BIOMEDICAL ENGINEERs – Warriors of all time

In COVID-19 crisis, the real warriors were the Biomedical Engineers. They played an important role in medical technology in patient care. They involved themselves in making ventilators and PPE (personal protection equipment) kits to help the COVID patients. Biomedical engineers focus on inventing new devices and develop modern technologies which help in improving human health care system. With the help of the doctors and researchers, Biomedical Engineers are developing equipments to solve clinical problems. 

Electing biomedical engineering as métier is extremely rewarding. Biomedical Engineers has the ability to save lives through innovation and modern technology. That’s why experts from Human Resource Department’s planning team suggest that every doctor along with medical studies should be accustomed with biomedical engineering studies. 

Biomedical engineering, also known as medical engineering, is a form of engineering associated with the study in the fields of biology and health care system.  

The following qualities are required for Biomedical Engineers: 

  • Analytical skills 
  • Communication skills  
  • Listening skills 
  • Math skills 

Apart from these skills, they should have idea of all disciplines ranging from material science to electronics, life science to biomechanics and mathematics to computation. Because of these, Biomedical Engineering is completely interdisciplinary in nature and the Biomedical Engineers possess vast knowledge across of all domains.  

How is Biotechnology impacting millions of lives?

Are you an avid lover of biology? Are you naturally inclined to apply the principles of biology to create an impact on people’s lives? Well, then the Biotechnology sector is where you may find your dream job.

With the world still reeking of over 520 million deaths due to the COVID-19 pandemic, it is undeniable that the figure could have been in billions or even more had it not been for the Biotechnology sector. Almost everything starting from the diagnosis and immediate treatment to the development of vaccines brought to light the promise that Biotechnology holds as a leading technology in the modern world. To know more about the potential of Biotechnology and the facets of human lives that it is able to impact upon, read further down.

What is Biotechnology?

Biotechnology is an industrial sector that deals with the manipulation of living organisms to create commercial products. For instance, the wealth of knowledge accumulated by cell biologists, botanists, zoologists, molecular biologists, and geneticists have been implemented by genetic engineers to manipulate information carried by the DNA in order to create transgenic animals and plants of commercial importance. Quite undoubtedly, the deepest penetrations of the biotechnology sector has been in the healthcare and agricultural markets. However, there are several other important areas where Biotechnology is making inroads with sustainable solutions. This blog highlights some fields wherein Biotechnological interventions are working wonders.

Vaccine development

Within a few months of the detection of coronavirus, scientists mapped the entire genome of the virus and it helped to understand how the virus operates. Genome mapping being an important technique in Biotechnology, the Biotechnology sector can boast of its towering presence in global markets across the map. Also, the highly effective mRNA-based vaccine for COVID-19 was first tested in cells inside the laboratory which entails practising some basic techniques of Biotechnology. Weighing the outcomes, government organizations and pharmaceutical giants have entered into strong public-private partnerships to pool resources and fund research in the domain of vaccine development.

Next-generation computing-aided drug discovery

Advanced computing technology such as artificial intelligence and machine learning have enabled Biotech companies to automate their processes and scale up operations. This handholding of technologies have enabled to reduce the cost and time required to take new drugs from bench to bedside. The ability to analyze large data sets helps medicine manufacturers to identify treatments based on the root cause of a disease. This holds immense potential to reduce the usual 90 percent failure rate for developing new drugs.  Data mining from current clinical trials can also help to predict the effectiveness of treatments down to a molecular level and even predict new or different uses for an existing drug thereby reducing cost and effort of establishing new drugs.

Genome editing

Techniques for manipulating the information present in the DNA, known as gene editing in technical jargon, has come a long way since they were first used to make edits such as addition, deletion, silencing, or replacement of a specific gene. Precise gene editing has been made possible by the advancement of technologies such as the revolutionary CRISPR-Cas9 systems. Engineered nucleases called CRISPRs acting as molecular scissors have unfurled a plethora of applications in gene therapy for the treatment of many conditions including rare genetic disorders and even fatal cancers. Furthermore, gene editing has also allowed the development of improved transgenic plants and animals capable of synthesizing a variety of medically important recombinant human proteins such as Insulin.

