Indigenous 3D bio-printer to print human tissue

InnoHEALTH magazine digital team — Fri, 06 Jan 2023 06:20:13 +0000

India Science Wire: Bio-printing is a method of tissue replication that temporarily or permanently supports and nurtures living cells. This technique is a potential alternative to organ transplantation, which could be useful in manufacturing functional human tissues such as skin by using specifically engineered biomaterials or bio-inks to print artificial living tissues.

An indigenous state-of-the-art 3D Bio-Printer ‘Mito Plus’ launched by Indian Tech Startup Avay Biosciences has been found to be helpful in printing human tissues. Mito Plus was launched at Bengaluru Tech Summit held between 16th and 18th November 2022. The prototype of Mito Plus was installed at the Indian Institute of Science (IISc), Bangalore, the top-ranked science research institute by NIRF Rankings.

Mito Plus is an advanced version of 3D bio-printer developed with inputs on the prototype from the research lab of Dr Bikramjit Basu at IISc, and developed by Avay which an IIT Madras alumnus co-founded. It is one of the advanced 3D bio-printers in India. Avay Biosciences provides wholly indigenous software and hardware development for end-to-end Bio 3D printing solutions in India.

Manish Amin, Chief Executive Officer, Avay Biosciences, said, “MITO plus is an advanced bio-printer at its price range which can be used to print a wide range of biomaterials. This printer comes up with an inbuilt UV curing option, HEPA filter and effective temperature control features. In this the print-head and the print-bed can be cooled up to four degrees celsius and heated to 80 degrees celsius. MITO plus can be used for pharmaceutical drug discovery and drug testing applications, it can also be used in cancer biology and cosmetology applications.”

Tissue printed by Mito Plus 3D Bio Printer

Mito Plus Bio-printer

Bio-printers work in almost the same way as other 3D printers do, with one major difference i.e instead of delivering materials such as plastic, metal or powders, bio-printers deposit layer of biomaterials, that may include living cells, to build complex structures like skin tissue, liver tissue, etc. 3D bio-printing is a unique gift to humanity through science and technology. However, many challenges are yet to be solved. ‘’There is still a long way to go before we can create fully functioning and viable organs for human transplant,” Amin explained.

“We are working on having our printers develop skin – the most common type of layered tissue that could help victims of severe burns. These tissues can also be used for toxicology screens and other testing mechanisms,” said Suhridh Sundaram, Chief Operating Officer, Avay Biosciences.

Typically bio-printing uses various polymers which attempt to recreate the extracellular matrix (ECM) native to the specific cell. The availability of cost-effective bio-printers is essential in developing artificial organs, since all future research depends on this infrastructure. If animal cells are used, bioprinting can also be utilized to create artificial meat, a space-age food dream.

Apart from premier Research and Development institutions such as IIT Madras and IISc Bangalore, the tech startup’s customers and collaborators include the Institute of Chemical Technology (ICT), Mumbai; National Institute of Pharmaceutical Education And Research (NIPER), Hyderabad; and BITS Pilani (Goa Campus). (Source: India Science Wire)

ISW/USM/Avay Biosciences/Bio-printing/ENG/18/11/2022

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We Could Probably Live Longer

InnoHEALTH Magazine — Wed, 06 Nov 2019 10:50:53 +0000

Jeanne Louise Calment, a French supercentenarian, is the oldest recorded person to live on earth. She died in 1997 at the age of 122. Imagine how cool would it be if we could live for like 200 or 300 years.

Derreck Rossi, Harvard University said, ìWe are programmed to dieî. As creepy as it sounds, it is true. We start the journey of our life as a single celled zygote, which further divides and forms embryo, divides more and then a foetus, and then more and goes on from the infant stage to puberty to adulthood and to old age. Human cells divide and divide the whole time and so do the other living cells but as the chromosomes keep dividing the whole time as well, we may loose some vital information. There are cap like structures on tips of the chromosomes called ìtelomeresî which are often compared to the tips of the shoe lace.Telomeres protect the chromosomes while deterioration or in other words, telomeres are a part of chromosomes which we can afford to loose.

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As the cells divide, the telomeres get shorter and shorter and further fail to cover the chromosomes and thatís when we start ageing and get diseases and organ damages. If we could somehow increase the length ofthe telomeres, we could probably live longer. Progeria is a deadly disease in which a child starts ageing really quickly and dies at an age of 13 or near. Till now, there is no known way to treat progeria. Progeria is like ageing. If we can find a way to increase the length of telomeres or live longer, we may be able to treat progeria as well.

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Dr. John P Cooke, Chair of the Department of Cardiovascular Sciences at the Houston Methodist Research Institute, Texas has been working on this with his team to somehow treat Progeria. A ribonucleic protein called Telomerase, or terminal transferase, canactually prevent the telomere to shorten and we can live longer. Telomerase maintains the health of the telomeres. But yes, a lot is still in the dark and still needs to be researched about. Telomere has single stranded TTAGGG sequencebundle on tips of the chromosomes and the telomerase enzyme can add more TTAGGG sequences to the tips of the telomeres ñ in which case we may live longer than we do. TERT is an active component of telomerase. If there was some way that we could activate the Telomerase enzyme in order for telomeres not to get any shorter, we could live longer and may also reverse ageing. But as everything has pros and cons, there are chances that these anti-ageing methods may lead to cancer in people.

About the author

Simran Sachdeva, a class 11 bright student, hails from Karnal, India. She has keen interest in analytical research in the field of healthcare. She won the prestigious Hindustan Times essay contest 2017-18 and was also the Chief Writer for the special edition of the Times Of India in 2018-19. Her areas of keen interest include Science, Research & Technology and wishes to be a scientist in future.

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Indigenous 3D bio-printer to print human tissue

We Could Probably Live Longer

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