IIT Archives - InnoHEALTH magazine

S&T Minister launches AI-based water purification project

InnoHEALTH magazine digital team — Mon, 28 Feb 2022 10:15:20 +0000

Union Minister of State (Independent Charge) Science & Technology; Minister of State (Independent Charge) Earth Sciences; MoS PMO, Personnel, Public Grievances, Pensions, Atomic Energy and Space, Dr Jitendra Singh has launched a start-up of IIT alumni that uses Artificial Intelligence for water purification at an affordable cost. The Gurugram based company’s patented system, ‘Clairvoyant’ uses artificial intelligence to optimise purification systems and predict future breakdowns. This helped to remotely manage, update, and repair each system in real time. They have also developed clean drinking water solutions in the form of Water ATMs, which combine Internet of Things (IoT) technology with solar energy to provide clean drinking water. The water ATMs used solar energy to pump water from rivers, wells, ponds, or groundwater depending upon the location. The water is then treated with appropriate technology to make it potable. With this innovation, the cost of purified water is expected to be brought down to as low as 25 paise per litre. On the occasion, an MoU was also signed between Technology Development Board (TDB), a statutory body of Department of Science & Technology, Government of India and M/s Swajal Water Private Limited, the start-up company, which has been founded by ex-IITians.

Dr Jitendra Singh welcomed the financial support extended to Swajal by TDB and said that his Ministry is committed to reaching out to potential small and viable start-ups having skill and talent pool but lacking resources. He asked the CEO & Co-founder of Swajal, Dr Vibha Tripathi, to scale up this technology to help achieve India’s ambitious target of providing clean drinking water to all by 2024, as envisaged by Prime Minister Narendra Modi. The Minister said that apart from the Central Government’s initiatives like National Rural Drinking Water Programme (NRDWP) and Jal Jeevan Mission, the private sector should come forward in a big way with state-of-the-art tech solutions to cover nearly 14 Crore households where clean drinking water is yet to reach. Referring to Prime Minister’s 75th Independence Day speech, where he said that in just two years of the Jal Jeevan Mission, more than four and a half crore families have started getting water from taps, Dr Jitendra Singh said that the Ministry of Science and Technology is positively contributing to Prime Minister Narendra Modi’s Vision and Mission of “Har Ghar Nal Se Jal”.

Dr. Srivari Chandrashekhar, Secretary DST & Chairperson TDB, pointed out that this project is a combination of new emerging technologies IoT and AI, combined with renewable solar energy to cater to the need for pure drinking water in villages and remote areas. Shri Rajesh Kumar Pathak, Secretary, TDB, said that the project will empower communities to plan and monitor their drinking water needs with community ownership and will get affordable, accessible, reliable, and clean drinking water 24×7 throughout the year. TDB is committed to supporting such innovative technologies for mass utility. “With the financial support from Technology Development Board, a social impact start-up like Swajal could do wonders. We are looking forward to covering more states in India at the earliest,” said Dr VibhaTripathi, CEO & Co-founder, Swajal.

SOURCE: India Scienc

The post S&T Minister launches AI-based water purification project appeared first on InnoHEALTH magazine.

IIT Delhi Launches Grassroots Innovation Programme for Students

InnoHEALTH magazine digital team — Thu, 19 Aug 2021 10:00:03 +0000

New Delhi, June 30th (India Science Wire): The Principal Scientific Advisor (PSA) to the Government of India, Prof K. Vijay Raghavan launched ‘Grassroots Innovation Programme (GRIP)’ for students, an initiative by IIT Delhi under which the Institute students will work on finding novel solutions to grassroots societal problems identified by them from rural and semi-urban areas, including the communities they come from.

Lauding the initiative launched by IIT Delhi, Prof K. Vijay Raghavan expressed hope that GRIP will result in the development of several innovative solutions for society.

Activities proposed as a part of this new initiative includes Social Immersion, a programme in which group of students will visit communities located in smaller towns and villages to immerse in social environments for a substantial time (one week to months) to study, understand and identify local needs and challenges, which can be addressed by the students when they return to the Institute campus.

