Discussion 1:

A defibrillator works by giving an electrical shock to the heart muscle. The point is to shock the heart into a fit to make it thump in a customary example of unwinding and contracting, which is the way the heart pumps blood through the body. I as of late perused that defibrillators don’t deal with a flat line except if the flat line is really a tiny heartbeat that the machine can’t get. The shock really stops the heart and gives it a “reset”. You wouldn’t shock a heart that was at that point halted. CPR is a superior technique to restarting a halted heart since it carries oxygen to the heart which can make it begin siphoning once more.

A few precautionary measures to take while directing is to ensure the patient is dry, that nobody is contacting the patient, and to eliminate overabundance chest hair to guarantee adequate skin contact is made. Another safety measure is to not involve the defibrillator in a climate that has combustible fumes present. The power from the defibrillator could ignite a fire.

One more illustration of a clinical gadget that is likewise an electrical gadget is a pacemaker. A pacemaker screens an individual’s heartbeat and manages it. Pacemakers have terminals that record the heartbeat.

Assuming the heartbeat becomes unpredictable, the pacemaker sends little electrical shocks to make the heartbeat normal. An EEG machine, or electroencephalogram, is a clinical trial that involves terminals joined to the head to screen electrical action in the mind. This test can analyze issues in the cerebrum like epilepsy or mind growths.

Dissussion 2:

Defibrillators work by delivering a controlled electric shock to the heart to restore its normal rhythm during cardiac arrest or life-threatening arrhythmias. The electric shock aids in resetting the heart’s electrical activity, allowing the natural pacemaker to restore a regular heartbeat.

To prevent unintended damage, the person giving therapy must take certain precautions, such as making sure the patient is unconscious and pulseless, making sure the device is charged and positioned correctly, and making sure no one is in close contact with the patient during the shock.

Other examples of medical devices that interact with the body using electrical currents include pacemakers, which regulate heart rhythm; transcutaneous electrical nerve stimulators (TENS), used for pain relief; cochlear implants, which help restore hearing; and deep brain stimulators, used to treat neurological conditions like Parkinson’s disease. These devices show how important bioelectricity is to modern medicine.

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