Deep Brain Stimulation in Alzheimer's Disease: Biomarkers and Dose Optimization

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Background/Rationale: Despite years of recognition and attempts at treatment, Alzheimer's Disease (AD) remains a pervasive and challenging condition, with an inexorable progression to severe disability and death once a diagnosis is made. The latest attempts at pharmacologic have yielded, at best, ve...

Background/Rationale: Despite years of recognition and attempts at treatment, Alzheimer's Disease (AD) remains a pervasive and challenging condition, with an inexorable progression to severe disability and death once a diagnosis is made. The latest attempts at pharmacologic have yielded, at best, very modest results. There exists, therefore, no treatment for AD that significantly slows down its progression, and alters the metabolic milieu of AD brains. We have conducted and published the world's first phase I safety and feasibility trial of deep brain stimulation (DBS) for early Alzheimer's Disease and the first Phase II randomized, placebo-controlled study of DBS in the same population. These trials have had the following three objectives: 1) establishing the safety of DBS in AD, 2) studying the possible slowing of cognitive decline in AD, and 3) studying the relationship between focal brain stimulation and metabolic changes in regions known to be affected by AD neurodegeneration. With this background, we now want to continue and expand our DBS for AD trials. The rationale of the currently proposed study is to optimize patient selection and stimulation parameter dose for DBS for AD. We will measure the effects of DBS on brain amyloid load, on cerebrospinal fluid (CSF) Alzheimer protein metabolites and will screen various stimulation parameter settings for their acute effects on memory function. The latter will be used in an attempt to define the optimal stimulation dose. The significance of this study is two-fold: 1) A possible demonstration that DBS may directly influence brain pathology in AD as measured by amyloid imaging and CSF protein changes, hence providing a mechanism of action for its clinical effects, and 2) the first study to empirically determine, using a memory task, the optimal stimulation parameters for DBS patients to improve memory function. Study Objectives: Influence of DBS on AD Pathology Early results suggest that DBS may influence cognitive and memory functions in patients with early Alzheimer's Disease (AD). It is not clear, however, whether DBS can directly influence pathology in AD, such as CSF protein biomarkers and amyloid plaque load in the brain. The objective of this study is to analyze CSF and brain plaque load prior to and after surgery to determine whether DBS influences central nervous systems pathology associated with AD. Dose Optimization Currently, selecting the optimal stimulation dose for patients with non-motor conditions (i.e. Alzheimer's Disease, depression, obsessive-compulsive disorder) is performed largely arbitrarily, and borrows heavily from settings used in motor conditions (i.e. Parkinson's Disease, Tremor). The objective of this study is to establish a clinically meaningful dose optimization test that will use the patients' performance on an experimental memory task to determine the optimal stimulation settings. Study Hypotheses: Our study has the following exploratory hypotheses: i. DBS may lead to changes in CSF biomarkers of AD pathology, including tau, phosphorylated tau, and beta amyloid, consistent with plaque clearance ii. DBS may lead to reductions in plaque burden, demonstrated by amyloid PET imaging iii. The optimal dose of brain stimulation, which maximizes benefits and minimizes adverse events, can be selected using an acute memory task performed in the post-operative period. Design and Methodology: This is an open-label, prospective trial designed to measure the influence of DBS on AD brain pathology and to optimize stimulation parameter selection post-operatively. Twelve (12) patients will be enrolled and operated, and followed in an open-label fashion. All subjects will be followed to a common closing date, which will be at the time the last subject enrolled is followed for 12 months. Patient selection and enrollment: Pre-treatment procedures The schedule for individual subjects is outlined below in table format and is displayed in Figure 1 as a flowchart. This study is divided into four phases: screening, baseline, surgery, and on-stimulation. All patients will be recruited through the memory clinic at Toronto Western Hospital and local advertisements. Patients meeting inclusion/exclusion criteria will be approached for participation. There will be two distinct periods of informed consent in this study: the first, to allow study investigators to screen patients for study inclusion, and the second, to formally enroll patients into the study. Figure 1 outlines the process that will take place for identified patients and the estimated number of individual subjects at each stage. Once patients are identified by the study neurologist, screening consent will be obtained. This consent will signal entrance into the first phase of the study, and indicates that the patient meets inclusion/exclusion criteria. During the screening visit, patients will undergo a medical history and general physical examination, medication screening, electrocardiogram, relevant pre-operative blood work, neuropsychological testing and psychiatric screening: the Alzheimer's Disease Assessment Scale-Cognitive Subscale(ADAS-Cog) Clinical Dementia Rating (CDR) scale, Neuropsychiatric Inventory (NPI), Columbia Suicide Severity Rating Scale (C-SSRS), Cornell Scale for Depression in Dementia (CSDD), Young Mania Rating Scale (YMRS), which will be used to classify participants by inclusion/exclusion criteria. Once the screening is complete, patients will be discussed by the study team to determine whether they should