Consciousness Hacking, Perception of time and space, Consciousness in First Person, A Map of the Emotions, Latam Amerindian - TMS and Neuroscience, NIRS EEG Experiments Design
Consciousness Hacking, Perception of time and space, Consciousness in First Person, A Map of the Emotions, Latam Amerindian - TMS and Neuroscience, NIRS EEG Experiments Design
Consciousness Hacking Perception of time and space Consciousness in First Person and A Map of the Emotion
Transcranial Magnetic Stimulation (TMS) and Functional Near-Infrared Spectroscopy (fNIRS), along with Electroencephalography (EEG), are valuable techniques used in neuroscience research for studying brain function. When planning to use these technologies together in experiments, there are several considerations to take into account.
1. TMS & Neuroscience:
Overview: TMS is a non-invasive technique that induces neuronal activity in the brain by applying magnetic fields. It can temporarily stimulate or inhibit specific areas of the brain.
Applications: Used in cognitive neuroscience, clinical psychology, neurophysiology, and psychiatry.
Experiment Design:
Define the target brain region.
Decide on the type of TMS (single-pulse, repetitive, etc.).
Determine stimulation parameters (intensity, frequency, duration).
2. NIRS & EEG Experiments:
Overview: fNIRS measures brain oxygenation, while EEG records electrical activity.
Concurrent Usage: These can be used simultaneously as they measure different brain activity aspects and do not interfere with each other significantly.
Experiment Design for fNIRS & EEG:
Subject Preparation: Ensure proper placement of fNIRS optodes and EEG electrodes on the scalp.
Signal Acquisition: Record both EEG and fNIRS data simultaneously. Consider synchronization issues and time stamp data accurately.
Data Analysis: Preprocess and analyze data separately, then integrate the results for interpretation.
3. Combined Approach with TMS:
If combining TMS with fNIRS or EEG, consider:
Timing: Synchronize the delivery of TMS pulses with data acquisition from fNIRS and EEG.
Artifact Reduction: TMS may induce artifacts in EEG signals; use appropriate filtering and artifact rejection techniques.
Safety: Ensure the experiment is conducted safely, respecting guidelines and contraindications for TMS and electrode placement.
4. Experimental Design Considerations:
Research Question: Clearly define the research question or hypothesis.
Subject Selection: Determine inclusion and exclusion criteria for participants.
Protocol Development: Develop a detailed protocol outlining each step of the experimental procedure.
Ethical Approval: Obtain approval from an ethics committee or institutional review board.
5. Data Analysis & Interpretation:
Process and analyze the data collected from each modality separately and then look for correlations or interactions between the different sets of data.
Employ statistical methods to analyze and interpret the results accurately.
6. Limitations & Challenges:
Be aware of the limitations of each technique and the challenges of integrating data from different modalities.
7. Conclusion:
Draw conclusions based on the data, taking into account the limitations and potential sources of error in the experiment.
When designing experiments with TMS, fNIRS, and EEG, careful planning is crucial to ensure that the data collected is reliable and valid. Consider the logistics of combining these techniques, address synchronization issues, and plan for the analysis of multimodal data. Always conduct these experiments under ethical guidelines, with safety being the top priority. Each method's nuances and complexities require a deep understanding, and consulting literature and experts in the field is advisable as you plan and execute your experiment.
Consciousness in First Person | A Map of the Emotions
A Map of the Emotions
Consciousness in First Person | Perception of time and space
Perception of time and space
Consciousness in First Person | Consciousness Hacking
Consciousness Hacking
TMS and Neuroscience | TMS EEG
For baseline EEG feedback you can have:Return to time less than 10 ms we indicate BrainAmpDC; EEG signal return less than 3 ms indicates actiChamp PLUS.
TMS Application | TMS EEG
For baseline EEG feedback you can have:Return to time less than 10 ms we indicate BrainAmpDC; EEG signal return less than 3 ms indicates actiChamp PLUS.
TMS EEG | TMS EEG
Design of Experiments | Design of Experiments
Design of Experiments
EEG experiment | Design of Experiments
NIRS Experiments Design | Design of Experiments
Design of Experiments
Latam el Nuevo Futuro Ancestral | Latam Amerindian
Latam Amerindian
00:00:00 - 01:39:00 A Map of the Emotions |
01:39:00 - 04:00:00 Perception of time and space |
04:00:00 - 06:57:00 Consciousness Hacking |
06:57:00 - 08:04:00 For baseline EEG feedback you can have:Return to time less than 10 ms we indicate BrainAmpDC;EEG signal return less than 3 ms indicates actiChamp PLUS. |
08:04:00 - 08:40:00 For baseline EEG feedback you can have:Return to time less than 10 ms we indicate BrainAmpDC;EEG signal return less than 3 ms indicates actiChamp PLUS. |
08:40:00 - 09:57:00 For baseline EEG feedback you can have:Return to time less than 10 ms we indicate BrainAmpDC;EEG signal return less than 3 ms indicates actiChamp PLUS. |
09:57:00 - 12:21:00 Design of Experiments |
12:21:00 - 13:18:00 PLP7j-gqTcYzcMXT3pgersYrmoFqIGIM8F |
13:18:00 - 15:50:00 Design of Experiments |
15:50:00 - 23:59:00 Latam Amerindian |