Category Archives: Technology

Three Parent IVF / Three Parent Baby

three parents baby

Britain on 3 Feb 2014 became the first country in the world to allow ‘Three Parent – In Vitro Fertilisation (TP-IVF)’ or ‘Three Parent Babies’. This technique will help couples with mitochondrial diseases, an incurable conditions passed down the maternal line that affect around one in 6,500 children worldwide. But critics say the technique will lead to the creation of genetically modified ‘designer babies’.

The treatment is known as TP-IVF because the babies, born from genetically modified embryos, would have DNA from a mother, a father and from a female donor. Under current UK law, genetically altered embryos cannot be implanted into a woman. But in this case fertility clinics will be given license for TP-IVF.

What is the benefit of TP-IVF?

A small number of children each year are born with faults in their mitochondrial DNA which can cause diseases. Mitochondria are small structures present inside cells and provide energy. They have their own set of 37 genes which are separate from the 25,000 genes present in nucleus and does not affect human characteristics such as hair or eye colour, appearance or personality traits.

How do the faulty mitochondria affect people?

The parts of the body that need most energy are worst affected: the brain, muscles, heart and liver. Faulty mitochondria have also been linked to more common medical problems, including Parkinson’s, deafness, failing eyesight, epilepsy and diabetes. There are no cures for mitochondrial disorders.

How are mitochondrial disorders passed on?

Only mothers pass mitochandria on to their children. Because egg cells contribute nucleus as well as rest other cellular component including mitochondria whereas sperms contribute only nucleus during fertilization process.

How TP-IVF could prevent the mitochondrial diseases?

Scientists have developed two techniques to stop mitochondrial diseases being passed from mother to child.

The first is called mitochondrial spindle transfer (MST). In this, doctors use standard IVF procedures to collect eggs from the mother. They take the nucleus from one of the eggs and drop it into a healthy donor egg that has had its own nucleus removed. The reconstituted egg contains all the normal genes from the mother, but her faulty mitochondria are replaced by those from the healthy donor. The egg is then fertilised with the father’s sperm. The resulting embryo has the usual 23 pairs of chromosomes that hold the mother and father’s DNA, but the 37 mitochondrial genes, about 0.2% of the total, come from a third person, the donor.


The second procedure is called pronuclear transfer. It is similar to MST, but both the mother’s and donor’s eggs are fertilised first with the father’s sperm. Before the eggs divide into early stage embryos, the parents’ chromosomes are removed from the mother’s fertilised egg and placed into the donor egg, which has had its own chromosomes removed.

Is mitochondrial transfer safe and effective?

Both procedures have been tested in animals and resulted in healthy offspring. Good results have also been seen in human cells, but treated embryos have not been implanted into a woman to achieve a pregnancy. A review of work on mitochondrial transfer by independent scientific panel concluded there was no evidence the procedures were unsafe.

What objections do people have to the TP-IVF procedure?

Mitochondrial transfer passes on genetic changes from one generation to another. That raises ethical concerns because any unexpected problems caused by the procedure could affect people who are not yet born. Mitochondria are not completely understood, and the DNA they hold might affect people’s traits in unknown ways. The Catholic church opposes because a fertilised egg from the mother is destroyed in pronuclear transfer process and mitochondrial transfer dilutes parenthood.

Is ‘three-parent’ babies a good description of children born to the procedure?

Three-parent baby is misnomer. Women who donate their mitochondria would remain anonymous and have no legal rights over the child. On a genetic level the donor only contributes mDNA, less than 0.2% of the total genetic material.

Will this change in law allow ‘designer’ babies?

Designer baby is a concept of modifying human characteristics such as eye, skin and hair colour and other defining traits by altering nuclear DNA or gene. The procedure of TP-IVF does not change this nuclear DNA. The ban on altering nuclear DNA remains in place.