continue in the trial, and progress to the baseline stage. The baseline stage will require an additional informed consent, as this stage signals entry into the formal trial. Baseline investigations will commence within 2 months of signing baseline consent, and can take place up to within 1 day of surgery ("implantation"). Baseline investigations will include all tests and examinations done during Screening (excepting the ECG), with the addition of: the Alzheimer's Disease Cooperative Study Activities of Daily Living Inventory 23-item Scale (ADCS-ADL23), the Hopkins Verbal Learning Test (HVLT), neuroimaging (MRI and Amyloid PET) as well as a lumbar puncture (LP) for AD protein markers. Participants will also complete acute experimental memory tasks that will be used in the 'dosing' phase, to familiarize them with the procedure. For these memory tasks, patients will view stimuli (e.g., objects, faces, scenes, words), and then be asked to remember them. In addition, an experimental visual associative recognition task, which is a simplified version of the one that was critical in identifying memory-specific effects in the sentinel case (Hamani et al 2008), will be introduced at this stage. Once all baseline investigations are complete, patients will be scheduled for surgery and implantation. Treatment procedures - DBS surgery DBS surgery will be performed as is done routinely and has been performed on the previous 18 patients with AD at our centre. Patients will arrive on the morning of surgery at the Toronto Western Hospital medical imaging department. They will have a small part of their head shaved and then have a stereotactic frame attached directly to their skull, after infiltration with local anaesthesia. The frame allows precise co-ordinates to be acquired so that deep brain structures can be targeted with implanted electrodes. The patient will then undergo an MRI scan (for surgical planning) with the frame in place, followed by transport directly to the operating room. The anaesthesia team will insert an intravenous line followed by induction and initiation of general anaesthesia (GA). The entire case, including electrode implantation and implantation of the pulse generator, will be done under general anaesthesia with the patient fully asleep. In the operating room the patient's head, via the frame, will be attached to the operating room table, and their scalp infiltrated with additional local anaesthetic. A skin incision will be made and two 2.5 mm diameter burr holes drilled through the skull. A DBS electrode will be delivered at the fornix target as identified on the MRI scan obtained earlier in the morning. The patient will be monitored throughout the entire case. Once implanted, the second stage of the operation with begin (about 30 min) whereby the electrodes are connected to a battery placed under the right collarbone. With the patient asleep, the electrodes are tunneled to the battery, and connected. Both the head and chest incisions are then closed and the patient transferred to the recovery room. Following surgery, the patient will be transferred to the neurosurgical ward for recovery. On the first post-op day, they will undergo an MRI of their brain to confirm the electrode location. Should the electrodes be in a suboptimal location (e.g. nearby but not within the target), patients will be offered several options: re-operation for lead repositioning, leave the system in place and turn device on, leave the system in place and keep device off, or removal of the system completely. Recovery following surgery should take 1-2 days, and patients will be discharged home on post-op day 2, with the stimulator in the off position. Patients will return to the neurosurgical clinic two weeks after discharge to check the wound, remove staples, and for routine post-op follow-up. Other Procedures Beta-Amyloid Positron Emission Tomography (PET) scans. Beta-Amyloid PET scans will be used to estimate amyloid burden in the brains of the patients and to probe whether DBS has an impact on this process. Flutemetamol (GE Healthcare) is an FDA-approved amyloid PET radiotracer that has been approved by Health Canada for research use. PET scans will be performed on a Siemens HRRT scanner. During radiotracer uptake, patients will be maintained in a quiet, dimly lit room, with eyes open and ears unoccluded. Ninety minutes after a 5mCi ± 10% radiotracer injection, patients will be positioned in the scanner, and a 20-minute emission scan will be obtained, followed by a transmission scan. Lumbar Puncture (LP) for protein analysis. The procedure is done with patients lying on their side. The skin is washed with sterilizing solution; 3 ml of local anesthetic is injected in the skin and subcutaneous tissue at the lumbar 4/5 level. 6 ml of CSF is removed and distributed in aliquots. The samples are immediately frozen and stored at -80C. CSF levels of Tau, phosphoTau and beta amyloid are determined by standard protein analysis. The analysis will be performed as per the Alzheimer's Disease Neuroimaging Initiative (ADNI) guidelines. Stimulation dose finding studies. At the patient visits, the DBS will be programmed to test the effects of various stimulus settings on memory performance. Testing sessions will last up to 2.5 hours or less if, the patient becomes tired. Settings will be adjusted to ensure that the patients do not feel or experience adverse effects. Heart rate will be monitored during programming. Patients will be asked to perform a memory task at each of the tested settings to determine optimal setting during subsequent visits. This setting will remain stable until the next visit, at which time settings will again be evaluated and may be changed. For the memory tasks, patients will view stimuli (e.g., objects, faces, scenes, words), and will then be asked to remember the stimuli. Each test will last approximately 5-10 minutes.

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