Technology brings convenience and efficiency in our lives, so it should be made accessible to everyone at the most affordable cost possible. Let us take a look at the progress that has been made in developing the most affordable IoT sensors that there are.
The Internet of Things (IoT) is a network of physical objects called things, which include electronics hardware, software, sensors, power sources, and network connectivity that connects these objects to collect and exchange data. The IoT devices need to be self-supporting for their longevity, which is essential for them, but they also need to be low-cost.
The world as a whole is not a very rich place. According to the data from the World Bank Atlas, almost half of the world, or over three billion people, live on less than 2.5 dollars a day, while 80% of humanity lives on less than 10 dollars a day. It is important to keep their requirements in mind while developing new technology as they cannot afford iPhones and iPads. We need to develop technologies that are suitable for them as well and can improve their quality of life.
There is also a need for low-cost IoT platforms due to the issues that are being faced in the following sectors:
Security. For homeland security as well as cyber security.
Healthcare. For web-enabled healthcare initiatives, diagnostics, rural healthcare, etc. Clean water and sanitation issues need to be addressed as well.
Agriculture. 80% of the water gets used for agriculture, so saving water is very crucial. We only have 4% of the world’s water resources in India for 18% of the world’s population.
Pedagogy. India needs to create a million jobs per month to meet the demand and address their training needs, educational requirements, and skill development.
Environment. Sensor networks are needed to regularly monitor and transmit information related to the population, water quality, etc.
Low-cost cardiac diagnostic system
Back in 2004-05, we formed a multidisciplinary group and started to think about what could be improved and address the requirements at the same time. One of the first problems that we took on was a low-cost cardiac diagnostic system. Every third death in India is cardiac related. We strived to make the diagnosis simpler for everyone at the lowest possible cost.
There are multiple cardiac markers to open in CK MB myoglobin markers. We started working on some of these markers, because sometimes the cardiac muscles release some of these proteins into the blood when a patient starts to die. If troponin concentration is high, one needs to be admitted to a hospital immediately. With the help of some simple technologies these markers can be detected. But these markers need to be tested repetitively as it is not a one-time measurement need.
We wanted to build such a system, so we started working on iSens that could detect myocardial infarction. You just need to take the blood sample and filter it out. There are micro channels there along with the biosensor array for different cardiac markers and then there is a small tabletop system.
At the time of development, we realized that these are all disposable systems and silicon devices turned out to be quite expensive to be disposed of frequently. While all the associated electronics are made of silicon, but for the actual cartridge we started making use of polymer sensors. These are all piezo-resistive polymer cantilevers that can be implemented with low-cost techniques.
When an antibody gets coated on the cantilever and binds to the cardiac proteins, it causes a reaction and generates a stress, and that stress goes on to cause a strain. Any binding of the cardiac protein to the cantilever surface gives rise to an electrical signal, and that is how you know whether the cardiac markers are of a high or low category.