IAF gets Tejas-LCA


Defence Minister Manohar Parrikar handed over the indigenously built Light Combat Aircraft (LCA) Tejas to the Indian Air Force (IAF) in Bengaluru on 17th Jan 2015. The LCA has finally been handed over to the Air Force after Initial Operational Clearance-II, which signifies that the Tejas is airworthy in different conditions.


Tejas is a single-seat, single-engine, multi-role light fighter being jointly developed by the Defence Research and Development Organisation (DRDO) and Hindustan Aeronautics Limited (HAL) for India. It is a tailless, compound delta wing design powered by a single engine. It came from the LCA programme, which began in the 1983 to replace India’s ageing MiG-21 fighters. It is supersonic and highly manoeuvrable, and is the smallest and lightest in its class of contemporary combat aircraft. Features like latest electronic warfare suite (tested few weeks back), mid-air refuelling among others will be fielded in the FOC aircraft.


The Tejas was given Initial Operational Clearance-I in January 2011. It received the second of three levels of operational clearance on 20 December 2013. The Final Operational Clearance (FOC) is expected by the year-end and the first squadron of 20 aircraft is likely to be scheduled to enter service by 2017-2018. The entire project till induction is estimated at Rs. 30,000 crore.


LCA falls in the lower tier of the evolving conventional force structure of the IAF. At the upper end is the Su-30MKI, a heavy fighter. The middle rung will be formed by the Medium Multi-Role Combat Aircraft likely to be the Dassault Rafale which India is currently negotiating with France. Tejas will form the lower end of the strike package complimenting the heavy Sukhoi’s and the medium Rafale’s. It is ideal for point defence and strikes at low to medium ranges.


Analysts say that despite 65 percent indigenous content, the scrapping of the indigenous Kaveri engine development and the critical dependence on the US-made GE engines to power the plane is a matter of concern. Presently, the LCA-I is flying with an underpowered GE-404 engine. Air Force officials said the Air Force was banking on advanced LCA Mk-II and equipped with greater thrust generated by GE-414 engines. But this also means critical dependence of one of the mainstays of the future IAF on the US.

Maiden Test-flight of Panchi UAV


Panchi, the wheeled version of the unmanned aerial vehicle (UAV) Nishant, capable of taking off from and landing on small airstrips, had its maiden flight on December 24 from an airfield at Kolar in Karnataka. The flight lasted 25 minutes. The aim of the flight was to demonstrate that Panchi can take off and land on its wheels.


Panchi was designed and developed by the Aeronautical Development Establishment (ADE), a Defence Research and Development Organisation (DRDO) facility at Bengaluru. Since the Army wanted a wheeled version of Nishant, the ADE quickly developed it with modifications to the hardware and software.


Nishant, which has an underbelly airbag, is launched by a catapult i.e. Tatra-truck based Mobile Hydro-Pneumatic Launcher (MHPL) and can be recovered by a Parachute System, thus eliminating the need for a runway.

Panchi is capable of taking off from and landing on small airstrips. It has all the surveillance capabilities of Nishant, but it can stay in the air longer because it does not have to carry the airbag and the parachute systems. It is also a light vehicle with its body made of composite materials, and has a high degree of stealth because it has a low radar cross-section signature.

Nishant which had already been with the Army, was designed for battlefield surveillance and reconnaissance, tracking of targets and artillery fire correction. A sophisticated image processing system was used for analysing the images transmitted by it.


GSLV Mk-III X : First Experimental Flight Successful


The first experimental flight of India’s next generation launch vehicle GSLV Mk-III was successfully conducted on December 18, 2014 morning from Satish Dhawan Space Centre SHAR, Sriharikota. Also known as LVM3, this suborbital experimental mission was intended to test the vehicle performance during the critical atmospheric phase of its flight and this carried passive (non functional) cryogenic upper stage.


