Category Medical World

How do MRNA vaccines work?

A shot in the arm!

Vaccines have helped control many infectious diseases. But developing them is not easy and also takes years. With researchers working tirelessly for months together, what seemed like an endless wait for a vaccine against COMD-19 has given way to hope with the UK approving the Pfizer/ BioNTech vaccine for the coronavirus. COVID-19 has claimed over 1.5 million lives worldwide

Pfizer’s BNT162b2, which took only 10 months from conception to approval is an MRNA vaccine approved for use in humans for the first time. The vaccine has been shown to be 95% effective in preventing COMD-19. It needs to be stored in bones containing dry ice that are capable of staying at -70 degrees Celsius, the frigid temperature needed to preserve the drug. Besides the U.K., other countries such as Bahrain Canada, Saudi Arabia, Mexico, Israel and the U.S. have approved the emergency use of the Pfizer vaccine.

What is an MRNA vaccine?           

Vaccines work by priming the body to recognise and fight the proteins produced by disease-causing organisms. Instead of using an inactivated coronavirus or viral proteins in a vaccine, an MRNA vaccine uses a messenger RNA, or MRNA, to prompt an immune response in the body. An MRNA is a synthetic genetic material, a copy of a natural component of living cells. An mRNA vaccine carries genetic instructions, which direct cells in the body to make viral proteins that prime the immune system to produce protective antibodies. If these antibodies adhere to a virus, it cannot enter the cells to replicate.

Are they safe?

MRNA vaccines are said to be safer than live vaccines, as there is a risk of the virus reverting to a dangerous form with the latter. MRNA vaccines are not likely to produce unwanted reactions. Besides, they can be made much faster than the traditional vaccines.

Picture Credit : Google

How do hearing aids work?

A hearing aid, which consists of a microphone, amplifier, and speaker, makes sound louder for the user.

A hearing aid is a small electronic or digital medical device designed to help people who are hard of hearing. It makes sound louder for the user.

A hearing aid basically consists of three parts- a microphone, amplifier, and speaker. The microphone collects the sounds from the user’s environment and converts the sound waves into electrical (or digital) signals. The amplifier magnifies the power of the signals and then sends them to the inner ear through a speaker.

Those with a hearing disability have damaged hair cells in the inner ear. The surviving hair cells detect the sound vibrations magnified by the hearing aid and transmit them to the brain. However, if the hair cells are too damaged, then a hearing aid may be ineffective.

Hearing aids are available in various styles. The most common ones known as behind-the-ear (BTE) aids, consist of plastic cases worn behind the ear, which contain the electronic parts. The cases are connected with a narrow tube to the earmold which is inserted inside the ear. Smaller hearing aids in the form of earmolds that fit in snugly inside the ear are almost invisible to others like in-the-ear (ITE), in-the-canal (ITC) and completely-in-canal (CIC) aids.

Picture Credit : Google 

What are the achievements of T Govindaraju?

T Govindaraju has made significant contributions in the medical field. He is a professor in the Bioorganic Chemistry Laboratory at the Jawaharlal Nehru Centre for Advanced Scientific Research (JNCAR), Bengaluru. Bioorganic Chemistry uses chemical methods in the study of biological processes.

Prof. Govindaraju is from a remote village in Karnataka. As a school boy, he saw that mentally ill patients were treated cruelly. This image guided him to choose his area of research. He completed his PhD from CSIR-NCL. He then did post-doctoral research in the U.S and Germany. His research was on neuro degenerative diseases and cancer. Neuro degenerative diseases occur when cells in the central nervous system stop working.

You must have also heard about Alzheimer’s disease. This occurs when the brain becomes small and the brain cells die. Prof. Govindaraju and his team discovered a new molecule -TGR63 which could be the future drug to treat Alzheimer’s. A Delhi based pharma company has obtained the rights to do its trial runs.

Prof. Govindaraju found the similarities between Alzheimer’s disease and cancer and this led to the discovery of TGP 18, another molecule-based drug. This could be used to treat lung cancer.

He was a Humboldt research fellow in Germany and a visiting faculty at the University of Paris, France. He is also keen on raising the standards of rural schools and has been a part of outreach initiatives. He is also into bringing awareness about mental illness among school children in Karnataka and other states.

Picture Credit : Google 

How did Wilson Greatbatch invented the pacemaker?

Quite by accident, American engineer Wilson Greatbatch invented the implantable cardiac pacemaker in the year 1958. Read on to know how….

An artificial pacemaker is a small battery-operated electronic device that’s placed under the skin in the chest to help control the heartbeat. The first successful implantable pacemaker was invented in 1958 by an American electrical engineer, Wilson Greatbatch. He was making a heart rhythm recorder when, by mistake, he added a wrong electronic component. He was shocked when the device, instead of simply recording the sound of the heartbeat, produced electronic pulses quite similar to the sounds made by a healthy heart.

It struck him then that the device could make an unhealthy heart beat in rhythm by delivering electrical pulses to make the heart muscles contract and pump blood. For two years he worked on modifying the device. He miniaturised it, coated it with a kind of resin to prevent it from getting damaged by body fluids, and powered it with a mercury-zinc battery.

