 ± 10 26 ± 15 √ √ √ Vesper 200444 5 Retrospective 18 NA NA √ √ √ Wharen 201745 6 Prospective 127 65 ± 10 29 ± 17 √ √ √ Abbreviations: IST, intraoperative stimulation test; MER, microelectrode recording; MRI, magnetic resonance imaging. 3.2 Tremor Rating Scale scores at different time points

We analyzed the TRS total score and the motor, hand-function, and ADL subscores in both stim-on and stim-off conditions at different time points. We first compared the follow-up scores with the baseline in the stim-on condition (Figure 2 and Table S4). The score changes were considered to reflect improvements during the follow-up period. All subscores at all time points showed significant differences in comparison with the baseline. Long-term efficacy was confirmed in the long-term follow-up, and the peak score showed a decreasing trend, although the decrease was statistically insignificant. In the hand-function and ADL subscales, the average rate of improvement after 4 years was only about half of the maximum improvement rate.

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TRS scores at different time points on stimulation. (A) TRS total score, (B) motor subscore, (C) hand-function subscore, and (D) ADL subscore. All scores at all time points were significantly different with preoperative scores. Individual results were presented by dots; the diameter of the dots reflect the sample size of the study. Only one study had a follow-up period between 1 and 4 years (stim-on) in hand-function score. ADL, activities of daily living; TRS, Tremor Rating Scale

The stim-off results are shown in Figure 3 and Table S5. We evaluated the scores on the basis of the disease progression rate, and the findings for the different TRS scores varied widely. The TRS total score indicated progression after 24 months and significant worsening after 4 years. The motor subscore slightly decreased in the first 12 months but deteriorated significantly after 4 years. The hand-function subscore showed no significant difference during the long-term follow-up. However, the changes in the ADL subscore were similar to those in the TRS total score, which remained stable for 12 months and deteriorated after 4 years.

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TRS scores at different time points of stimulation. (A) TRS total scores, (B) motor subscore, (C) hand-function subscore, (D) ADL subscore. ETs progress significantly in both TRS total score and ADL subscore during the long-term follow-up. Motor subscore improved in the first year after DBS, while slightly progressed in the long-term follow-up. Hand-function subscore had not seen significant progressing. Studies which reported stim-off scores were fewer than stim-on scores. Individual results were presented by dots, and the diameter of the dots reflect the sample size of the study. One study reported the 12-month follow-up TRS total scores, and another study reported the 24-month results; we merge them together to calculate the disease progression within 2 years. Only one study had a follow-up period between 1 and 4 years in hand-function score, which was not included in the further analysis. No study reported ADL score in stim-off between 1 and 4 years. ADL, activities of daily living; TRS, Tremor Rating Scale

3.3 Comparisons between short- and long-term follow-up findings

Of the 18 included studies, 9 reported both short-term (<12 months) and long-term (>4 years) results. We extracted these data and displayed the changes from the short to the long term (Table 2). We categorized these results as the loss of the effect of DBS. The motor subscore remained stable during the long-term follow-up, and it showed no significant difference during follow-up (p = 0.183). However, the TRS total score and the other two subscores all indicated a reduction in the efficacy of DBS (p < 0.001, p = 0.036, and p = 0.004).

TABLE 2. Tremor Rating Scale (TRS) score comparison of the short-term and long-term efficacy of deep brain stimulation (DBS) TRS total score (A) Motor subscore (B) Hand-function subscore (C) ADL subscore Studies 3 7 3 5 Point estimate 17.23 2.10 4.84 4.73 Standard error 2.11 1.57 2.31 1.63 Z-value 8.17 1.33 2.09 2.91 p value <0.001* 0.183 0.036* 0.004* Note This table compared the long-term (>4 years) and short-term (<12 months) outcomes to reflect the benefit loss of DBS in different aspects. TRS total score, hand-function subscore, and ADL subscore all showed the benefit loss, while motor subscore kept stable during the long-term follow-up. * Significant difference. 3.4 Comparisons between essential tremor disease progression and loss of deep brain stimulation benefits

In a subsequent analysis, we compared the loss of DBS benefits with ET disease progression (Table 3). DBS tolerance was considered to exist when the loss of benefits was significantly larger than ET disease progression. A significant difference was observed in the hand-function (p < 0.001) and ADL (p = 0.028) subscores, but not in the TRS total score (p = 0.059) or the motor subscore (p = 0.075).

