12-09-2024, 05:40 AM
This post was last modified 12-09-2024, 06:16 AM by Sirius. Edited 3 times in total.
Don't know where to place this. It's all very speculative around how UFO's could be messing with us 
So electrolytes are ions and can be messed with, the question for me is how long before side effects show. Imbalances in these can produce seizures that can explain some of the physiological effects people have during encounters. A little bit of this, a little bit of that, a bright flash of light or noise and BAM! you got yourself an embolized human
gpt disclaimer, use at own risk
Electrolytes Potentially Affected by Magnetic/Electric Fields
1. Sodium (Na⁺)
2. Potassium (K⁺)
3. Calcium (Ca²⁺)
4. Magnesium (Mg²⁺)
5. Chloride (Cl⁻)
6. Phosphate (PO₄³⁻)
Key Systems Affected by Magnetic/Electric Fields via ElectrolytesNervous System
Research Insights
So electrolytes are ions and can be messed with, the question for me is how long before side effects show. Imbalances in these can produce seizures that can explain some of the physiological effects people have during encounters. A little bit of this, a little bit of that, a bright flash of light or noise and BAM! you got yourself an embolized human
gpt disclaimer, use at own risk
Electrolytes Potentially Affected by Magnetic/Electric Fields
1. Sodium (Na⁺)
- Role:
- Crucial for generating action potentials (nerve impulses).
- Drives electrical activity in neurons and muscles.
- Crucial for generating action potentials (nerve impulses).
- Susceptibility:
- Sodium ions move across cell membranes during nerve signaling. Strong electric or magnetic fields might interfere with this movement, potentially disrupting nerve and muscle function.
- Magnetic fields could theoretically alter sodium ion channels, affecting the excitability of neurons and cardiac cells.
- Sodium ions move across cell membranes during nerve signaling. Strong electric or magnetic fields might interfere with this movement, potentially disrupting nerve and muscle function.
2. Potassium (K⁺)
- Role:
- Regulates repolarization of neurons after action potentials.
- Maintains the resting membrane potential of cells.
- Regulates repolarization of neurons after action potentials.
- Susceptibility:
- Potassium channels are highly voltage-sensitive, meaning they respond to changes in electric potential. Strong electric fields might interfere with their normal function.
- Disruptions could lead to irregular heart rhythms (arrhythmias) or altered neuronal firing patterns.
- Potassium channels are highly voltage-sensitive, meaning they respond to changes in electric potential. Strong electric fields might interfere with their normal function.
3. Calcium (Ca²⁺)
- Role:
- Acts as a signaling molecule for muscle contraction, neurotransmitter release, and numerous enzymatic processes.
- Calcium channels are tightly regulated by voltage changes and are integral to heart and nerve function.
- Acts as a signaling molecule for muscle contraction, neurotransmitter release, and numerous enzymatic processes.
- Susceptibility:
- Calcium ions and their channels are especially sensitive to electromagnetic fields (EMFs). Research has shown that certain EMFs can:
- Alter the opening and closing of calcium channels.
- Increase intracellular calcium levels, potentially triggering abnormal signaling.
- Alter the opening and closing of calcium channels.
- Excessive intracellular calcium due to EMF exposure could lead to muscle spasms, seizures, or overactive neural responses.
- Calcium ions and their channels are especially sensitive to electromagnetic fields (EMFs). Research has shown that certain EMFs can:
4. Magnesium (Mg²⁺)
- Role:
- A natural calcium blocker; regulates nerve and muscle excitability.
- Stabilizes cell membranes and reduces the likelihood of excessive electrical activity.
- A natural calcium blocker; regulates nerve and muscle excitability.
- Susceptibility:
- Magnesium's role in stabilizing ion channels may make it indirectly affected by EMFs that target calcium or sodium channels.
- Low magnesium levels could exacerbate the effects of electric or magnetic fields on other ions.
- Magnesium's role in stabilizing ion channels may make it indirectly affected by EMFs that target calcium or sodium channels.
5. Chloride (Cl⁻)
- Role:
- Balances positive ions (like sodium and potassium) in cells.
- Helps regulate the electrical potential across cell membranes.
- Balances positive ions (like sodium and potassium) in cells.
- Susceptibility:
- Chloride movement is essential for inhibitory signaling in the nervous system (via GABA receptors). EMFs could hypothetically alter these processes, leading to increased excitability or inhibition.
- Chloride movement is essential for inhibitory signaling in the nervous system (via GABA receptors). EMFs could hypothetically alter these processes, leading to increased excitability or inhibition.
6. Phosphate (PO₄³⁻)
- Role:
- Involved in energy storage (e.g., ATP) and cellular signaling.
- Plays a role in buffering pH levels in the body.
- Involved in energy storage (e.g., ATP) and cellular signaling.
- Susceptibility:
- Less directly affected by electric or magnetic fields compared to sodium, potassium, or calcium, but its involvement in ATP production and signaling pathways means indirect effects could occur.
- Less directly affected by electric or magnetic fields compared to sodium, potassium, or calcium, but its involvement in ATP production and signaling pathways means indirect effects could occur.
Key Systems Affected by Magnetic/Electric Fields via ElectrolytesNervous System
- Electric fields directly influence the movement of sodium, potassium, and calcium, disrupting action potentials and neurotransmission.
- Magnetoreception in Humans:
- While more studied in animals (e.g., birds), there is some evidence that humans may have magnetite (iron oxide) in their brain tissue, which could theoretically interact with magnetic fields.
- This interaction might affect neuronal activity or cause sensations like dizziness, confusion, or altered perception.
- While more studied in animals (e.g., birds), there is some evidence that humans may have magnetite (iron oxide) in their brain tissue, which could theoretically interact with magnetic fields.
- Cardiac cells rely heavily on sodium, potassium, and calcium for initiating and propagating electrical signals (heartbeat).
- Electric or magnetic interference could:
- Disrupt the cardiac conduction system.
- Lead to arrhythmias or other heart rhythm abnormalities.
- Disrupt the cardiac conduction system.
- Muscle contractions depend on calcium influx into cells. Magnetic or electric fields might enhance or suppress calcium signaling, causing cramps, spasms, or weakness.
- Electromagnetic fields can:
- Alter ion transport across membranes (e.g., via ion channels or pumps).
- Disrupt the balance of electrolytes, potentially causing cellular stress or dysfunction.
- Alter ion transport across membranes (e.g., via ion channels or pumps).
Research Insights
- Calcium Channels and EMFs:
- Studies have shown that voltage-gated calcium channels (VGCCs) are highly sensitive to EMFs. Activation of VGCCs by electric fields can lead to excessive calcium entry into cells, resulting in oxidative stress or abnormal signaling.
- Studies have shown that voltage-gated calcium channels (VGCCs) are highly sensitive to EMFs. Activation of VGCCs by electric fields can lead to excessive calcium entry into cells, resulting in oxidative stress or abnormal signaling.
- Low-Frequency Magnetic Fields:
- Fields at low frequencies (e.g., 50-60 Hz) are known to interact with charged particles like ions. These interactions might subtly influence electrolyte dynamics in biological systems.
- Fields at low frequencies (e.g., 50-60 Hz) are known to interact with charged particles like ions. These interactions might subtly influence electrolyte dynamics in biological systems.
- High-Intensity Fields:
- High-intensity fields (e.g., from industrial equipment) could have more pronounced effects on ion movement, potentially leading to noticeable physiological changes.
- High-intensity fields (e.g., from industrial equipment) could have more pronounced effects on ion movement, potentially leading to noticeable physiological changes.
compassion, even when hope is lost