“The immersion programme provides an opportunity for students to put themselves in the shoes of end-users and to co-create solutions which are likely to succeed. This programme also acts as a pipeline of ideas, which students and student teams can address as a part of semester-long design and innovation courses already available to them,” said Prof. PVM Rao, Head, Department of Design, IIT Delhi who is coordinating the initiative.

Another component of the GRIP initiative includes Grassroots Innovation Programme in which students and student teams will be allowed to work on semester-long or year-long projects on finding novel solutions to grassroots problems identified by them.

The needs/problems on which students are expected to work can be from one of the two routes: Students or student teams have identified the problem/need and validated it as a part of prior social immersion programme. Secondly, IIT Delhi student(s) who come from diverse regions of the country, identify problems/challenges being faced in their local communities (in their villages, towns and semi-urban settings).

The GRIP initiative will provide physical, intellectual, and financial resources to the students to carry out these projects. To implement the above programmes, existing courses and schemes of the Institute will be leveraged. In this way students will have an opportunity to earn academic credits for their efforts. The programme can synergize with other programmes of the Institute, which include UBA, RUTAG, NSS, ENACTUS, etc.

“There are many students who have shown interest in addressing the unmet needs in their own neighbourhoods. Further, students are enthusiastic to participate in proposing and validating novel solutions that respond to the local situation and the interests and values of the communities involved. The GRIP initiative is aimed at providing resources to the students who want to help the society by solving its problems,” said Prof V. Ramgopal Rao, Director, IIT Delhi.

IIT Delhi and Honey Bee Network (HBN), a volunteer based network that seeks innovative ideas and traditional knowledge produced at the grassroots level by individuals and communities and disseminates them to the wider ecosystem, have joined hands to groom students as torchbearers of social and grassroots innovation through GRIP programme.

Prof. Anil K. Gupta, Coordinator of Honey Bee Network said, “For the GRIP initiative, the Honey Bee Network will act as one of the facilitators to connect IIT Delhi students and faculty with local communities and environments.”

He further said that the social immersion and shodh-yatras will give an opportunity for students to learn from grassroots innovators and also to add value to their efforts. Students who do immersion in earlier years will have additional opportunity to address some of the needs identified by them as their course projects. (India Science Wire) ISW/USM/IITD/ENG/30/06/2021

The post IIT Delhi Launches Grassroots Innovation Programme for Students appeared first on InnoHEALTH magazine.

Epilepsy is the Fourth Most Common Neurological Disorder

InnoHEALTH Magazine — Wed, 23 Oct 2019 11:04:03 +0000

Artificial Intelligence can help decode epileptic brains. Epilepsy is the fourth most common neurological disorder affecting nearly 65 million people worldwide. The seizures or ‘fits’ as is commonly known, arise due to unusual electrical activity in the brain and is the chief symptom of epilepsy. Neither dependent on age or gender, the onset of the seizure is unpredictable without a set pattern of frequency of occurrence or severity, often posing a challenge to the caregiver.

Did you know that one student commits suicide every hour in India?

Although epilepsy can be related to previous brain injuries or genetic factors, neurologists have found unprovoked, recurrent seizures in healthy individuals too. How and why these seizures occur remains a mystery. However, research has found that the source of seizures is within the brain. In other words, the brain itself is the generator of epilepsy.

Spatial maps of top 10 networks: If the origin is within the brain, then are there any fingerprints that can be detected? Does the brain often tell-tale signs which can be mapped to predict the tendency of epilepsy?

Reason for Aggression After Drink

Seeking answers to these questions, a team of interdisciplinary researchers conducted a study to peep inside epileptic brains. The results indicate that there exist independent neural networks that can carry disease sensitive information about the anomaly. With the help of machine learning models and artificial intelligence, researchers were able to detect and reveal the hidden patterns.

“Epilepsy is not a disorder but the manifesting of something from within the brain’s electrical activity. Interestingly, each one of us has the neural map of epilepsy within our brain. It is only when the network gets fired and manifests externally, in a recurrent manner, it becomes disorder or epilepsy,” explained Dr. Tapan Kumar Gandhi, lead researcher of the study from Indian Institute of TechnologyDelhi, while speaking to India Science Wire.