The mission began with the launch of GSLV Mk-III at 9:30 am IST as scheduled and about 5.4 minutes later, carried its payload – the 3.8 ton Crew Module Atmospheric Re-entry Experiment (CARE) – to the intended height of 126 km. Following this, CARE separated from the upper stage of GSLV Mk-III and re-entered the atmosphere and safely landed over Bay of Bengal with the help of its parachutes about 20 minutes 43 seconds after lift-off.

The total budget of the experimental mission was Rs 155 crore, including the crew module, which cost Rs 15 crore. A few years back Isro had carried out a similar experiment, Space-capsule Recovery Experiment (SRE), on a smaller scale by PSLV in which the module had orbited around the earth for 15 days before entering back.


With this successful GSLV Mk-III X / CARE mission, the vehicle has moved a step closer to its first developmental flight with the functional C25 cryogenic upper stage. It will be the ISRO’s most powerful rocket, capable of putting four-tonne communication satellites into orbit. This launch was also an early test of a crew module being developed for human space flight.


National Supercomputing Mission


India’s plans to be a world-class computing power are taking shape as the government lays out its strategy to build a vast supercomputing grid, comprised of 73 high-performance computing facilities. The project is expected to take seven years and comes with a price tag of Rs. 4,500-crore. It will have at least 3 petascale machines about 40-times faster than the country’s current record-holder.

India’s finance ministry panel authorized the National Supercomputing Mission, which is being jointly managed by the department of science and technology and the department of electronics and information technology. However, the project still has to clear the Indian cabinet before becoming official policy.


Professor Rajat Moona, director general of Centre for Development of Advanced Computing (C-DAC), described the mission as the first step to have a supercomputer machine in the top 20 list. According to Professor Moona, it will have transformative impact on research quality and quantity by facilitating the training of Indian scientists and the development of indigenous applications in medicine, agriculture and technology.

The seven-year mission will take place in two phases: the first three years will see the construction of 73 networked systems at research and education sites across the country. In the remaining four years, the focus will be on application development to make the most of this investment.


India has only 9 systems on the Top500 list ranking, India’s fastest ‘Prithvi’ (IBM made) is at 71 rank and India’s second fastest ‘ParamYuva-II’ (C-DAC made) is at 131 rank. In this computer age nation’s international importance is often measured on the number and the size of supercomputers it runs. China has 61 supercomputers in the Top 500 compared to a whopping 231 in the US.

World’s Top Ten Supercomputers


Every six months, the Top500 Organization ranks the five hundred fastest supercomputers in the world. And for the fourth consecutive list, China’s Tianhe-2 is on top, performing at 33.86 petaflop/s. That is nearly twice as fast as the number two computer, Cray’s Titan supercomputer.

The 44th Top 500 list of the world’s most powerful supercomputers, revealed during November’s International Supercomputing Conference (ISC) in New Orleans, contained only one new entry – a 3.57 petaflops Cray CS-Storm system installed at a secret US government facility.


India has only 9 systems on the Top500 list ranking, India’s fastest ‘Prithvi’ (IBM made) is at 71 rank and India’s second fastest ‘ParamYuva-II’ (C-DAC made) is at 131 rank. In this computer age nation’s international importance is often measured on the number and the size of supercomputers it runs.

China has 61 supercomputers in the Top 500, down from 76 since June’s list, compared to a whopping 231 in the US. However, the US has never had fewer in the Top 500 – a year ago it had 265.


1 – Tianhe-2 : Placed at China’s National University of Defence Technology in Guangzhou, Tianhe-2 is the world’s top system with a performance of 33.86 petaflops. It is named after the Milky Way.

2 – Titan : A Cray system at the US Department of the Oak Ridge National Observatory at Harvard, Massachusetts, it is a 17.5 petaflop system for a range of science projects.

3 – Sequoia : A former top-ranker, at the Lawrence Berkeley National Laboratory in California, concentrates on extending the life of ageing nuclear weapons and conducting experiments on nuclear fusion. This IBM Blue Gene machine can sustain 17.1 petaflops.