TABLE 3. The comparison between essential tremor (ET) disease progression and deep brain stimulation (DBS) benefit loss TRS total score (A) Motor subscore (B) Hand-function subscore (C) ADL subscore Studies 2a 7 3 3a Point estimate 4.91 −0.86 3.12 1.38 Standard error 2.60 0.48 0.84 0.63 Z-value 1.89 −1.78 3.71 2.19 P value 0.059 0.075 <0.001* 0.028* Note This table shows the comparison between ET disease progression and DBS long-term benefit loss. When benefit loss is significantly larger than disease progression, we considered the results as DBS tolerance. Hand-function and ADL subscores suffer from DBS tolerance during the long-term follow-up. a Only included studies reported both stim-off and stim-on scores in long-term results. * Significant difference. 3.5 Meta-regression for long-term outcomes

Baseline data were collected to determine the predictive factors influencing the long-term outcomes (Figure 4). Due to the insufficient number of studies, we merely performed univariable meta-regression. The predictive factors for the TRS total score were the frequency of stimulation (r = 0.96, p < 0.0001) and the preoperative score (r = 0.97, p < 0.0001). The preoperative score was also a predictive factor for the motor subscore. Frequency showed a negative correlation with the TRS total score, while the preoperative score showed a positive correlation with the TRS total score and motor subscore. No independent prognostic factors were observed for the hand-function and ADL subscores.

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The results of meta-regression. Frequency and preoperative Tremor Rating Scale (TRS) total scores are predictors of the improvement of TRS total score. Preoperative TRS total score is also the predictor of the improvement of TRS motor subscore

4 DISCUSSION

The present investigation is, to our knowledge, the largest study to assess the long-term efficacy of Vim-DBS in the treatment of ET. A total of 533 cases from 18 studies were included in this investigation. We summarized the long-term efficacy of Vim-DBS in four parts (TRS total score, motor function, hand function, and ADL). We also discussed the reasons why Vim-DBS lost its efficacy and explored the predictive factors for long-term efficacy. The evidence obtained in this study suggests that Vim-DBS is a promising treatment in terms of long-term outcomes. The improvement rates of the four parts after a 4-year follow-up period were 40.4% (TRS total score), 47.1% (motor), 29.7% (hand function), and 31.1% (ADL). Efficacy loss was not observed in the motor score, indicating that motor capacity was well-controlled and remained stable over the long term; in contrast, for hand function, the efficacy loss was due to DBS tolerance, and for ADL, the efficacy loss was due to disease progression (Table 4). The preoperative score and stimulation frequency were independent prognostic factors for long-term clinical outcomes. Thus, we recommend that the efficacy of ET treatment should be confirmed from multiple perspectives instead of focusing solely on motor recovery. Improvement of both motor symptoms and actual functions will be a major challenge for future treatment.

TABLE 4. The long-term outcome in each scores Scores Disease progression Benefit loss DBS tolerance TRS total score √ √ × Motor score √ × × Hand-function score × √ √ ADL score √ √ √ Note This table summarized the results of our study. 4.1 Analysis of the Tremor Rating Scale total score and subscores

In our analysis, the efficacy of Vim-DBS for ETs at all time points was significantly different from that at baseline. Previous studies have reported improvements in postoperative TRS scores in assessments of both short- and long-term outcomes.11, 13, 46, 47 We verified that Vim-DBS is a promising treatment for ETs. We further analyzed the disease progression of ET patients and concluded that the TRS total score worsened significantly. Two studies reflected a similar trend: 3.2%–5.3% ET progression per year.48, 49 Notably, the other subscores showed various changes. Motor sc

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