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The Hunt For Coronavirus Variants: How The New One Was Found And What We Know So Far

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The Hunt For Coronavirus Variants: How The New One Was Found And What We Know So Far


Since early in the COVID pandemic, the Network for Genomics Surveillance in South Africa has been monitoring changes in SARS-CoV-2. This was a valuable tool to understand better how the virus spread. In late 2020, the network detected a new virus lineage, 501Y.V2, which later became known as the beta variant. Now a new SARS-CoV-2 variant has been identified – B.1.1.529. The World Health Organisation has declared it a variant of concern, and assigned it the name Omicron. To help us understand more, The Conversation Africa’s Ozayr Patel asked scientists to share what they know.

What’s the science behind the search?

Hunting for variants requires a concerted effort. South Africa and the UK were the first big countries to implement nationwide genomic surveillance efforts for SARS-CoV-2 as early as April 2020.

Variant hunting, as exciting as that sounds, is performed through whole genome sequencing of samples that have tested positive for the virus. This process involves checking every sequence obtained for differences compared to what we know is circulating in South Africa and the world. When we see multiple differences, this immediately raises a red flag and we investigate further to confirm what we’ve noticed.

Fortunately South Africa is well set up for this. This is thanks to a central repository of public sector laboratory results at the National Health Laboratory Service, (NGS-SA), good linkages to private laboratories, the Provincial Health Data Centre of the Western Cape Province, and state-of-the-art modelling expertise.

In addition, South Africa has several laboratories that can grow and study the actual virus and discover how far antibodies, formed in response to vaccination or previous infection, are able to neutralise the new virus. This data will allow us to characterise the new virus.

The beta variant spread much more efficiently between people compared to the “wild type” or “ancestral” SARS-CoV-2 and caused South Africa’s second pandemic wave. It was therefore classified as a variant of concern. During 2021, yet another variant of concern called delta spread over much of the world, including South Africa, where it caused a third pandemic wave.

Very recently, routine sequencing by Network for Genomics Surveillance member laboratories detected a new virus lineage, called B.1.1.529, in South Africa. Seventy-seven samples collected in mid-November 2021 in Gauteng province had this virus. It has also been reported in small numbers from neighbouring Botswana and Hong Kong. The Hong Kong case is reportedly a traveller from South Africa.

The World Health Organisation has given B.1.1.529 the name Omicron and classified it as a variant of concern, like beta and delta.

Why is South Africa presenting variants of concern?

We do not know for sure. It certainly seems to be more than just the result of concerted efforts to monitor the circulating virus. One theory is that people with highly compromised immune systems, and who experience prolonged active infection because they cannot clear the virus, may be the source of new viral variants.

The assumption is that some degree of “immune pressure” (which means an immune response which is not strong enough to eliminate the virus yet exerts some degree of selective pressure which “forces” the virus to evolve) creates the conditions for new variants to emerge.

Despite an advanced antiretroviral treatment programme for people living with HIV, numerous individuals in South Africa have advanced HIV disease and are not on effective treatment. Several clinical cases have been investigated that support this hypothesis, but much remains to be learnt.

Why is this variant worrying?

The short answer is, we don’t know. The long answer is, B.1.1.529 carries certain mutations that are concerning. They have not been observed in this combination before, and the spike protein alone has over 30 mutations. This is important, because the spike protein is what makes up most of the vaccines.

We can also say that B.1.1.529 has a genetic profile very different from other circulating variants of interest and concern. It does not seem to be a “daughter of delta” or “grandson of beta” but rather represents a new lineage of SARS-CoV-2.

Some of its genetic changes are known from other variants and we know they can affect transmissibility or allow immune evasion, but many are new and have not been studied as yet. While we can make some predictions, we are still studying how far the mutations will influence its behaviour.

We want to know about transmissibility, disease severity, and ability of the virus to “escape” the immune response in vaccinated or recovered people. We are studying this in two ways.

Firstly, careful epidemiological studies seek to find out whether the new lineage shows changes in transmissibility, ability to infect vaccinated or previously infected individuals, and so on.

At the same time, laboratory studies examine the properties of the virus. Its viral growth characteristics are compared with those of other virus variants and it is determined how well the virus can be neutralised by antibodies found in the blood of vaccinated or recovered individuals.

In the end, the full significance of the genetic changes observed in B.1.1.529 will become apparent when the results from all these different types of studies are considered. It is a complex, demanding and expensive undertaking, which will carry on for months, but indispensable to understand the virus better and devise the best strategies to combat it.

Do early indications point to this variant causing different symptoms or more severe disease?

There is no evidence for any clinical differences yet. What is known is that cases of B.1.1.529 infection have increased rapidly in Gauteng, where the country’s fourth pandemic wave seems to be commencing. This suggests easy transmissibility, albeit on a background of much relaxed non-pharmaceutical interventions and low number of cases. So we cannot really tell yet whether B.1.1.529 is transmitted more efficiently than the previously prevailing variant of concern, delta.

