Tag Archives: Ivan Mijakovic

Reducing toxicity of Alzheimer’s proteins with graphene oxide

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Nobody really knows what causes Alzheimer’s disease (a form of dementia) so researchers continue to investigates the cause(s) and, also, possible remedies. An October 4, 2023 news item on ScienceDaily announces some of the latest research,

A probable early driver of Alzheimer’s disease is the accumulation of molecules called amyloid peptides. These cause cell death, and are commonly found in the brains of Alzheimer’s patients. Researchers at Chalmers University of Technology, Sweden, have now shown that yeast cells that accumulate these misfolded amyloid peptides can recover after being treated with graphene oxide nanoflakes.

An October 4, 2023 Chalmers University of Technology press release (also received via email and on EurekAlert) by Susanne Nilsson Lindh & Johanna Wilde, which originated the news item, delves into the topic,

Alzheimer’s disease is an incurable brain disease, leading to dementia and death, that causes suffering for both the patients and their families. It is estimated that over 40 million people worldwide are living with the disease or a related form of dementia. According to Alzheimer’s News Today, the estimated global cost of these diseases is one percent of the global gross domestic product.

Misfolded amyloid-beta peptides, Aβ peptides, that accumulate and aggregate in the brain, are believed to be the underlying cause of Alzheimer’s disease. They trigger a series of harmful processes in the neurons (brain cells) – causing the loss of many vital cell functions or cell death, and thus a loss of brain function in the affected area. To date, there are no effective strategies to treat amyloid accumulation in the brain.

Researchers at Chalmers University of Technology have now shown that treatment with graphene oxide leads to reduced levels of aggregated amyloid peptides in a yeast cell model.

“This effect of graphene oxide has recently also been shown by other researchers, but not in yeast cells”, says Xin Chen, Researcher in Systems Biology at Chalmers and first author of the study. “Our study also explains the mechanism behind the effect. Graphene oxide affects the metabolism of the cells, in a way that increases their resistance to misfolded proteins and oxidative stress. This has not been previously reported.”

Investigating the mechanisms using baker’s yeast affected by Alzheimer’s disease
In Alzheimer’s disease, the amyloid aggregates exert their neurotoxic effects by causing various cellular metabolic disorders, such as stress in the endoplasmic reticulum – a major part of the cell, in which many of its proteins are produced. This can reduce cells’ ability to handle misfolded proteins, and consequently increase the accumulation of these proteins.

The aggregates also affect the function of the mitochondria, the cells’ powerhouses. Therefore, the neurons are exposed to increased oxidative stress (reactive molecules called oxygen radicals, which damage other molecules); something to which brain cells are particularly sensitive.

The Chalmers researchers have conducted the study by a combination of protein analysis (proteomics) and follow-up experiments. They have used baker’s yeast, Saccharomyces cerevisiae, as an in vivo model for human cells. Both cell types have very similar systems for controlling protein quality. This yeast cell model was previously established by the research group to mimic human neurons affected by Alzheimer’s disease.

“The yeast cells in our model resemble neurons affected by the accumulation of amyloid-beta42, which is the form of amyloid peptide most prone to aggregate formation”, says Xin Chen. “These cells age faster than normal, show endoplasmic reticulum stress and mitochondrial dysfunction, and have elevated production of harmful reactive oxygen radicals.”

High hopes for graphene oxide nanoflakes
Graphene oxide nanoflakes are two-dimensional carbon nanomaterials with unique properties, including outstanding conductivity and high biocompatibility. They are used extensively in various research projects, including the development of cancer treatments, drug delivery systems and biosensors.

The nanoflakes are hydrophilic (water soluble) and interact well with biomolecules such as proteins. When graphene oxide enters living cells, it is able to interfere with the self-assembly processes of proteins.

“As a result, it can hinder the formation of protein aggregates and promote the disintegration of existing aggregates”, says Santosh Pandit, Researcher in Systems Biology at Chalmers and co-author of the study. “We believe that the nanoflakes act via two independent pathways to mitigate the toxic effects of amyloid-beta42 in the yeast cells.”

In one pathway, graphene oxide acts directly to prevent amyloid-beta42 accumulation. In the other, graphene oxide acts indirectly by a (currently unknown) mechanism, in which specific genes for stress response are activated. This increases the cell’s ability to handle misfolded proteins and oxidative stress.

How to treat Alzheimer’s patients is still a question for the future. However, according to the research group at Chalmers, graphene oxide holds great potential for future research in the field of neurodegenerative diseases. The research group has already been able to show that treatment with graphene oxide also reduces the toxic effects of protein aggregates specific to Huntington’s disease in a yeast model.

“The next step is to investigate whether it is possible to develop a drug delivery system based on graphene oxide for Alzheimer’s disease.” says Xin Chen. “We also want to test whether graphene oxide has beneficial effects in additional models of neurodegenerative diseases, such as Parkinson’s disease.”