Precision medicine

Sequencing the entire human genome, an initiative known as the Human Genome Project, began in 1990 and was completed by 2003. This was another hallmarking achievement of Biotechnology that now allows extensive screening of patients and targeting of interventions. Improvisation of sequencing technologies have reduced the cost of genetic sequencing drastically ever since thereby making personalized gene sequencing affordable. This, in turn, has enabled the development of personalized treatment plans and targeted therapies, which are more effective than less-specific therapies because they focus on a patient’s genetic constitution. Furthermore, the falling cost of sequencing technologies has fostered the development of rapid and inexpensive methods to detect pathogens from clinical samples as well as soil samples.

Boosting agricultural yields

The global population is set to increase by 25% from 7.9 billion in 2022 to 9.7 billion in 2050. The basic need for a growing population is food, and hence its demand for feeding both people and livestock is about to increase proportionately. This automatically necessitates the use of increasing hectares of land for farming while practically cultivable land will keep on reducing as the expanding population of humans keep encroaching onto such lands. Biotechnology offers a solution to this alarming problem through the approach of gene editing. For example, crops such as wheat or corn may be engineered through the transgenic technology to grow in harsher conditions or produce more grain in a smaller area than other crop varieties while providing the same nutritional value. From another perspective, the development of biopesticides can enable protection of crops without the use of harmful chemicals thereby averting environmental damage. 

Bioprinting and tissue engineering

Another promising futuristic application of Biotechnology in the medical field is 3D bioprinting, wherein bioprinters are used to develop cell-based scaffolds using a ‘bio-ink’ comprising cells and biomaterials. This empowers one to develop skin, bone, and vascular grafts from the patient’s own cells for personalized medicine. The bioprinting technology has added a major thrust to the field of tissue engineering and regenerative medicine by enabling the creation of autologous tissue grafts for wound healing and organ transplantation.

Conclusion

These trends clearly show that the demand for biotechnology is on the rise. The fact that this particular sector is being able to solve real-life problems related to human health and nutrition has catapulted it to fame. It is also quite evident that biotechnologists need more than just a background in biology, chemistry, or pharmaceutical science to build their careers upon. With innovative solutions rooted to the genetic level, biotechnology is here to stay and offer myriad career opportunities to the brightest minds!

Biomass based biofuel generation future in India

Out of some of the hottest trends that have been on the top lists for quite a while are choosing an entrepreneur as the primary occupation and doing an eco-friendly business.

The need of renewable energy is increasing in the world due to rapidly growing human population, urbanization and huge consumption of fossil fuels. Fossil fuel reserve is very limited, and the reserve is getting depleted day by day. The primary sources of energy that can be used as the alternative of fossil fuels are wind, water, solar and biomass-based energy.

Currently biomass as a feedstock for biofuel production is gaining importance. Biomass energy is supplying about 10-15% of total energy demand of the present world. Biomass feedstocks include organic material such as wood, wood-based energy crops, grass, lignucellulosic materials like wheat straw, rice straw, sugarcane baggase, corn, microalgae, agricultural residues, municipal wastes, forest product wastes, paper, cardboard and food waste. Biomass can be converted into biofuels by thermochemical and biochemical conversion. Based on the types of feedstocks or biomass the biofuels derived are divided into different groups i.e. 1st generation, 2nd generation, 3rd generation. 1st generation biofuels mainly extracted from the food crop-based feedstocks like wheat, barley, sugar and used for biodiesel and by fermentation to produce bioethanol. But first-generation biofuels face the “fuel vs food” debate and also the net energy gain is negative.  1st generation biofuels production systems also have some economic and environmental limitations. To overcome the drawbacks of 1st generation biofuels 2nd generation biofuels have been generated from the non-food crops-based feedstocks like organic wastes, lignocellulosic biomass etc. For biofuel production from these sources rigorous pretreatments are required to make the feedstocks suitable for biodiesel production. This is the major drawback of 2nd generation biofuel production. Then the attention of the world has been shifted towards 3rd generation biofuel production entails “algae-to biofuels”. Microalgae is easy to cultivate, has higher photosynthetic rate and growth rate than other plants and there is no food vs. feed dilemma present of using microalgae as feedstock for biofuel production. Presently the attention is also given towards fourth generation biofuel. The former concept of third generation of biofuel deals with the conversion process itself from the microalgae to biofuel. The fourth generation of biofuel concept deals with development of microalgal biotechnology via metabolic engineering to maximize biofuel yield. Fourth generation biofuel uses genetically modified (GM) algae to enhance biofuel production. In comparison with third generation in which the principal focus is in fact processing an algae biomass to produce biofuel, the main superior properties of the fourth are introducing modified photosynthetic microorganisms which in turn are the consequence of directed metabolic engineering, through which it is possible to continuously produce biofuel in various types of special bioreactors, such as photobioreactors.

