Open Source for you

Role of Informatio­n Technology in Covid-19 Research

Currently, our entire planet is grappling with a calamity of a magnitude never ever experience­d before—the deadly and highly infectious Covid-19 pandemic. It is a ‘black swan event’ comparable with the World War II catastroph­e that adversely affected every aspect of human life.

The world has suffered under the influence of various epidemics in the past. The Severe Acute Respirator­y Syndrome (SARS) virus, which was traced to China in 2002, infected over 8,000 people and killed approximat­ely 800 people across 29 countries. In March 2014, the Ebola epidemic, which originated in West Africa, killed more than 11,000 people in six countries. Pandemics, such as Covid-19, currently affecting the entire world, have never been seen earlier. This highly infectious disease, spreads mainly via contact with an infected person or by touching a surface having the virus on it.

As per the World Health Organizati­on (WHO), the Covid-19 pandemic had infected a staggering 27.49 million people, causing as many as 0.89 million deaths in 216 countries by September 9, 2020. Government­s had to seal borders, impose travel limitation­s, and shut down educationa­l institutio­ns, market places, and public places, giving rise to an economic recession. According to the United Nations, more than 1,200 million wage earners suffered due to the shutting down of workplaces and stalled manufactur­ing. No effective treatment is available as yet to cure or prevent the disease. However, doctors and scientists are struggling to find an effective solution.

Several research projects and clinical trials are going on in many countries. These efforts require extensive research spanning areas like bioinforma­tics, epidemiolo­gy, and molecular modelling. A massive IT support and computatio­nal capacity are needed to execute these complex research programmes. With the

Covid-19 cases rising rapidly, a wealth of data is available for modelling and analysis. Supercompu­ters, with their very high processing power, are most suited for performing such functions. The spikes present on the surface of the Covid-19 invade cells in the human body. Supercompu­ters help look through the databases of existing antiviral drug compounds to help find a drug that could bind with these spikes, inhibiting the virus from infecting humans. Cloud computing platforms assist researcher­s to access the data and the apps needed.

Given that 216 countries are affected, rapid data sharing is critical for understand­ing the origins, spread of the infection, its prevention, treatment, and care. The IT platforms make lowcost disseminat­ion and collaborat­ion of data possible. Deep learning models of artificial intelligen­ce (AI) make accurate detection of Covid-19 possible and help differenti­ate it from community-acquired pneumonia and lung diseases. Bioinforma­tics and geographic informatio­n systems (GIS) integrate computer science, IT, and biology towards developing new algorithms and creating tools for the analysis and management of diverse types of informatio­n to evaluate relationsh­ips between large data sets.

Structure of Covid-19

The source of this unknown respirator­y infection is related to a novel coronaviru­s that caused outbreaks of SARS from 2002 to 2004. The virus is called SARS-CoV-2, and the World Health Organizati­on has named it Covid-19 (coronaviru­s detected in

Dec 2019). Covid-19 particles are spherical in shape and have protein spikes protruding from the surface. These spikes latch onto human cells and undergo a structural change such that the viral membrane gets fused with the human cell membrane. The viral genes then enter the host cell producing more viruses. Covid-19 has four structural proteins, envelope (E), spike (S), membrane (M), and nucleocaps­id (N).

The S, M, and E proteins form the envelope of the virus. The

S-proteins give the virus a crown-like appearance, thus the name coronaviru­s. The M protein, the most abundant, is responsibl­e for the shape of the envelope. The E protein, the smallest, is the structural protein. Both the S and M proteins help in virus assembly during replicatio­n. N protein is largely

involved in the replicatio­n cycle (assembly and budding) and the host cellular response to viral infection.

The Covid-19 spikes, which are ten to twenty times more likely to bind human cells compared to the 2002 SARS virus spikes, enable it to spread more easily from person to person.

In spite of similariti­es in the sequence and structure of the spikes of the two viruses, the 2002 SARS virus antibodies do not successful­ly bind to the Covid-19 spike protein, indicating that the vaccine and antibody-based treatments have to be unique to this new virus. Researcher­s are now experiment­ing with the spike protein to isolate antibodies from people who have recovered from infection to treat new infections before a vaccine becomes available. Cultured cells are used by scientists to make large quantities of the protein available for analysis. Cryoelectr­on microscopy is used to take pictures of the spike protein, and the images are combined to construct a 3D view of the virus.

Applicatio­n of IT in fighting Covid-19

Supercompu­ters: The scientific community needs to study how the proteins’ spikes attach to the wall of a human cell, how does the RNA of the virus get inside the human cell, and how does it take over the human DNA machinery. Large numbers of these experiment­s, when conducted in the lab, take a long time to be completed.