4 – K computer : Fujitsu’s K computer sits in Japan’s RIKEN Advanced Institute for Computational Science, where the machine uses its 10.5 petaflops to solve the energy, sustainability, healthcare, climate change, industrial and space related problems.

5 – Mira : Another IBM Blue Gene machine, the Mira supercomputer at Argonne National Laboratory, Illinois, is owned by the US Department of Energy (DOE). It’s of 8.58 petaflops.

6 – Piz Daint : It is housed at the Swiss National Supercomputing Centre, this Cray system uses its 6.27 petaflops primarily for climate and weather modelling, though also for astrophysics, materials science and life science.

7 – Stampede : This Dell-made 5.1 petaflops system at the Texas Advanced Computing Center, available for open research, with projects including drug molecule construction to weather forecasting to astrophysics.

8 – Juqueen : This IBM Blue Gene machine boasts 5 petaflops and does neuroscience, computational biology, climate research and quantum physics at the Forschungszentrum Juelich, Germany.

9 – Vulcan : Almost identical to the Juqueen, this IBM BlueGene system runs 4.29 petaflops at the Lawrence Livermore National Laboratory (LLNL) in California.

10 – *Top secret* : It’s a 3.57 petaflops system by Cray, this US government-owned supercomputer lacks the usual name, and its whereabouts isn’t publicly known.

Pinaka Mark -II Test Fired


An advanced version of the indigenously developed Pinaka Mark-II rocket was successfully test-fired on Tuesday, 9 Dec 2014 from a defence base in Odisha using a multi-barrel launcher. The advanced version Mark-II rocket with a range of more than 60-km and capable of acting as a force-multiplier, was developed to supplement artillery guns.


Pinaka is a multiple rocket launcher produced in India and developed by the Defence Research and Development Organisation (DRDO) for the Indian Army. The system has a maximum range of 40 km for Mark-I and 65 km for mark-II. With a battery of six launchers, the Pinaka system can fire a salvo of 12 rockets in 44 seconds and can neutralise a target area of 3.9 sq. km. The system’s capability for incorporating several types of warheads makes it deadly for the enemy as it can destroy solid structures and bunkers.

The quick reaction time and high rate of fire of the system would give the army an edge in low-intensity conflict situations. The system is mounted on a Tatra truck for mobility. Pinaka saw service during the Kargil War, where it was successful in neutralizing enemy positions on the mountain tops. It has since been inducted into the Indian Army in large numbers.

This unguided rocket system has undergone several tough tests since 1995. Eralier this year in May, 40 km-range Pinaka mark-I with rapid salvos successfully test-fired thrice from a multi-barrel launcher at an armament base near Balasore in Odisha. According to defence sources, some more rounds of test will be conducted in the next four days.

India Signs TMT Development Agreement


On 2nd Dec 2014, Science and Technology Department of India signed a multilateral agreement admitting India‘s participation in the development of the Thirty Metre Telescope (TMT) in Hawaii. India has agreed to spend Rs. 1299.8 crores over the next decade for this project. The telescope is expected to be completed by 2024.

Institutions from the United States of America, Canada, Japan and China are also participating in the construction of the world’s largest telescope on Mount Mauna Kea. This telescope, 4207 metres above sea level, may cost more than 1.47 billion US dollars.


TMT will contain 492 hexagonal mirror segments of 82 different kinds. These will behave like a single mirror with an aperture of 30 metre diameter. This large collecting area of 650 square metres is thrice as sensitive as the Hubble Space Telescope. India’s role will primarily be to create the control systems and software that keep the mirrors aligned and collects the data. These will be manufactured by General Optics (Asia) in Puducherry, Avasarala Technolgies and Godrej in Bengaluru respectively.

India will also manufacture 100 aspherical mirror segments in Hoskote, near Bengaluru. These thin glass slabs made in Japan have minimal expansion when heated. Indian scienticts will apply a protective layer and a reflective coating using technology from Caltech.


