Alzheimer Disease Clinical Trial
— StimoLaMenteOfficial title:
StimoLaMente - La Stimolazione Cerebrale Non Invasiva Applicata Alla Riabilitazione Della Malattia di Alzheimer/ StimoLaMente - Applying Non-invasive Brain Stimulation in Alzheimer's Rehabilitation
Presently, few studies have evaluated the clinical impact of rTMS in Alzheimer's disease. Though some studies have demonstrated an improvement, there have been conflicting results, as others do not seem to demonstrate beneficial effects. Furthermore, it is the combined application of rTMS with cognitive training that could represent a real turning point in interventions aiming to slow down cognitive decline resulting from AD. Research has shown that the best way to promote the strengthening of a network is to stimulate the area while simultaneously activating the network (i.e. through cognitive training) which supports the specific function of interest. Recently, there have been new protocols from animal model research showing that "bursts" of repetitive stimulation at a high theta frequency induce synaptic plasticity in a much shorter time period than required by standard rTMS protocols. This type of rTMS stimulation, theta-burst stimulation (TBS), is therefore even more compelling as a therapeutic intervention given that it includes the benefits previously ascribed to other rTMS protocols, but requires less administration time. Furthermore, studies conducted using both types of stimulation suggest that TBS protocols are capable of producing long term effects on cortical excitability that exceed the efficacy of those using standard rTMS protocols. This project offers patients the possibility of accessing an innovative non-invasive, and non-pharmacological treatment. The goal is to evaluate the clinical efficacy TBS in patients diagnosed with mild cognitive decline (MCI) and AD, verifying if TBS in conjunction with cognitive training produces results better than those obtainable with only one of the two methodologies alone. Patients will be evaluated throughout the full scope of the treatment period, through clinical assessments and neuropsychological evaluations. We will examine neuroplastic changes by investigating the neural correlates underlying improvements using the multimodal imaging technique: TMS-EEG co-registration. A secondary objective will be to define the most effective stimulation protocol, verifying if TBS applied continuously (cTBS) or intermittently (iTBS) produces better behavioral outcomes. The results will be crucial to gain a better understanding of the mechanisms through which brain stimulation contributes to the promotion of neuroplasticity, and the efficacy of TBS combined with cognitive training.
Status | Recruiting |
Enrollment | 200 |
Est. completion date | January 31, 2024 |
Est. primary completion date | January 31, 2024 |
Accepts healthy volunteers | No |
Gender | All |
Age group | 50 Years to 85 Years |
Eligibility | Inclusion Criteria: General Inclusion Criteria (must be met for both AD and MCI group): - right-handed - normal or corrected to normal vision through lenses - meet inclusion criteria related to TMS - Be able to provide information regarding their cognitive and functional skills, or have a caregiver available who is able to provide the patient information necessary for participation in the study and who is present when signing the patient's informed consent. AD Patient Inclusion Criteria: - Mini Mental State Examination (MMSE) score = 16; - Stable intake of cholinesterase inhibitors for at least 3 months before the start of the protocol MCI Patient Inclusion Criteria: - Diagnosis of mild cognitive impairment - Mini Mental State Examination (MMSE) score = 24; Patients will be selected through clinical evaluation (battery of neuropsychological tests at the Neurocognitive Rehabilitation Center (CeRiN) and, in accordance with the APSS, a CSF and PET examination will be performed as well as a further finalized neuropsychological evaluation for research. Exclusion Criteria: - Patients who are unable to perform the tasks required by the experimental procedure; - History and / or evidence of any other central nervous system disorder that could be interpreted as a cause of dementia such as structural or developmental abnormality, epilepsy, infectious disease, degenerative or inflammatory/demyelinating diseases of the central nervous system such as Parkinson's disease or Fronto-temporal dementia - History of significant psychiatric disease which, in the investigator's judgment, could interfere with study participation - History of alcohol or other substance abuse, according to DSM-V criteria, or recent or previous history of drug abuse if this could be a contributing factor to dementia - Ongoing treatments with drugs that contain / intake of the following substances: imipramine, amitriptyline, doxepin, nortriptyline, maprotiline, chlorpromazine, clozapine, foscarnet, ganciclovir, ritonavir, amphetamines, cocaine, (MDMA, ecstasy), phencyclidine (PCP, angel dust), gamma-hydroxybutyrate acid (GHB), theophylline - Presence of cardiac pacemakers, electronic prostheses, bio-stimulators, metal inserts or electrodes implanted in the brain or skull or spine. Absolute exclusion criteria (Criteria for TMS), which in detail are: - presence of cardiac pace-makers, artificial heart valves and / or bio-stimulators - presence of hearing aids located in the middle ear; - presence of metal inserts on the head and shoulders; |
Country | Name | City | State |
---|---|---|---|
Italy | Centro Interdipartimentale Mente/Cervello - CIMeC | Rovereto | Trento |
Lead Sponsor | Collaborator |
---|---|
Università degli Studi di Trento |
Italy,
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* Note: There are 34 references in all — Click here to view all references