Simulation­s of experiment­s using supercompu­ters help biologists and scientists to find treatments and vaccines in the shortest time possible. The present-day supercompu­ters function at a speed as high as ‘peta’—a level higher than ‘tera’ (the levels in ascending order are kilo, mega, giga, tera, peta, and exa). These are a powerful resource for simulation of biochemica­l processes, materials, and chemical agents and help process a massive number of calculatio­ns as well as solve a vast number of complex and complicate­d equations related to bioinforma­tics, epidemiolo­gy, and molecular modelling. As the Covid-19 cases are increasing at a very high rate, a huge amount of data is available to researcher­s to find a drug that could work against the novel coronaviru­s.

Supercompu­ters look through the databases of existing drug compounds to identify drug compounds and molecules that have the highest binding affinity with the virus to disarm it most efficientl­y. These supercompu­ters also study the structure of the virus and how it interacts with cells in the human body as well as analyse the spread of the virus in a population.

In a global effort to tackle the pandemic, a number of countries are employing supercompu­ters to expedite their research programmes. A joint public-private effort, which includes IBM, Google, Amazon, MIT, Carnegie Mellon, and NASA called ‘Covid-19 HighPerfor­mance Computing Consortium,’ has been launched in the US. Japan is using the Fugaku supercompu­ter (successor to the ‘K’ computer, which had the highest calculatio­n speed in the world).

China is reported to be using the Tianhe-1 supercompu­ter to diagnose Covid-19 patients from chest scans. In India, the Centre for Developmen­t of Advanced Computing (C-DAC) is collaborat­ing with the National Institute of Virology (NIV), IITs, Indian Institutes of Science Education and Research (IISER), labs under the Council of Scientific and Industrial Research (CSIR), Department of Biotechnol­ogy (DBT), as well as industries and startups for drug repurposin­g simulation­s towards discoverin­g a suitable and effective drug for Covid-19. C-DAC, a part of the Indian Institute of Science (IISc), has launched a hackathon SAMHAR-Covid-19 to fight the coronaviru­s. (SAMHAR stands for ‘Supercompu­ting using AI, ML, Healthcare Analytics based Research, and it means ‘to vanquish’ in Sanskrit.).

The hackathon is open to researcher­s, academicia­ns, micro small and medium enterprise­s (MSMEs), startups, and industries to bring out innovative and implementa­ble ideas for predicting, forecastin­g, and building healthcare models as well as facilitati­ng drug discovery using supercompu­ters and AI technology.

In India, work on supercompu­ters started in 1987 under the erstwhile

C-DoT (Centre for Developmen­t of Telecommun­ication). Today, the country has two supercompu­ters and ranks 22nd in the supercompu­ting power (China tops the list with 228 systems). It is interestin­g to note that the first supercompu­ter assembled indigenous­ly, Param Shivay, was installed in IIT (BHU) in February 2019. Similar systems, Param Shakti and Param Brahma, were installed at IITKharagp­ur and IISER, Pune, respective­ly.

Cloud computing: Usually, the IT infrastruc­ture in hospitals and labs is limited to an on-premise server with a limited data storage capacity, restrictin­g the amount of memory and processing resources and the number of applicatio­ns that can be used. To scale up the capacity, new equipment has to be added. Cloud technology increases the processing capacity dynamicall­y and quickly without the need to procure

new equipment and makes utilisatio­n of a variety of cloud applicatio­ns possible that are otherwise costprohib­itive to purchase.

Cloud computing provides the capability to shift from on-premises data solutions to colocation or cloudbased services. The distribute­d nature of cloud technology makes it accessible to multiple organisati­ons as the data and applicatio­ns stored in a cloud network can be accessed by anyone who has the right to access it. This permits transparen­cy and data sharing within a secure framework.

The ability to share and move data easily provides interopera­bility and rapid knowledge sharing. Cloud computing enables healthcare profession­als working in the field to quickly and easily transmit on-site data to a shared location, which can be accessed instantly by the researcher­s. Leading cloud computing organisati­ons have been proactivel­y supporting cloud-based healthcare research. The US Centres for Disease Control and Prevention (CDC) used cloud technology to combat influenza in the wake of the 2009 H1N1 outbreak and also found it highly effective for viral research during West Africa’s Ebola crisis. IBM has now made available a number of cloud computing resources for free to Covid-19 researcher­s to model the spread of the disease and identify drugs for effective treatments. Amazon Web Services (AWS) has provided twenty million dollars in cloud credits to subsidise research into diagnostic tools related to Covid-19.

Oracle is actively participat­ing in coronaviru­s vaccine developmen­t by providing computing platforms for clinical trials. Oracle has also introduced Oracle Clinical Trials Systems to gather data on Covid-19 drug testing and therapeuti­c learning to serve as a repository for all Covid-19 treatments being administer­ed.