Through it scientists hope to find answers to fundamental questions about the universe. These include, how and when the first galaxies were formed, does life exist outside the Earth, the constitution of black holes and the nature of the universe’s acceleration.

Besides learning about the universe, India will gain the technology to manufacture fine aspherical mirror segments from the California Institute of Technology (Caltech). According to experts, this technology will form the basis of the next generation of spy satellites. They can resolve structures up to the size of man walking on the Earth.

GSAT-16 : Successfully Launched


India’s communication satellite, GSAT-16, was successfully launched on December 7, 2014 by the European launcher Ariane-5 of Arianespace from French Guiana. Ariane-5 placed GSAT-16 into the intended Geosynchronous Transfer Orbit (GTO), after a flight of about 32.5 minutes duration. It is the 18th satellite launched by Arianespace for Isro.

ISRO’s Master Control Facility (MCF) at Hassan in Karnataka started acquiring the signal from the satellite and the commanding of the satellite was initiated. The MCF monitors and handles all national communication satellites throughout their life and is about 200 km from Bengaluru.


GSAT-16 is configured to carry a total of 48 communication transponders, the largest number of transponders carried by a communication satellite developed by ISRO so far, 12 in the C band, 12 in the extended C and 24 in the Ku band – cover the entire country and the Andaman & Nicobar islands.


GSAT-16 will be the 11th among GSAT series of Indian communication satellites. The satellite will boost public and private TV and radio services, large-scale Internet and telephone operations. The satellite is aimed as a replacement for satellite INSAT-3E.


Currently ISRO have 188 transponders from the INSAT/GSAT fleet. India has leased an additional 95 transponders on foreign satellites mainly for the use of private television broadcasters. Inadequate satellite capacity has been a frequent complaint of private sector users – mainly broadcasters and VSAT operators.

Once GSAT-16 starts working, total number of ISRO’s transponders would increase to 236 and the issue of capacity crunch should somewhat ease. ISRO is confident that India will have about 400 transponders by 2017, despite the previous target of having 500 transponders by 2012 not having been met.

GSLV Mark III – Its First Experimental Flight


In the month of December 2014, the Geosynchronous Satellite Launch Vehicle (GSLV) Mark III is expected to lift off for the first time from Sriharikota on an experimental flight that will assess the rocket’s performance. It will be the ISRO’s most powerful rocket, capable of putting four-tonne communication satellites into orbit. The forthcoming launch will also provide an early test of a crew module being developed for human space flight.

During the 1990s, it became clear that a new launcher was needed to meet the country’s requirements for heavier communication satellites with large numbers of transponders. Rs. 2,498 crore project for developing the GSLV Mark III was approved by the Government in May 2002


The GSLV Mark III is a three stage launch vehicle. It has two huge solid propellants boosters as first stage, flanking a big liquid propellant core as second stage and a cryogenic upper stage. The GSLV Mark III has just four propulsion modules while its predecessor, the GSLV, has seven, which is crucial for increasing the rocket’s reliability and reducing launch costs.

While the solid booster and the liquid propellant core stage completed ground tests and were qualified for flight about three years back, development of the cryogenic engine for the Mark III’s upper stage is still in progress. For the experimental launch, the Mark III will be equipped with a dummy cryogenic engine and stage that will simulate the weight and other characteristics of the flight version.

The rocket will give the crew module a velocity of 5.3. km/second before it separates at a height of about 125 km. The capsule will then descend and splashdown in the Bay of Bengal, about 600 km from Port Blair in the Andaman Islands.

The GSLV Mark III is more sensitive than the Polar Satellite Launch Vehicle (PSLV) and the current GSLV to disturbances that might occur as it accelerates through the dense atmosphere. The ability of the rocket’s control systems to effectively handle such perturbations without violating the vehicle’s structural capabilities will be tested during the experimental flight.

According to ISRO, the first developmental flight of the GSLV Mark-III, with a functional cryogenic engine and stage, could take place in two years’ time.

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