Typically the medical electronics industry is probably the fastest growing markets in the us. As the drive to reduce room and weight while incorporating functionality at a reduced cost carries on, flexible circuitry is quickly becoming an ideal interconnection and presentation design solution for this sector.

The adoption of adaptable Norton law circuitry in medical equipment goes back to the early 70's, when companies like Heart failure Pacemakers and Medtronic applied flex circuitry for implantable pacemakers and implantable defibrillators. As electronics and packing advanced, medical products have got enjoyed a tremendous growth throughout the US and overseas. This specific growth can be expected to continue since new and innovative goods, with increasingly demanding digital requirements, challenge product developers to get ten pounds in to a five pound bag. Implantable Medical Devices. These include pacemakers, defibrillators, neurological implants as well as cochlear implants (hearing). They are surgically implanted inside the human body. Product requirements are usually extreme reliability, long lasting, light-weight, and compact in size.

Non implantable Medical Devices. Hearing aids, medicine dispensing systems, and outside defibrillators (attached to patient) are some examples of this health-related application. These devices are usually put on or attached to the skin in the patient.

Monitoring Devices: Equipment include portable or wearable electronic devices that monitor heartbeat, blood pressure, body temperature, and blood sugar levels rate. Also included in this class are bedside monitoring units. Diagnostic Equipment: This category contains equipment that does ultrasound scanning, MRI's, CT scanning services, X-Ray's and a variety of other sorts of equipment that aid in discovering and diagnosing health problems. Surgical procedure Tools: These include electronic saws, screw drivers and cauterizing scissors for clamping and also closing blood vessels while carrying out surgery. Single Use Units (SUD's). Applications include ultrasonic scalpels, electrode recording catheters, biopsy instruments, electric biopsy forceps and hundreds of additional applications where sterile needs dictate one time use.

The range of uses and applications will be continually expanding with modern designs or redesigns regarding existing equipment. This makes the particular medical industry one of the most effective growing and existing sectors for flexible circuit purposes. There are a number of important causes that flexible circuitry is great for the medical industry:

Since the 1950's, flexible circuitry was used in the military along with avionics industry, with both programs requiring extraordinary reliability. Often the nearly 20 years of confirmed performance in these high demand software provided the medical marketplace with confidence in flex circuitry's reliability and robustness. Adaptable circuitry has inherent positive aspects because it eliminates connection items, thereby simplifying assembly in addition to eliminating chances of human problem or interconnect defects like poor solder joints.

The need in the medical industry for making devices smaller and brighter makes flexible circuits best in applications when excess weight and space are a large. Flexible circuitry is skinny (total circuit thickness may be Bio-compatibility: The materials found in flexible circuits have proven to be bio-compatible in a wide range of applications. Although implantable devices are totally sealed to eliminate contamination, non- implantable devices are used inside applications requiring contact with individual skin.