COVID-19 is more likely to manifest as severe, often life-threatening disease in the elderly and chronically ill individuals. But the population groups often most exposed first to a new virus are younger, mobile and usually healthy people. If B.1.1.529 spreads further, it will take a while before its effects, in terms of disease severity, can be assessed.

Fortunately, it seems that all diagnostic tests that have been checked so far are able to identify the new virus.

Even better, it appears that some widely used commercial assays show a specific pattern: two of the three target genome sequences are positive but the third one is not. It’s like the new variant consistently ticks two out of three boxes in the existing test. This may serve as a marker for B.1.1.529, meaning we can quickly estimate the proportion of positive cases due to B.1.1.529 infection per day and per area. This is very useful for monitoring the virus’s spread almost in real time.

Are current vaccines likely to protect against the new variant?

Again, we do not know. The known cases include individuals who had been vaccinated. However we have learnt that the immune protection provided by vaccination wanes over time and does not protect as much against infection but rather against severe disease and death. One of the epidemiological analyses that have commenced is looking at how many vaccinated people become infected with B.1.1.529.

The possibility that B.1.1.529 may evade the immune response is disconcerting. The hopeful expectation is that the high seroprevalence rates, people who’ve been infected already, found by several studies would provide a degree of “natural immunity” for at least a period of time.

Ultimately, everything known about B.1.1.529 so far highlights that universal vaccination is still our best bet against severe COVID-19 and, together with non-pharmaceutical interventions, will go a long way towards helping the healthcare system cope during the coming wave.

Prof. Wolfgang Preiser, Head: Division of Medical Virology, Stellenbosch University; Cathrine Scheepers, Senior Medical Scientist, University of the Witwatersrand; Jinal Bhiman, Principal Medical Scientist at National Institute for Communicable Diseases (NICD), National Institute for Communicable Diseases; Marietjie Venter, Head: Zoonotic, Arbo and Respiratory Virus Programme, Professor, Department Medical Virology, University of Pretoria, and Tulio de Oliveira, Director: KRISP – KwaZulu-Natal Research and Innovation Sequencing Platform, University of KwaZulu-Natal

This article is republished from The Conversation under a Creative Commons license. Read the original article.





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Feeling Tired All The Time? Possible Causes And Solutions

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Long days of work, lack of sleep, and stress at the office can be the most common factors that make you feel tired. However, feeling “tired all the time” (TATT) without known reasons can be an indication of an underlying health issue that needs immediate attention.

Finding the exact cause of the lingering tiredness can be the first step toward solving the symptom.

Health conditions that cause fatigue:

1. Anemia – Anemia is one of the most common causes of fatigue. A person who has anemia does not have enough red blood cells in the body, causing symptoms such as tiredness, dizziness, feeling cold and crankiness.

Most often, anemia is caused by iron deficiency. Hence, the condition can be best resolved by including iron-rich foods in the diet and use of iron supplements.

2. Sleep Apnea – It causes the body to stop breathing momentarily during sleep. The condition can affect the quality of sleep and hence make you feel fatigued.

For milder cases of sleep apnea, lifestyle changes such as losing weight or quitting smoking can help solve the sleep disorder. In more severe cases where there is an obstruction in breathing, surgeries and therapies can help.

3. Diabetes – A person who has diabetes has changes in blood sugar level, which can cause fatigue. A patient who is already on diabetic medication can also experience tiredness as a side effect of the medication.

Early identification and taking the correct treatment is the key to managing diabetes. Losing extra weight and having a healthy diet also help in the treatment.

4. Thyroid – Thyroid diseases can be due to an overactive or an underactive thyroid gland. In people who have an underactive thyroid (hypothyroidism), the metabolism slows down leading to symptoms such as lethargy and fatigue. In people with an overactive thyroid (hyperthyroidism), the metabolism speeds up leading to fatigue and difficulty sleeping.

Right diet and lifestyle choices, along with medications, can help in thyroid management.

5. Infections – A person can show symptoms of fatigue when the body is fighting a viral or bacterial infection. Infections ranging from the flu to HIV can cause tiredness.

Along with fatigue, other symptoms such as fever, headache, body aches, shortness of breath and appetite loss can also accompany the infection. Treating the symptoms and taking adequate rest helps in faster recovery.

6. Food allergies – Fatigue may be an early warning sign of hidden food allergies and autoimmune disorders such as celiac disease. Identifying the allergen using a food allergy test or through an elimination diet can help in allergy treatment.

7. Heart disease – If you feel exhausted from an activity that used to be easy, then it is good to check your heart health, as fatigue can be an indication of underlying heart disease.

8. Depression/ anxiety – Fatigue can also be an indicator of a mental health disorder such as depression or anxiety. A combination of medication and psychotherapy can help relieve symptoms.

Lifestyle causes

Apart from serious health conditions, certain lifestyle habits such as dehydration, poor diet, stress and insufficient sleep can cause exhaustion. Having a well-balanced diet, regular exercise and routine sleep can help solve fatigue caused by lifestyle habits.