Biomass has the highest potential for small scale business development and mass employment. Characterized by low-cost technologies and freely available raw materials, it is still one of the leading sources of primary energy for most countries. With better technology transfer and adaptation to local needs, biomass is not only environmentally benign, but also an economically sound choice. Bio-based energy can be expected to grow at a faster pace in the years to come. 

On the Biomass Energy sector, the India government committed to increasing the share of non-fossils fuel in total capacity to 40% by 2030. India produces about 450-500 million tonnes of biomass per year. Biomass provides 32% of all the primary energy use in the country at present. A total capacity of 10145 MW has been installed in the Biomass Power and Cogeneration Sector. The Installed Capacity of Biomass IPP is 1826 MW together with the Installed Capacity of Bagasse Cogeneration is 7547 MW and the Installed Capacity of Non-Bagasse Cogeneration is 772 MW. 

The eco-friendly business has lots of benefits, by going green with your business you’re promoting the Earth’s safety from potential environmental catastrophe, you support innovation and concomitantly producing green energy.

The Government of India has been constantly bound on increasing the use of clean energy sources. This does increase a better future and at the same time creates employment opportunities too. According to The Ministry of New and Renewable Energy (MNRE), India’s total installed capacity of renewable energy is 90 GW excluding hydropower. Also, it states that 27.41 GW will be added. Renewable Energy in India is a great asset to Energy Contribution, yet India still needs to work a lot in Renewable Energy Sectors.

Scope of Life Sciences and Biotechnology: Understanding Various Specializations and Career Opportunities

Biotechnology, Microbiology and Biochemistry is an interdisciplinary field of applied Biology that encompasses all realms of life sciences, as well as related fields of technology, offers topics based on Genetics, Molecular Biology, Immunology, Biophysics, Plant & Animal Biotechnology, Microbial Biotechnology, Fermentation Technology, Bioinformatics, Genetic Engineering, Medical Biotechnology, and many others. The course also provides ample scope of skill development through appropriate laboratory training in different areas of Biotechnology. SoLB’s mission and vision is to prepare the students to undertake multi-disciplinary research and entrepreneurship in biotechnology and related areas in engineering, medicine and life sciences to provide solutions for human and animal health, agriculture and environment. In addition, our aim is to develop consultancy and community services to establish a thoroughly industrialized nation committed to the virtues of quality and relevance to contribute to the dynamic socio-economic development of the nation.

Key features of SoLB

  • Course structure based on UGC approved Choice Based Credit System (CBCS).
  • A dynamic curriculum that was designed and constantly updated while consulting stalwarts from industry and research institutes.
  • Highly experienced faculty members with PhD from national and International institutes offers teaching in diverse areas of applied biosciences.
  • Technology-based pedagogy including blended learning, flipped classrooms, think-pair-share, peer learning and video lectures.
  • Holistic learning through the development of human values and professional ethics, design thinking, venture ideation and entrepreneurship skills.
  • Seamless interdisciplinary learning and projects across the field.
  • A highly interactive and informative teaching atmosphere where students learn while discussing the relevant topics
  • Adamas Biotechnology Club offers a perfect platform to learn about entrepreneurship, career development and ideation.
  • Student Mentoring System to provide a personalized care for each student.

