INNOVATIVE SMART ENGINEERING
The definitive results of successful innovative cost-effective smart engineering are :
- ability to produce good results without costing a lot of money ,
- focus on the best , most efficient , accurate and optimal schemes ,
- outcome helpful in cost-saving initiatives for industrial operations , and
- capacity to obtain the ultimate outcome in the increase of profits .
Highlights of the top-trending smart engineering innovations in the respective industrial sectors aimed towards further sustainable , society enhancement and business success worldwide include :
Iconic Smart Medical Health Engineering
The World Health Organisation ( WHO ) noted that every year around one million citizens worldwide are waiting for a kidney transplant . Although about 130,000 kidney organ transplants are successfully carried out every year , all the noble global medical efforts just meet 10 % of the annual demand for kidney transplants worldwide . Owing to the global organ shortage scenario , thousands of critically-ill patients around the world are left waiting indefinitely for compatible donors . Likewise , approximately 22.6 million patients worldwide annually require neurosurgical interventions to treat unfortunate damage to their peripheral nervous systems . Imagine the direct crystal-clear benefits from society-centred engineering research if , instead of waiting for an organ compatible match , the health centre can successfully use an engineering designed 3D-bioprinting technology to fabricate a new well-matched organ made from the patient ’ s own cells . Organ bioprinting , similar to classic 3D printing , uses ‘ bio-ink ’ which contains living stem cells instead of plastic or metal being the printing material . Though significant progress has been made in printing skin tissues and cartilage , the next phase for medical society-centred engineering research worldwide is in the successful printing of fully functional complex organs with integrated nerve cells , such as eyes , lungs , hearts and livers . The World Health Organisation reports that every year about 15 million people worldwide suffer from cardiac arrest / heart attack . The victims ’ odds of survival are presently set at a depressing rate of 8 %. The main reason for this sad statistic is the long response time of about an average of ten minutes for Emergency Response Teams to reach the respective victims , while brain death or fatalities occur within four to six minutes . Motivating engineering research into the development of efficient Emergency First Aid Drones can definitely save lives since these light-weight drones ( 4 kg ) with speeds of up to 100 km / h can easily manoeuvre over difficult terrains , overcome traffic jams and reach tight spots in crowded areas within a oneminute time frame from a distance of 3 km away within a 12 km 2 zone . Deployment of these lifesaving drones in strategic locations can give the unfortunate victim suffering from a heart attack an 80 % positive chance of survival . The Ambulance Drone is another novel technology to rapidly transport victims from difficult-toassess accident and disaster zones quickly to the medical centre for treatment . Millions of patients around the world and their families would be most grateful and relieved if these proposed toppriority community-centred medical engineering research projects achieve more health successes in the near future .
Drone / Unmanned Aerial Vehicle ( UAV ) Engineering
Some of the major benefits of using this engineering marvel for any industrial sector projects include more than 99 % results accuracy , 85 % faster time to complete task and five times cheaper for overall
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