The usual diagnosing tool for epilepsy is by EEG (Electroencephalography) readings of epileptic patterns and visible symptoms like convulsions, loss of consciousness or sensory disturbances.

Existing studies reveal specific patterns that represent synchronous activities of sensory, auditory, cognitive and other functions. These activities are indicated by the change in blood flow to the brain and seen as BOLD signals or changes in the Blood-Oxygen-Level-Dependent output.

Recent developments in Magnetic Resonance Imaging or MRI help picture these activities in the brain and detect the cause of seizures such as a lesion or scar. However, MRI is not very useful when a seizure flares up. Whereas, functional MRI — another scanning method — can record regional interactions in the brain when a particular task is being performed.

In 1995, Indian researchers had found that the brain shows prominent neural network connections even in its resting state. Termed as resting-state functional MRI or rsfMRI, the images from this scanning indicate neural patterns in an individual’s brain even when no action is performed.

In the present study, the team utilized rsfMRI technique and performed brain scans on individuals with Temporal Lobe Epilepsy (TLE), which is the most common form of epilepsy.

Dr. Gandhi said, “We hypothesized that there could be ‘disease-specific networks’ in epilepsy prone brain that can be identified with the help of the machine learning model.” Machine learning involves artificial intelligence to read live data instead of pre-programmed information. Such a building block of a machine is analogous to a neuron cell in the brain.

Researchers used a tool called Support Vector Machine (SVM) to deal with the complex and non-linear data obtained from the scans. By using another algorithm called Elastic-net based ranking, the relevant features of the neuroimaging data were extracted. The signals were integrated to reveal the patterns.

The team conducted a pilot study on 132 subjects – 42 with epilepsy, and the rest with healthy individuals. Parameters like age, gender, history of epilepsy, genetic predisposition, incidents of injuries, medications and more, were taken into account. The epilepsy patients underwent three rsfMRI while those in the healthy group were scanned once.

In all, 88 independent components or networks were obtained from the whole brain imaging data and fed as input to the SVM. From the patterns, top 10 strong networks were correlated with clinical features using another standard method called Pearson’s Correlation to generate the rsfMRI epileptic neural networks.

From the pattern inputs, the SVM could identify epileptic individuals to an accuracy of 97.5% and specific lobes in the brain responsible for the condition. The model also revealed correlations such as the age of onset, frequency of seizures, or duration of illness.

By this, researchers concluded that the independently derived rsfMRI contains epilepsy-related networks. ‘Our research establishes that with the help of machine learning methods, we can identify these networks, as we had hypothesized. Increased strength in these networks indicates the possibility of a progressing Temporal Lobe Epilepsy’, explained Dr.Gandhi.

The team included Rose Dawn Bharath, Sujas Bharadwaj, Sanjib Sinha, Kenchaiah Raghavendra, Ravindranadh C. Mundlamuri, Arivazhagan Arimappamagan, Malla Bhaskara Rao, Jamuna Rajeshwaran, Kandavel Thennarasu and Parthasarathy Satishchandra (National Institute of Mental Health and Neurosciences, Bengaluru); Tapan K. Gandhi and Jeetu Raj (IIT, Delhi); Rajanikant Panda (Universitè de Liège, Belgium); Ganne Chaitanya (Thomas Jefferson University, USA) and Kaushik K. Majumdar (Indian Statistical Institute, Bengaluru). The study results have been published in the journal European Radiology.

Credits: India Science Wire

The post Epilepsy is the Fourth Most Common Neurological Disorder appeared first on InnoHEALTH magazine.

Integrating Technologies to Better Healthcare

InnoHEALTH Magazine — Wed, 17 Apr 2019 09:57:49 +0000

Age and disease demographics are changing rapidly across the globe. The number of people above 65 years is expected to double and constitute nearly 17% of the world population by 2050. The chronic disease incidence rate is expected to rise to 57% by 2020. These figures highlight the need to enhance the quality and efficiency of care with quick response time to health-related emergencies.