Greatbatch discussed his invention with surgeon William Chardack, whom he met in a chance encounter. In 1960, the Chardack-Greatbatch pacemaker was implanted in an elderly man with an irregular heartbeat. The patient’s life was extended by 18 months.

Pacemakers today are about the size of a bullet. They are encased in titanium and keep the heart ticking with regular beats through computer-guided electrical pulses. They are inserted through the leg up into the right ventricle. Their batteries can last from 5 to 15 years.

Picture Credit : Google 

Scientists create first ‘synthetic embryo’

In a research breakthrough, scientists have created world’s first synthetic embryo with a brain and a beating heart. The scientists used only stem cells to create synthetic mouse embryo models. Replete with a beating heart, and a brain, the embryo was created sans sperm, eggs and fertilisation.

The feat was achieved by researchers from the University of Cambridge. The team was led by Professor Magdalena Zernicka-Goetz. The result was the creation of a beating heart and brain. The work is the result of decades-long research.

The new findings will aid in reaching a better understanding about how tissues are formed during the natural course of development, that is in the case of natural embryos.

The breakthrough is key because it opens new frontiers for learning how the stem cells form into organs in the embryo. In the future, this could help grow organs and tissues using synthetic embryo models. They are called synthetic embryos as they are made without fertilised eggs. This will be a game-changer for human organ transplantation as transplantable tissues can be created thus.

“Our mouse embryo model not only develops a brain but also a beating heart, all the components that go on to make up the body,” said Zemicka-Goetz, Professor in Mammalian Development and Stem Cell Biology in Cambridge’s Department of Physiology, Development and Neuroscience in a release issued by the university.

“The stem cell embryo model is important because it gives us accessibility to the developing structure at a stage that is normally hidden from us due to the implantation of the tiny embryo into the mother’s womb. This accessibility allows us to manipulate genes to understand their developmental roles in a model experimental system.” Zernicka-Goetz added in the release.

For the development of the synthetic embryo, cultured stem cells representing the types of tissues were put together in a suitable environment that aided in their growth. One of the major achievements of the study is the growth of the entire brain, especially the anterior part of the brain.

The present research was being carried out in mouse models and the researchers plan to develop human models. This will aid in studying those aspects of the organs that would not be possible in real embryos.

The researchers are also developing an analogous model of the human embryo to further their studies. This is crucial as all these findings can help understand why some human pregnancies fail.  The understanding at the embryo level is crucial as the majority of human pregnancies fail at the developmental stage.

WHAT ARE STEM CELLS?

Our body is home to hundreds of types of cells. A majority of them begin as stem cells. They carry within them instructions to develop into specialised cells such as muscle, blood or brain cell. In short, stem cells are human cells that grow into different cell types ranging from brain cells to nerve cells. They can be used to treat damaged tissues. Stem cell-based therapies are being carried out for serious medical conditions such as Alzheimer’s, Parkinsons’ and other genetic disorders.

MAJOR BREAKTHROUGHS IN STEM CELL RESEARCH

1981:  Embryonic stem cells identified in mice for the first time by Martin Evans of Cardiff University, UK.

1997:  The first artificial animal clone, Dolly the sheep, created. It was a turning point in stem cell research.

1998:  Human embryonic stem cells were isolated and grown in the lab. 2007 The Nobel Prize in Medicine, 2007, was given to Mario R. Capecchi, Sir Martin J. Evans and Oliver Smithies “for their discoveries of principles for introducing specific gene modifications in mice by the use of embryonic stem cells.”

2012:  Human embryonic stem cells used in two patients. It helped improve their vision.

2022:  The Ogawa-Yamanaka Stem Cell Prize was awarded to Juan Carlos Izpisua Belmonte for his work on cellular rejuvenation programming aimed at improving age-associated diseases.

Picture Credit : Google

WHAT IS A BILDUNGSROMAN?

A bildungsroman is a testament to how literature deals with the souls of individuals. It highlights how our lives are a multi-dimensional confluence of revenge, tragedy, comedy, and satire, seasoned with age and made amicable by experience.

A bildungsroman is a jargonic term used for a coming-of-age story. It is a literary genre that focusses on the protagonist’s spiritual journey from a point in his or her childhood to adulthood. Coined in 1819 by Karl Morgenstern a philologist, this term is a combination of two German words ‘Bildung’ meaning education, and Roman’ which means “novel.” The first book to ascribe to this genre was Wilhelm Meister’s Apprenticeship by Johann Wolfgang Goethe. Published in 1796, this German classic records the titular character Wilhelm Meisters journey to self-discovery through the medium of theatre and art.

The Shift

Literary works of this genre are character-centric and lay special emphasis on the shifts in prespective that accompany life-altering experiences and help mould a more realistic worldview of the character.

A bildungsroman is a testament to how literature deals with the souls of individuals. It highlights how our lives are a multi-dimensional confluence of revenge, tragedy, comedy, and satire, seasoned with age and made amicable by experience. Some popular literary works of this genre include To Kill a Mockingbird by Harper Lee. The Diary of a Young Girl by Anne Frank, David Copperfield by Charles Dickens, The Harry Potter series by J. K. Rowling, and The Lord of the Ring” series by J. R. R. Tolkien.

Picture Credit : Google