Published by Medicaldaily.com



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How To Overcome Your Sleep Debt And Reclaim Energy

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Picture this: you’re burning the midnight oil, studying or binge-watching your favorite shows, all at the expense of a good night’s sleep. Have you ever stopped to think about the toll it takes on your body and mind? The consequences can be more serious than you might realize.

Not getting enough sleep can translate into a multitude of issues, including weight gain, lack of focus, tiredness, a haze of confusion, and even depression. If you too are encountering similar issues lately then chances are you have a sleep debt.

Wondering what is sleep debt?

People from 13-18 years of age need 8 hours of sleep, whilst adults beyond that age will require at least 7 hours of snooze.

Sleep debt is a collection of the total hours you haven’t slept or traded your sleep for something else. Sleep debt keeps piling up as a person falls short of the total hours of sleep recommended for an adult, according to the Centers for Disease Control and Prevention.

And when you keep letting go of your sleep for other activities, the body adapts to the new normal and effects start to reflect on the energy levels, which deplete.

“However, like every other debt out there, this too has a repayment option,” Dr. Kunal Kumar, medical director of the Sleep Center at Einstein Medical Center in Philadelphia, told Livestrong.

Below are some expert-vetted ways you can pay back the sleep debt. (Courtesy: Livestrong and Sleepfoundation)

Just like financial debt, imagine sleep debt as a debt you owe to your body. It needs to be repaid. The good news is that catching up on sleep is indeed possible.

  • Maintain a set sleep schedule: Overhauling the sleep schedule is a pretty difficult task to achieve, and it’s best to do that gradually. Create a set sleep schedule by making some small changes to your routine. Instead of making abrupt shifts in your bedtime or wake-up time, adjust them gradually by 15 to 30-minute increments.
  • Minimize your gadget usage: Wind down activities and minimize electronic usage before bed to promote better sleep. Relax and prepare for quality sleep by dimming the lights and setting an alarm for 30 minutes to an hour before bed.
  • Reshuffle your sleeping arrangements: Are you finding it hard to get a good night’s sleep due to excessive sweating? Well, here’s a handy solution: consider upgrading to a cooling mattress or opting for cooling sheets. These innovative sleep essentials can help regulate your body temperature, and keep you comfortably cool throughout the night, ensuring a more blissful slumber. Memory foam pillows can work wonders in relieving neck and back discomfort in case you are struggling with backache.
  • Improve the bedroom environment: Create a sleep-friendly bedroom environment by adjusting the temperature for comfort, and blocking out disruptive lights, or noises that might disturb your restful slumber. And if your mattress, pillow, or sheets are worn out or no longer providing the support you need, consider treating yourself to new ones.

Published by Medicaldaily.com



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Omega-3 Fatty Acids Slow The Progression Of Amyotrophic Lateral Sclerosis: Study

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Omega-3 fatty acids are known for a range of health benefits, from promoting brain and heart health to reducing inflammation and protection against several chronic conditions.

In a new study, researchers found that omega-3 acids, especially the type found in foods like flaxseeds, walnuts, chia seeds, canola oil and soybean oil, can slow down the progression of amyotrophic lateral sclerosis (ALS).

It is a debilitating nervous system disease that gradually worsens over time and can be fatal. The condition results in a loss of muscle control and affects the nerve cells in the brain and spinal cord. It is also known as Lou Gehrig’s disease after the baseball player who was diagnosed with it.

The initial symptoms of the disease include muscle weakness, difficulty in walking and hand movements. The symptoms can slowly progress to difficulties with chewing, swallowing, speaking and breathing.

The exact cause of ALS is not known. However, around 10% of people get it from a risk gene passed down from a family member. It is estimated that more than 32,000 people in the U.S. live with the condition.

In the latest study, researchers from Harvard T.H. Chan School of Public Health in Massachusetts evaluated 449 people living with ALS in a clinical trial. The team assessed the severity of their symptoms, the progression of their disease, along with the levels of omega-3 fatty acids in their blood, for 18 months.

The study suggested that alpha-linolenic acid (ALA), a type of omega-3 found in plants, is particularly beneficial in slowing the progression of ALS. The participants with the highest levels of ALA had a 50% reduced risk of death during the study period compared to those with the lowest levels of ALA.

Researchers also found a reduction in death risk in participants who had eicosapentaenoic acid, the type of omega-3 fatty acid found in fatty fish and fish oil, and linoleic acid found in vegetable oils, nuts and seeds.

A previous study conducted by the same team suggested that a diet high in ALA and higher blood levels of the nutrient could reduce the risk of developing the condition.

“In this study, we found that among people living with ALS, higher blood levels of ALA were also associated with a slower disease progression and a lower risk of death within the study period. These findings, along with our previous research suggest that this fatty acid may have neuroprotective effects that could benefit people with ALS,” said Kjetil Bjornevik, the lead author of the study.

Published by Medicaldaily.com



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