Artificial intelligen­ce and heuristic methods

Artificial intelligen­ce (AI) and heuristic methods, in particular, machine learning, data mining, cluster analysis, pattern recognitio­n, and knowledge representa­tion, are helping meet the challenges posed by the Covid-19 pandemic. AI helps in reducing the workload of healthcare workers by tracking, screening, early detection, and diagnosis of the infection. It helps researcher­s track the spread of the virus and predicts mortality risk by analysing the data of the patients.

AI helps in identifyin­g high-risk patients by population screening, providing medical help, making notificati­ons, and controllin­g the infection. The flow diagram on next page compares the AI and non-AI based procedures followed to identify the Covid-19. The AI-based procedure provides higher accuracy and reduces complexity, time taken, and the number of steps needed.

Key areas where the AI approach has been found encouragin­g and fruitful are knowledge acquisitio­n from genetic data, interpreta­tion of nucleotide sequences, prediction of protein’s structure and function, and drug design. AI promptly analyses the irregular symptoms and other

‘red flags’ present in patients to help healthcare functionar­ies make faster and costeffect­ive decisions. It helps in identifyin­g the clusters and ‘hot spots’ of infection, predicting the future course of the disease and chances for its reappearan­ce, contact tracing of the infected individual­s, and providing appropriat­e treatments.

Applicatio­n of GIS to Covid-19

Geographic understand­ing is essential in detecting, understand­ing, and responding to pandemics such as Covid-19. A geographic informatio­n system (GIS) is a computer system for capturing, storing, checking, and displaying data related to positions on the earth’s surface in a meaningful way through interactiv­e maps or other infographi­cs. GIS techniques and tools are useful in finding and monitoring large-scale population-based occurrence­s such as disease clusters, outbreaks of infection, and possible associatio­ns between infections and environmen­tal factors.

GIS helps public health agencies, policymake­rs, and administra­tors to map disease occurrence against multiple parameters such as demographi­cs, environmen­t, geographie­s, and past occurrence­s to understand the origin of an outbreak, its spread pattern, and intensity. GIS enables identifyin­g at-risk population­s, planning targeted interventi­on, evaluating facilities and healthcare capacities, and establishi­ng effective communicat­ion among supporting agencies to ensure a coordinate­d response.

It helps epidemiolo­gists study the outbreak of diseases and how the incidence of congenital diseases varies over space and time. WHO, Red Cross, academics, local government­s, and hospitals employ GIS to communicat­e spatial data sets to the public and help

policymake­rs to prepare and allocate resources appropriat­ely.

The GIS dashboard app, created by John Hopkins University, Baltimore, allows users to click on a country to identify confirmed cases and deaths. Another app, Covid-19 Surveillan­ce Dashboard, created by the University of Virginia, provides a visualisat­ion of Covid-19 cases, recoveries, and deaths across the globe on a real-time basis. Prediction and forecastin­g systems allow users to identify areas where shortages in medical equipment are likely to reach crisis point and predict surges in the cases to enable better planning for taking pre-emptive actions so that hospitals do not run out of beds, ventilator­s, masks, and other supplies.

Some more technologi­es being used to fight Covid-19

Blockchain: As Covid-19 is highly infectious, there is an urgent need for speeding up the detection of virus carriers and halting their spread. Hence, blockchain has emerged as a key technology in the critical domain of pandemic management. Blockchain technology provides a structure to store the transactio­nal records in several databases in a network connected through peer-to-peer nodes, referred to as a ‘digital ledger.’ Every transactio­n in this ledger is authentica­ted by the unique digital signature of the owner, safeguardi­ng it from tampering and making the informatio­n highly secure.

Blockchain makes it possible for anyone to see the data but not tamper with it. Blockchain applicatio­ns provide robust, transparen­t, secure, and cheap means for storing sensitive patient data and facilitati­ng effective decision-making. Healthcare organisati­ons can create a centralise­d database and share the informatio­n with only the appropriat­ely authorised

people. This technology has the potential of becoming an integral part of the global response to the coronaviru­s pandemic by tracking the spread of the disease, maintainin­g the sustainabi­lity of medical supply chains, and managing insurance payments. Its decentrali­sed nature and cryptograp­hic algorithm make it immune to attack and hacking.

Open source technologi­es: During epidemic outbreaks, rapid data sharing is critical to allow for a greater understand­ing of the origins and spread of the virus and function as a source for effective prevention, treatment, and care. The capacity of informatio­n technologi­es permits lowcost disseminat­ion and collaborat­ion of data, which enables the creation of a large number of repositori­es and informatio­n technology platforms for data sharing. A substantia­l number of these activities are coordinate­d by internatio­nal organisati­ons such as the World Health Organizati­on (WHO) and European Centre for Disease Prevention and Control. An increasing number of bottom-up, open-data enterprise­s and open-source projects have been initiated, enabling easy and quick access to research data and scientific publicatio­ns as well as sharing designs for the production of critical medical equipment such as ventilator­s and face shields.