Why SoLB is your destination for career development in biological sciences

SoLB with its infrastructure of several state of the art labs offers a very interactive and innovative way of teaching. Practical understanding of theories always pave the way for a firm base of our students. Currently we have Molecular Biology lab, Recombinant Technology lab, Bioprocess lab and Plant Biotechnology lab. Additionally this year we have developed three more research labs to perform cutting-edge science in our campus. The new labs are Microbial Genetics lab, Cancer Biology lab and Stem Cell Biology labs addressing the current needs of scientific research. These labs are going to provide a golden opportunity for our graduate and postgraduate students to learn important techniques and building a challenging career. Several professors of SoLB with their strong background in scientific research provide their guidance to our students in shaping their mind to conduct a fruitful research.  

Skill development for industry-ready students

The course structure for several disciplines in SoLB has designed to cater the needs of skilled workers in the bioscience industry. To serve this purpose we have several eminent professors from industry and academia as a member in our Board of studies. Some notable members are Dr. Salavadi Easwaran – Dean, Biocon Academy, Prof. Ramakrishna Sen – HoD, Dept. of Biotechnology, IIT Kharagpur. We also have several courses on innovation, ideation, design & thinking to shape our new minds for innovative creations. These courses will help our students to develop ideas and design their steps to achieve them as a successful commercial product. Further, Adamas University Biotechnology club is offering a platform for our students to materialize their new ideas in the form of products required for betterment of society. The industry internships for students are arranged by our University’s Career Development Cell (CDC) and faculty members. The industry internships are mandatory for course completion.

Achievements of SoLB

The session of 2020-21 proves to be a very successful year for SoLB. Several students of B. Tech Biotechnology qualified GATE exams required to pursue M. Tech degrees in prestigious institutions of India. Among them Anwesha Bose scored GATE All India Rank- 48 becomes a momentary achievement for our school. There are few students from B.Sc. Biotechnology qualify JAM exams conducted by IITs and required to pursue M.Sc. in prestigious institutions of India. The year also marked with very good number of placement of our B. Tech and M.Sc. level students in several reputed companies with attractive salaries. Two professors from Department of Biotechnology and Department of Microbiology receives prestigious research grants from Department of Science and Technology (DST), Govt. of India.

 

Courses offered by SoLB

SoLB is among one of several schools of Adamas University creating vibrant innovative minds for tomorrow’s need of India. There are mainly three departments in SoLB offering twelve knowledge and research-based programmes:

Department of Biotechnology

  • B.Tech Biotechnology (Four-years duration)
  • B.Tech Food technology (Four-years duration)
  • B.Sc. Biotechnology (Three-years duration)
  • M.Tech Biotechnology (Two-years duration)
  • M.Sc. Biotechnology (Two-years duration)
  • PhD Biotechnology (Five-years duration)

Department of Microbiology

  • B.Sc. Microbiology (Three-years duration)
  • B.Sc. Genetics (Three-years duration)
  • M.Sc. Microbiology (Two-years duration)
  • PhD Microbiology (Five-years duration)

Department of Biochemistry

  • B.Sc. Biochemistry (Three-years duration)
  • M.Sc. Biochemistry (Two-years duration)
  • PhD Biochemistry (Five-years duration)

 

Eligibility criterion

B.Tech Biotechnology and B. Tech Food Technology

  • Minimum 60% marks overall in 10 + 2 level with Physics, Chemistry, Biology/Mathematics
  • Qualify Adamas University Admission Test (AUAT) conducted annually.

B.Sc. Biotechnology/ Microbiology/ Biochemistry

  • Minimum 50% marks overall in 10 + 2 level with Physics, Chemistry, Biology/Mathematics
  • Qualify Adamas University Admission Test (AUAT) conducted annually.

M.Tech Biotechnology

  • Minimum 50% marks overall in B.Tech/ M.Sc. (Biotechnology/ Biochemical Engineering/Chemical Engineering) level.
  • Qualify Adamas University Admission Test (AUAT) conducted annually.

M.Sc. Biotechnology/ Microbiology/ Biochemistry

  • Minimum 50% marks overall in B.Sc. (Botany/ Zoology/ Physiology/ Biotechnology/ Microbiology/ Biochemistry/ Agriculture/ or in allied subject) level.

Qualify Adamas University Admission Test (AUAT) conducted annually.

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