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04 August 2023 | Story The Conversation | Photo supplied
Claudia Ntsapi
Dr Claudia Ntsapi, Basic Medical Sciences Lecturer at the University of the Free State.

Opinion article by , Basic Medical Sciences Lecturer

As the world population has grown older, Alzheimer’s disease has become increasingly common. Alzheimer’s disease is the most prevalent form of dementia. Dementia is a term used to describe a range of symptoms linked to the decline in brain function with age. Symptoms include memory loss, communication difficulties, problem-solving struggles, and personality or behavioural changes.

Alzheimer’s disease is an increasingly urgent global issue. The World Health Organization predicts that the number of people with the condition will triple by 2050.

Despite this growing problem, Alzheimer’s disease remains a relatively understudied condition. This is particularly the case in sub-Saharan countries such as South Africa. One major challenge is that Alzheimer’s is a complex condition with no known cure. However, researchers have identified several key risk factors associated with the disease. These include age, genetics, lifestyle factors and underlying medical conditions.

In recent years, one of the most promising areas of research on age-related diseases, such as Alzheimer’s disease, has been the accumulation of harmful proteins in the brain. Specifically amyloid-ß. Amyloid-ß has remained a prominent area of research in Alzheimer’s disease as its build-up is a classic feature in the development of the condition. Understanding its involvement in the disease process is crucial for advancing our knowledge and developing effective strategies to diagnose, prevent and treat the disease.

The accumulation of amyloid-ß can lead to the formation of plaques. These plaques can interfere with communication between brain cells. This ultimately contributes to cognitive decline and other symptoms associated with Alzheimer’s disease.

Amyloid-ß is a large membrane protein that is essential in neural growth and repair. But its corrupted form in later life can destroy nerve cells. This triggers the loss of thought and memory that is associated with Alzheimer’s.

We therefore sought to find out if dietary interventions, particularly intermittent fasting, would counteract the accumulation of amyloid-ß in the brain and potentially safeguard against age-related brain cell death.

In a paper published in 2021, my colleague and I showed that in experiments conducted in mice we found that intermittent fasting counteracted amyloid-ß accumulation in the brain. These findings were further confirmed in a paper published in May of 2022.

Our findings are an important contribution to the search for the potential role of dietary interventions and are consistent with previous studies supporting the idea that intermittent fasting may help counteract amyloid-ß accumulation in the brain and protect against age-related brain cell death. To my knowledge, the most recent study using a variation of intermittent fasting, was published in September 2022. The clinical branch of this study remains ongoing.

Research into the causes of Alzheimer’s has gathered pace in recent years with new ground being broken on a regular basis as scientists search for treatments.

Our study’s findings suggest that intermittent fasting may be an effective way to increase the efficiency of autophagy – the process that breaks down and recycles damaged or unnecessary cellular components, such as organelles and toxic proteins. This process can therefore reduce the risk of amyloid-ß build-up and associated brain cell death.

These findings are particularly significant because they shed light on the relationship between autophagy and the death of brain cells with age, and the potential therapeutic benefits of interventions that target this process.

How it works

Intermittent fasting is a dietary approach that involves regulating food intake by alternating periods of fasting and eating. This dietary regimen comprises periods of restricted food consumption, followed by periods of normal eating.

There are different types of intermittent fasting. One is time-restricted eating, where food is consumed within a specific time window each day. Alternate-day fasting is where food is restricted every other day.

Intermittent fasting has been shown to have various health benefits. Some of the benefits relate to the promotion of brain health.

Our study’s findings suggest that intermittent fasting may be an effective way to increase the efficiency of autophagy, an essential process for removing toxic or misfolded proteins that can build up in cells.

Sometimes autophagy doesn’t work properly to remove harmful proteins or other cellular components from cells. This has been strongly implicated in the development and progression of various age-related diseases, and is a target of research for potential therapies.

What we did

In our study we investigated the effects of intermittent fasting on brain cells in mice, and brain cells isolated from mice with increased amyloid-ß toxicity. Mice cells are frequently used as a model for human cells in scientific research. This is because of the significant genetic similarity between mice and humans. This use of animal models allows researchers to gain valuable insights and test hypotheses. It is generally considered ethically preferable before potentially conducting human studies.

We found that 24 to 48 hours of intermittent fasting by mice provided protection against cell death in specific regions of their brain. We noted increased autophagy levels in cells of fasted mice. Even in the presence of a high amyloid-ß protein load in brain cells, intermittent fasting maintained autophagy activity. And the process remained effective over a 21-day treatment intervention period.