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Primary | Face-name associative memory performance - Measure of Memory Recall | Mean change in performance in ability to correctly memorize face/name paired associations [score range min=7, max=n/a, higher score=better outcome]. Patients will start at level 7, the level at which the training software begins paired face/name associations. The software will not allow the patient to go below level 7, so this is the minimum score (level) threshold for all patients. | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Primary | Mini-Mental State Evaluation (MMSE) Score - Non-Trained Measure of Global Function | Neuropsychological evaluation using mean changes in the Mini-Mental State Evaluation(MMSE) score Score range is from 0-30, with a score of 25 or higher is classed as "normal". If the score is below 25, the result indicates a possible cognitive impairment. A lower score = worse outcome | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | TMS evoked potentials - TEP: Analysis of cortical excitability and inhibition changes induced in the state of excitability/inhibition of brain circuits following the TMS impulse. | 120 pulses will be delivered to the target area (right DLPFC or left DLPFC) at 110% resting motor threshold intensity during EEG registration. This outcome will analyze cortical excitability and inhibition changes induced in the state of excitability/inhibition of brain circuits following the TMS impulse. The amplitude will be used as a marker of cortical excitability. | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Connectivity Index - Connectivity evoked by TMS: cortico-cortical connectivity analysis | 120 pulses will be delivered to the target area (right DLPFC or left DLPFC) at 110% resting motor threshold intensity during EEG registration. This outcome will analyze changes in the latencies and topographical distribution of the TEPs thus providing a connectivity index. This connectivity index will be used to infer the propagation of the activity from the stimulation site to functionally connected areas. | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | TMS evoked oscillations: changes induced by TMS and its influence on intrinsic oscillatory activity | 120 pulses will be delivered to the target area (right DLPFC or left DLPFC) at 110% resting motor threshold intensity during EEG registration. This outcome will analyze changes in responses induced by TMS in the frequency domain for the intrinsic capacity of the stimulated area to generate oscillatory activity in specific frequency bands. | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Raven's Colored Progressive Matrices: Evaluation of abstract non-verbal reasoning | Mean changes in test scores [score range 0-36, higher score=better outcome]) | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Digit Span: Evaluation of short and long term memory (verbal) | Mean changes in test scores [score range 0-9, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Spatial Span: Evaluation of short and long term memory (visuospatial) | Mean changes in test scores [score range 0-10, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Prose Memory:Evaluation of short and long term memory | Mean changes in test scores [score range 0-28, higher score=better outcome]; | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Free And Cued Selective Reminding Test: Evaluation of short and long term memory | Mean changes on tests scores [Immediate: score range 0-36; Deferred: score range 0-12, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Deferred re-enactment of the Complex Figure by Rey Osterrieth: Long term memory evaluation | Mean changes on tests scores [score range 0-36, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Token Test: Evaluation of linguistic production | Mean changes on tests scores [score range 0-36, higher score = better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Semantic fluency and Phonemic fluency | Mean changes on tests scores: [score range 0-no limits, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Multiple Features Cancellation task: Evaluation of attention and executive function "MFCT" | Mean changes in scores on MFCT Time [score range, min= N/A, max= no limit, higher score=worse outcome; Mean changes in scores on MFCT Accuracy [score range min=0, max=20, higher score=better outcome]; Mean changes in scores on MFCT False alarm [score range min: N/A, max= no limit, high score=worse outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Trail Making test (for A, B and B-A conditions): Evaluation of attention and executive function | Mean changes on scores for each condition [score range: min= n/a, max= no limits, higher score=worse outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Stroop test Error and Time: Evaluation of attention and executive function | Mean changes on scores [score ranges min=N/A, max= no limit, higher score=worse outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Attentional Matrices: Evaluation of attention and executive function | Mean changes on scores [score range 0-60, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Copy of Rey's Complex Figure: Evaluation of practical and visual-constructive skills | Mean changes on scores [score range 0-36, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Geriatric Depression Scale, GDS:Evaluation of depressive symptoms in the elderly | Mean changes on scores [score range 0-30, higher score=worse outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Questionnaire of Identification of Deficits (QID): Evaluation on quality of life and identification of deficit questionnaire for the patient and caregiver | Mean changes on scores [score range 0-52, higher score=worse outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Clinical Insight Rating Scale, (CIRS): Evaluation of awareness of deficits and disease | Mean changes on scores [score range 0-8, higher score=worse outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) | |
Secondary | Jefferson Scale: Evaluation of the patient's perception of empathy | Mean changes on scores [score range 0-35, higher score=better outcome] | Prior to treatment (baseline=t0=week 1), at the end of the intensive treatment phase (t1=Week 4), at the end of the maintenance phase (t2=Week 8), 3 months post-treatment (t3=Week 12), & 5 months post treatment (t4=Week 20) |
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Phase 2 | |
Active, not recruiting |
NCT03676881 -
Longitudinal Validation of a Computerized Cognitive Battery (Cognigram) in the Diagnosis of Mild Cognitive Impairment and Alzheimer's Disease
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Terminated |
NCT03487380 -
Taxonomic and Functional Composition of the Intestinal Microbiome: a Predictor of Rapid Cognitive Decline in Patients With Alzheimer's Disease
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N/A | |
Completed |
NCT05538455 -
Investigating ProCare4Life Impact on Quality of Life of Elderly Subjects With Neurodegenerative Diseases
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N/A | |
Recruiting |
NCT05328115 -
A Study on the Safety, Tolerability and Immunogenicity of ALZ-101 in Participants With Early Alzheimer's Disease
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Phase 1 | |
Completed |
NCT05562583 -
SAGE-LEAF: Reducing Burden in Alzheimer's Disease Caregivers Through Positive Emotion Regulation and Virtual Support
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N/A |