Wiki source code of to-do-list
Version 1.3 by manuelmenendez on 2025/01/29 18:43
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| author | version | line-number | content |
|---|---|---|---|
| 1 | == **1. Data Management & Integration** == | ||
| 2 | |||
| 3 | * Upload and organize harmonized biomarker datasets (PROMINENT). | ||
| 4 | * Store EEG, sleep, and neuroimaging data in the EBRAINS Bucket. | ||
| 5 | * Convert all datasets to .csv, .json, or .h5 formats for easier AI processing. | ||
| 6 | * Implement automated data ingestion scripts to streamline updates from new sources. | ||
| 7 | * Set up data harmonization methods to ensure consistency across different sources. | ||
| 8 | * Enable Federated Learning to train AI models on multi-center data without sharing raw patient data (GDPR-compliant). | ||
| 9 | |||
| 10 | == **2. AI-Based Risk Prediction & Diagnosis** == | ||
| 11 | |||
| 12 | * Implement machine learning models for dementia risk stratification (LETHE). | ||
| 13 | * Develop AI-based probabilistic models for filling in missing data (KNN Imputer, Bayesian approaches). | ||
| 14 | * Train AI models using multi-modal data (biomarkers, EEG, MRI, and lifestyle factors). | ||
| 15 | * Store pretrained models in the /models/ directory for future use. | ||
| 16 | * Implement real-time AI-based diagnostic annotation for clinicians. | ||
| 17 | * Add confidence intervals to AI predictions for clinical decision support. | ||
| 18 | * Integrate Explainable AI (SHAP analysis) to ensure transparency and clinician trust. | ||
| 19 | * Implement deep learning for pattern recognition in neuroimaging data (MRI/PET-based feature extraction). | ||
| 20 | * Explore the use of Large Language Models (LLMs) for medical report summarization. | ||
| 21 | |||
| 22 | == **3. EEG, Neuroimaging & Sleep Analysis** == | ||
| 23 | |||
| 24 | * Process EEG/MEG data using MNE-Python (AI-Mind). | ||
| 25 | * Apply EEG biomarkers for dementia detection (spectral analysis, connectivity metrics). | ||
| 26 | * Integrate sleep monitoring data from ADIS (smartwatches, headbands) as an early biomarker. | ||
| 27 | * Use MRI volumetric analysis for assessing brain atrophy in high-risk patients. | ||
| 28 | * Implement functional MRI (fMRI) analysis to link neuroanatomical changes with cognitive function. | ||
| 29 | |||
| 30 | == **4. Clinical Validation & Pilot Testing** == | ||
| 31 | |||
| 32 | * Design a pilot study to validate AI-generated diagnostic scores. | ||
| 33 | * Recruit a multicenter clinical validation cohort across European research hospitals. | ||
| 34 | * Compare AI-based diagnoses with clinician-based diagnoses to measure performance. | ||
| 35 | * Develop validation metrics (e.g., AUROC, precision-recall, false positive rates). | ||
| 36 | * Conduct a prospective study to test predictive accuracy over time. | ||
| 37 | * Implement clinician feedback loops to refine the AI model based on real-world usage. | ||
| 38 | * Publish validation results in peer-reviewed journals for credibility. | ||
| 39 | |||
| 40 | == **5. Ethical, Regulatory & GDPR Compliance** == | ||
| 41 | |||
| 42 | * Ensure AI models comply with the EU AI Act for medical applications. | ||
| 43 | * Implement privacy-preserving AI techniques (Federated Learning, Differential Privacy). | ||
| 44 | * Develop patient data anonymization pipelines before AI processing. | ||
| 45 | * Secure ethics approval for data usage in clinical applications. | ||
| 46 | * Set up consent management systems for patient data contributions. | ||
| 47 | * Ensure interoperability with hospital Electronic Health Records (EHRs). | ||
| 48 | |||
| 49 | == **6. EBRAINS Deployment & Cloud Infrastructure** == | ||
| 50 | |||
| 51 | * Deploy AI models on EBRAINS Cloud for real-time inference. | ||
| 52 | * Set up Jupyter Notebooks in EBRAINS Lab for collaborative development. | ||
| 53 | * Automate model training pipelines using GitHub Actions or EBRAINS’ HPC. | ||
| 54 | * Optimize computational efficiency to ensure AI inference runs on real-time clinical data. | ||
| 55 | |||
| 56 | == **7. Interactive Web App for Clinicians & Researchers** == | ||
| 57 | |||
| 58 | * Develop an interactive web-based AI diagnostic tool (Flask, FastAPI, or Streamlit). | ||
| 59 | * Allow clinicians to input biomarker data and get real-time AI predictions. | ||
| 60 | * Enable PDF report generation for clinical decision-making. | ||
| 61 | * Integrate custom dashboards with risk stratification results. | ||
| 62 | * Deploy the tool on **neurodiagnoses.com** using Netlify, Vercel, or AWS. | ||
| 63 | |||
| 64 | == **8. Cross-Project Collaborations** == | ||
| 65 | |||
| 66 | * Partner with AI-Mind for integrating EEG-based predictive models. | ||
| 67 | * Collaborate with LETHE on lifestyle-based cognitive decline risk scoring. | ||
| 68 | * Use PROMINENT’s multi-modal AI pipeline for refining dementia subtype classification. | ||
| 69 | * Leverage ADIS sleep monitoring research for non-invasive biomarker expansion. | ||
| 70 | * Expand partnerships with clinical institutions to increase dataset size. | ||
| 71 | |||
| 72 | == **9. Long-Term Expansion & Future Goals** == | ||
| 73 | |||
| 74 | * Explore AI-powered disease progression models for tracking neurodegeneration over time. | ||
| 75 | * Develop real-time multimodal patient monitoring (EEG, MRI, biomarkers, lifestyle). | ||
| 76 | * Investigate genomics and proteomics for precision diagnostics. | ||
| 77 | * Integrate wearable health tracking for continuous cognitive assessment. | ||
| 78 | * Create an open-access AI diagnostic API for global research collaborations. |
- 1. Data Management & Integration
- 2. AI-Based Risk Prediction & Diagnosis
- 3. EEG, Neuroimaging & Sleep Analysis
- 4. Clinical Validation & Pilot Testing
- 5. Ethical, Regulatory & GDPR Compliance
- 6. EBRAINS Deployment & Cloud Infrastructure
- 7. Interactive Web Application for Clinicians & Researchers
- 8. Cross-Project Collaborations
- 9. Long-Term Expansion & Future Goals