More about: proteins and peptides
Proteins and peptides are fundamentally the same type of molecule and are made up of amino acids. Peptide molecules are smaller – typically containing less than 50 amino acids – and have a less complicated structure. Proteins and peptides can both become deformed if they fold in the wrong way during formation in the cell. When many amyloid-beta peptides accumulate in the brain, the aggregates are classified as proteins.

Here’s a link to and a citation for the paper,

Graphene Oxide Attenuates Toxicity of Amyloid-β Aggregates in Yeast by Promoting Disassembly and Boosting Cellular Stress Response by Xin Chen, Santosh Pandit, Lei Shi, Vaishnavi Ravikumar, Julie Bonne Køhler, Ema Svetlicic, Zhejian Cao, Abhroop Garg, Dina Petranovic, Ivan Mijakovic. Advanced Functional Materials Volume 33, Issue 45 November 2, 2023 2304053 DOI: https://doi.org/10.1002/adfm.202304053 First published online: 07 July 2023

This paper is open access.

Killer graphene spikes to kill bacteria on medical implants

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Implants of all kinds (hip replacements, knee replacements, etc.) seem to be on the rise and along with that an increasing number of infections. A Swedish research team announces a technology that could make implants safer in an April 16, 2018 news item on Nanowerk,

A tiny layer of graphene flakes becomes a deadly weapon and kills bacteria, stopping infections during procedures such as implant surgery. This is the findings of new research from Chalmers University of Technology, Sweden, recently published in the scientific journal Advanced Materials Interfaces (“Vertically Aligned Graphene Coating is Bactericidal and Prevents the Formation of Bacterial Biofilms”).

An April 16, 2018 Chalmers University of Technology press release (also on EurekAlert), which originated the news item, provides more detail about the scope of the problem and the proposed solution (Note: A link has been removed),

Operations for surgical implants, such as hip and knee replacements or dental implants, have increased in recent years. However, in such procedures, there is always a risk of bacterial infection. In the worst case scenario, this can cause the implant to not attach to the skeleton, meaning it must be removed.

Bacteria travel around in fluids, such as blood, looking for a surface to cling on to. Once in place, they start to grow and propagate, forming a protective layer, known as a biofilm.

A research team at Chalmers has now shown that a layer of vertical graphene flakes forms a protective surface that makes it impossible for bacteria to attach. Instead, bacteria are sliced apart by the sharp graphene flakes and killed. Coating implants with a layer of graphene flakes can therefore help protect the patient against infection, eliminate the need for antibiotic treatment, and reduce the risk of implant rejection. The osseointegration – the process by which the bone structure grow to attach the implant – is not disturbed. In fact, the graphene has been shown to benefit the bone cells.

Chalmers University is a leader in the area of graphene research, but the biological applications did not begin to materialise until a few years ago. The researchers saw conflicting results in earlier studies. Some showed that graphene damaged the bacteria, others that they were not affected.

“We discovered that the key parameter is to orient the graphene vertically. If it is horizontal, the bacteria are not harmed” says Ivan Mijakovic, Professor at the Department of Biology and Biological Engineering.

The sharp flakes do not damage human cells. The reason is simple: one bacterium is one micrometer – one thousandth of a millimeter – in diameter, while a human cell is 25 micrometers. So, what constitutes a deadly knife attack for a bacterium, is therefore only a tiny scratch for a human cell.

“Graphene has high potential for health applications. But more research is needed before we can claim it is entirely safe. Among other things, we know that graphene does not degrade easily” says Jie Sun, Associate Professor at the Department of Micro Technology and Nanoscience.

Good bacteria are also killed by the graphene. But that’s not a problem, as the effect is localised and the balance of microflora in the body remains undisturbed.

“We want to prevent bacteria from creating an infection. Otherwise, you may need antibiotics, which could disrupt the balance of normal bacteria and also enhance the risk of antimicrobial resistance by pathogens” says Santosh Pandit, postdoc at Biology and Biological Engineering.

Vertical flakes of graphene are not a new invention, having existed for a few years. But the Chalmers research teams are the first to use the vertical graphene in this way. The next step for the research team will be to test the graphene flakes further, by coating implant surfaces and studying the effect on animal cells.

Chalmers cooperated with Wellspect Healthcare, a company which makes catheters and other medical instruments, in this research. They will now continue with a second study.

Here’s a link to and a citation for the paper,

Vertically Aligned Graphene Coating is Bactericidal and Prevents the Formation of Bacterial Biofilms by Santosh Pandit, Zhejian Cao, Venkata R. S. S. Mokkapati, Emanuele Celauro, Avgust Yurgens, Martin Lovmar, Fredrik Westerlund, Jie Sun, Ivan Mijakovic. Advanced Materials Interfaces Volume5, Issue7 April 9, 2018 Pages 1701331 [sic] https://doi.org/10.1002/admi.201701331 First published [online]: 2 February 2018

This paper is behind a paywall.

Finally, here’s a ‘killer spikes’ video made available by Chalmers University of Technology,