By increasing the efficiency of autophagy, it is possible to maintain the removal of harmful proteins in cells, even as we age.

The findings of this study suggest that interventions such as intermittent fasting could potentially protect against the development of age-related diseases. This has important implications for public health.

Intermittent fasting is a relatively simple dietary intervention: it’s easy to do. It has the potential to be widely adopted as a preventive measure against the onset of age-related diseases. These findings also provide a basis for future research into the mechanisms by which intermittent fasting protects against brain cell death, exploring the potential for additional therapeutic interventions that target autophagy, and examining the effects of different fasting regimens on brain health.The Conversation

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

News Archive

Researcher part of project aimed at producing third-generation biofuels from microalgae in Germany
2016-05-09

Description: Novagreen bioreactor Tags: Novagreen bioreactor

Some of the researchers and technicians among the tubes of the Novagreen bioreactor (Prof Grobbelaar on left)

A researcher from the University of the Free State (UFS), Prof Johan Grobbelaar, was invited to join a group of scientists recently at the Institute for Bio- and Geo-Sciences of the Research Centre Jülich, in Germany, where microalgae are used for lipid (oil) production, and then converted to kerosene for the aviation industry.

The project is probably the first of its kind to address bio-fuel production from microalgae on such a large scale.  

“The potential of algae as a fuel source is undisputed, because it was these photoautotrophic micro-organisms that were fixing sunlight energy into lipids for millions of years, generating the petroleum reserves that modern human civilisation uses today.  However, these reserves are finite, so the challenge is marrying biology with technology to produce economically-competitive fuels without harming the environment and compromising our food security.  The fundamental ability that microalgae have to produce energy-rich biomass from CO2, nutrients, and sunlight through photosynthesis for biofuels, is commonly referred to as the Third-Generation Biofuels (3G),” said Prof Grobbelaar.

The key compounds used for bio-diesel and kerosene production are the lipids and, more particularly, the triacylglyserols commonly referred to as TAGs.  These lipids, once extracted, need to be trans-esterified for biodiesel, while a further “cracking” step is required to produce kerosene.  Microalgae can store energy as lipids and/or carbohydrates. However, for biofuels, microalgae with high TAG contents are required.  A number of such algae have been isolated, and lipid contents of up to 60% have been achieved.

According to Prof Grobbelaar, the challenge is large-scale, high-volume production, since it is easy to manipulate growth conditions in the laboratory for experimental purposes.  

The AUFWIND project (AUFWIND, a German term for up-current, or new impetus) in Germany consists of three different commercially-available photobioreactor types, which are being compared for lipid production.

Description: Lipid rich chlorella Tags: Lipid rich chlorella

Manipulated Chlorella with high lipid contents (yellow) in the Novagreen bioreactor

The photobioreactors each occupies 500 m2 of land surface area, are situated next to one another, and can be monitored continuously.  The three systems are from Novagreen, IGV, and Phytolutions.  The Novagreen photobioreactor is housed in a glass house, and consist of interconnected vertical plastic tubes roughly 150 mm in diameter. The Phytolutions system is outdoors, and consists of curtains of vertical plastic tubes with a diameter of about 90 mm.  The most ambitious photobioreactor is from IGV, and consists of horizontally-layered nets housed in a plastic growth hall, where the algae are sprayed over the nets, and allowed to grow while dripping from one net to the next.

Prof Grobbelaar’s main task was to manipulate growth conditions in such a way that the microalgae converted their stored energy into lipids, and to establish protocols to run the various photobioreactors. This was accomplished in just over two months of intensive experimentation, and included modifications to the designs of the photobioreactors, the microalgal strain selection, and the replacement of the nutrient broth with a so-called balanced one.

Prof Grobbelaar has no illusions regarding the economic feasibility of the project.  However, with continued research, optimisation, and utilisation of waste resources, it is highly likely that the first long-haul flights using microalgal-derived kerosene will be possible in the not-too-distant future.

Prof Grobbelaar from the Department of Plant Sciences, although partly retired, still serves on the editorial boards of several journals. He is also involved with the examining of PhDs, many of them from abroad.  In addition, he assisted the Technology Innovation Agency of South Africa in the formulation of an algae-biotechnology and training centre.  “The chances are good that such a centre will be established in Upington, in the Northern Cape,” Prof Grobbelaar said.

 

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