Ideas that cut across medicine, biological and engineering sciences, material design, and system innovations are converging to address these challenges. The shift is going to be from legacy products like pacemaker and imaging systems to wearables for general fitness tracking and gait monitoring. Taking a step further, researchers are now developing and testing more focused miniaturized bioelectronic devices for recording and analyzing health data for detecting determinants of health and for medical interventions.

In diagnostics, non-invasive bioelectronic skin sensors that measure analytes in biofluids like saliva, tears, and sweat are showing promising results in assessing stress levels and detecting conditions like diabetes and cystic fibrosis. Researchers from the All India Institute of Medical Sciences (AIIMS) and Indian Institute of Technology (IIT) Delhi have developed a biosensor for detecting glucose in saliva samples for diabetes detection. The results can directly be viewed on the user’s smartphone. Many such studies are now underway in India.

Also Read: Healthy Lives: Everyone, Everywhere

Conductive gels and patch sensors resembling fashion accessories are also being developed to record cardiac, brain and muscle activity which could complement the traditional blood analysis and clinical examinations. Mechano-acoustic skin sensors that measure speech patterns and internal body sounds, like swallowing, are being explored to quantitatively measure the impact of rehabilitation in patients, such as those recovering from a stroke.

In treatment, miniscule implants placed inside the body can cross the blood-brain barrier and deliver the drug directly at the target site, even in hard-to-reach internal organs. Such devices have shown promising results in laboratory settings in reducing side effects and toxicity while increasing overall drug efficacy. This could also ensure patient compliance, a step further to the recently approved digital pill, especially in patients on long care and those with compromised cognition.

Certain implants can also electrically stimulate cardiac or brain tissues to treat conditions like irregular heartbeat, certain motor disorders, and cognitive impairments. Other implants like artificial retina and cochlear implants, restore functionalities of damaged tissues. These interventions, being referred to as ‘Bioceuticals’, could restructure conventional therapeutic options for more efficient outcomes.

In India, a lot of work has now started in this sphere. Results from a few studies have started trickling in, with most of them in development or early stages of testing. Research findings in the journal Scientific Reports by researchers from IIT Kharagpur earlier this year reported bio impedimetric analysis of cancer cells that efficiently distinguishes their aggressiveness by measuring electric field impedance in laboratory conditions. In another study published in the journal Sensors earlier this year, researchers at IIT Delhi developed a novel low-cost prosthesis based on sensors to enable normal gait kinematics, i.e. motion analysis, for lower limb amputees.

IIT Kharagpur is setting up a Bioelectronics Innovation Laboratory that aims to develop battery-free implantable miniaturized engineering systems for treatment of brain, nerve, muscle or spinal cord disorders by restoring missing neural functions. The proposed coin-sized implant will be powered wirelessly and will combine brain activity testing like electrical simulation, bio-potential recording and neuro-chemical sensing for use in rehabilitation and prosthesis.

Also Read: India’s First Smartphone Insertable Cardiac Monitor

Round-the-clock data collected from bioelectronic devices could replace the present time-point investigations and lead to better management of the health condition of patients. In addition, data from multiple people can help develop artificial intelligence algorithms and predictive tools. Such tools have already started showing analytic performance similar, and sometimes better than manual inspection by a specialist physician. In countries like India, that suffer from a shortage of qualified doctors in remote areas, such devices have immense potential. However, data standardization, data security, and privacy protection must be addressed and regulated before rolling out such interventions.

In the next few years, health monitoring, neural prosthetics, and biochemical prosthetics are expected to drive major developments in this space. Although the monitoring devices have already started testing the market in niche patient segments, it may take the implants another 5-10 years to reach health centers as they make their way through developmental and regulatory checkpoints.

The post Integrating Technologies to Better Healthcare appeared first on InnoHEALTH magazine.