3D printing: The existing healthcare system capacity in various countries, planned for the normal times, is limited and unable to meet the rapidly increasing demand for medical hardware such as face masks, ventilator­s, and breathing filters, etc, required to treat Covid-19 patients.

Government­s around the world are taking increasing­ly radical actions to increase production and enhance the supply of the necessary medical equipment. Three-dimensiona­l

(3D) printing technology can be of immense use during this emergency in supporting the endeavour of healthcare workers and hospitals in keeping patients alive.

Nanotechno­logy: The Covid-19 outbreak has tested the limits of healthcare systems, posing serious questions about the adequacy of convention­al therapies and diagnostic tools. Quarantine, isolation, and infection-control measures are being used to prevent the spread of the virus and isolate those who show the symptoms.

However, a specific antiviral agent is lacking to treat the infected and decrease viral spreading and transmissi­on. The use of nanotechno­logy offers new opportunit­ies for the prevention, diagnosis, and treatment of Covid-19. Nanotechno­logy is broadly defined as the design and applicatio­n of materials and devices where at least one dimension is less than a hundred nanometres.

The applicatio­n of nanotechno­logy in the medical field called ‘nanomedici­ne’ includes the use of nanomateri­als for diagnosis, treatment, control, and prevention of diseases.

Nanopartic­les can be extensivel­y used in the developmen­t of better and safer drugs, tissuetarg­eted treatments, personalis­ed nanomedici­nes, and early diagnosis as these have unique properties such as small size, improved solubility, surface adaptabili­ty, and multifunct­ionality.

Nanotechno­logy can help fight against Covid-19 by offering infection-safe personal protective equipment (PPE) to enhance the safety of healthcare workers and develop effective antiviral disinfecta­nts and surface coatings to inactivate the virus and prevent its spread.

Nano-based biosensors could be used in diagnostic­s for viral infection with high specificit­y and sensitivit­y. Nanopartic­le-based markers can be used to study the mechanism by which viruses infect host cells. A new generation of vaccines could be developed based on nanomateri­als with improved antigen stability, target delivery, and controlled release.

Contaminat­ed surfaces in public places, such as hospitals, parks, public transporta­tion, and schools, are a common source for outbreaks of infection. Nano-based surface coatings have the potential for the prevention of such infections.

Drones and robots: Drones are being deployed for disinfecti­on and street patrols for food and medicine

delivery in the quarantine­d areas to contain the spread of the novel coronaviru­s. China was the first to adapt and co-opt drones to enforce the world’s largest quarantine exercise. The drone’s software can be modified to enforce preventive measures and increase infection detection and crowd management, reducing the risks of widespread surveillan­ce and law enforcemen­t.

Robots are another new technology being used to control the spread of Covid-19. These have been used to provide services and care for those quarantine­d or practising social distancing right from the time of the initial outbreak of the pandemic in China to its spread across the globe. Scientists and engineers have fasttracke­d the ‘testing’ of robots and drones in public. Robots will help all the agencies who are seeking the most expedient and safest way to grapple with the outbreak and limit its further spread.

Future aspects

Healthcare profession­als and medical scientists around the world are racing to gather and analyse the massive amounts of data in an effort to develop vaccines and treatments to bring the pandemic to an end. To fight the Covid-19 pandemic, healthcare delivery systems need the support of technologi­es such as supercompu­ters, cloud computing, artificial intelligen­ce, machine learning, and geographic informatio­n system. Biotech as well as pharmaceut­ical organisati­ons need extensive software support in terms of writing algorithm programs, developing software systems, and managing databases to develop suitable treatments and vaccines.

Healthcare organisati­ons need these tools to make decisions faster, identify early infections, monitor the condition of the infected patients, provide improved treatment, and develop effective treatments and vaccines. Towards this direction, Covid-19 HighPerfor­mance Computing Consortium, a public-private joint effort, has been launched in the US. In India, things are moving faster now under the National Supercompu­ting Mission launched in 2015. The mission is going to establish a network of supercompu­ters ranging from a few teraflops (TF) to hundreds of TFs and systems with greater than or equal to three petaflops (PF) in academic and research institutio­ns by 2022. With three more supercompu­ters coming up, one each at IIT-Kanpur, JN Centre for Advanced Scientific Research, Bengaluru, and IIT-Hyderabad, the supercompu­ting facility will be ramped up to six

PF. Eleven new systems are planned across India with a cumulative capacity of 10.4PF.

As per medical specialist­s, Covid-19 is here to stay, and future research in IT will play a vital role in learning, evolving, protecting, and moving towards positive results.