Smartcity development are heat islands

InnoHEALTH Magazine — Fri, 23 Mar 2018 06:02:34 +0000

The phenomenon of urban heat islands, in which concrete and built areas experience higher temperatures than surrounding rural areas, may get accentuated with rapid urbanization. This is the conclusion of a new study of urban areas selected for development of smart cities. The study, which covered 89 of 100 areas selected for development of smart cities, has found that agriculture and irrigation are two dominant drivers of urban heat islands or UHI in India. In addition, significant presence of atmospheric aerosols – mainly pollutants – over urban areas can influence UHI.

Moisture from irrigation canals and agriculture fields play a key role in keeping rural areas surrounding cities much cooler that urban areas, resulting cities becoming heat islands. In a heat island, temperature could be 1 to 6 degrees higher than surrounding areas. Remote sensing data and climate modelling were used to evaluate UHI across the country.

When the surrounding of non-urban areas have no agriculture during summer, cities are relatively cooler during daytime. However, if the non-urban areas are under irrigated agriculture, cities are warmer than surroundings. This means UHI effect during day time is mainly driven by agriculture and irrigation. However, in the night-time, cities are significantly warmer than surroundings in both winter and summer seasons. Night time urban heat is mainly driven by the amount of heat stored in buildings and other impervious surfaces.

Urban areas located in highly irrigated regions – Indo-Gangetic Plain and north-west India (Haryana and Punjab) – show UHI intensity of 3 to 5 degrees. During summer season (April and May), when air temperature is at the peak, land surface temperature becomes is higher than that of the post monsoon season in absence of agricultural operations. Moreover, amount of moisture and vegetation in non-urban areas are also limited as crops are largely harvested by the end of March and soil moisture is depleted due to high atmospheric water demands, the study said.

“While urban areas have experienced increased number of heat waves and temperature extremes in recent past, urban heat island effect driven by rapid urbanization can further worsen extreme hot conditions in cities,” pointed out Dr Vimal Mishra, a scientist at the Water and Climate Lab of Indian Institute of Technology, Gandhinagar, which did the study. The results of the study appeared in journal Scientific Reports on Wednesday.

The development of smart cities will result in rapid growth in urban infrastructure and population, leading to increases in UHI intensity. “Our results can provide policy insights for development of smart cities,” Dr Mishra said. “Considering night-time heating which could be significant during heat waves, measures such as passive cooling should be used. Building materials that absorb less heat and are sustainable can reduce the amount of heating caused by stored heat.” The presence of water bodies and vegetation in cities can also help reduce additional nighttime heating in urban heat islands.

The study team included Rahul Kumar and Vimmal Mishra (IIT Gandhinagar); Jonathan Buzan and Matthew Huber (Purdue University, USA); Rohini Kumar (UFZ-Helmholtz Centre for Environmental Research, Leipzig, Germany); and Drew Shindel (Duke University, USA).

(Article shared from India Science Wire)

Want to write for InnoHEALTH? send us your article at magazine@innovatiocuris.com

Read all the issues of InnoHEALTH magazine:
InnoHEALTH Volume 1 Issue 1 (July to September 2016) – https://goo.gl/iWAwN2
InnoHEALTH Volume 1 Issue 2 (October to December 2016) – https://goo.gl/4GGMJz
InnoHEALTH Volume 2 Issue 1 (January to March 2017) – https://goo.gl/DEyKnw
InnoHEALTH Volume 2 Issue 2 (April to June 2017) – https://goo.gl/Nv3eev
InnoHEALTH Volume 2 Issue 3 (July to September 2017) – https://goo.gl/MCVjd6
InnoHEALTH Volume 2 Issue 4 (October to December 2017) – http://amzn.to/2B2UMLw
InnoHEALTH Volume 3 Issue 1 (January to March 2018) – https://goo.gl/fksdQx

Connect with InnovatioCuris on:
Facebook: https://www.facebook.com/innovatiocuris
Twitter: https://twitter.com/innovatiocuris
LinkedIn: https://www.linkedin.com/groups/7043791
Stay updated about IC, visit: www.innovatiocuris.com

The post Smartcity development are heat islands appeared first on InnoHEALTH magazine.