Brain shrinkage observed in people receiving drugs for Alzheimer’s treatment actually reflects their efficacy, suggests to a new study from University College London. The researchers analysed data from a dozen different trials of amyloid-targeting immunotherapy – including lecanemab, recently approved in the UK for Alzheimer’s treatment but not yet used by the NHS.
While brain shrinkage is usually an undesirable outcome, the team found that the excess volume loss was consistent across studies and correlated with how effective the therapy was in removing amyloid and was not associated with harm.
As a result, the researchers believe that the removal of amyloid plaques, which are abundant in Alzheimer’s patients, could account for the observed brain volume changes. And, as such, the volume loss should not be a cause for concern.
To describe this phenomenon, the research team coined a new phrase: “amyloid-removal-related pseudo-atrophy” or ARPA. The team published their findings in published in Lancet Neurology.
Senior author and Director of the UCL Dementia Research Centre, Professor Nick Fox said: “Amyloid-targeting monoclonal antibodies represent a significant therapeutic breakthrough in the treatment of Alzheimer’s disease. These agents work by binding to and triggering the removal of amyloid plaques from the brain.
“One area of controversy has been the effect of these agents on brain volumes. Brain volume loss is a characteristic feature of Alzheimer’s disease, caused by progressive loss of neurons.
“Amyloid immunotherapy has consistently shown an increase in brain volume loss – leading to concerns in the media and medical literature that these drugs could be causing unrecognised toxicity to the brains of treated patients.
“However, based on the available data, we believe that this excess volume change is an anticipated consequence of the removal of pathologic amyloid plaques from the brain of patients with Alzheimer’s disease.”
In August, the Medicines and Healthcare Products Regulatory Agency (MHRA) licensed lecanemab, for use in the early stages of Alzheimer’s disease in the UK *.
The drug works by targeting beta amyloid – a protein that builds up in the brains of people with Alzheimer’s disease and is thought to be the triggering event leading to neuronal dysfunction and cell death.
The National Institute for Health and Care Excellence (NICE) that decide whether drugs should be made available on the NHS have published draft guidance advising that the benefits of lecanemab are too small to justify the cost to the NHS. However, the decision will be reviewed following a public consultation and a second independent committee meeting later this year.
An international team of scientists have revealed that the widely prescribed Parkinson’s disease drug entacapone significantly disrupts the human gut microbiome by inducing iron deficiency. This international study, provides new insights into the often-overlooked impact of human-targeted drugs on the microbial communities that play a critical role in human health. The findings, published in Nature Microbiology, suggest however that iron supplementation can help counteract these impacts.
While it is well established that antibiotics can significantly disrupt the human gut microbiome, emerging research shows that a wide range of human-targeted drugs – particularly those used to treat neurological conditions – can also profoundly affect the microbial communities living in our bodies. Despite their intended therapeutic effects on different organs, these drugs can inadvertently disrupt the balance of gut microbes, leading to potential health consequences. Until now, most studies investigating these interactions relied either on patient cohort analyses affected by many confounding factors or on experiments using isolated gut bacteria, which do not fully capture the complexity of the human microbiome.
Investigating drug–bug interactions
The team, which included some from the University of Vienna, used a novel experimental approach. The researchers studied the effects of two drugs – entacapone and loxapine, a medication for schizophrenia – on faecal samples from healthy human donors. They incubated the samples with therapeutic concentrations of these drugs, then analysed the impact on the microbial communities using advanced molecular and imaging techniques, including heavy water labelling combined with Stimulated Raman Spectroscopy (SRS). The team discovered that loxapine and even more so entacapone severely inhibited many microbiome members, while E. coli dramatically expanded in the presence of entacapone.
“The results were even more striking when we examined microbial activity, rather than just their abundance,” explained Fatima Pereira, lead author of the study and former Postdoctoral researcher at the University of Vienna. “The heavy water-SRS method allowed us to observe the subtle yet significant changes in the gut microbiome, which are often missed in traditional abundance-based measurements.”
Entacapone induces iron starvation, favours pathogenic microbes
The researchers hypothesised that entacapone might interfere with iron availability in the gut, a crucial resource for many microbes. Their experiments confirmed that adding iron to faecal samples containing entacapone counteracted the drug’s microbiome-altering effects. Further investigation revealed that E. coli, which thrived under these conditions, carried a highly efficient iron-uptake system (enterobactin siderophore). This system allowed the bacteria to overcome iron starvation and proliferate, even in the presence of the drug.
“By showing that entacapone induces iron deficiency, we have uncovered a new mechanism of drug-induced gut dysbiosis, in which the drug selects for E. coli and other potentially pathogenic microbes well adapted to iron limiting conditions,” said Michael Wagner, scientific director of the Excellence Cluster and vice-head of the Centre for Microbiology and Environmental Systems Science (CeMESS) at the University of Vienna.
Wider implications for drug–microbiome interactions
This discovery has broader implications for understanding how other human-targeted drugs might affect the gut microbiome. Several drugs, including entacapone, contain metal-binding catechol groups, suggesting that this mechanism could be a more common pathway for drug-induced microbiome alterations.
The findings also present an opportunity to mitigate the side effects of drugs like entacapone. By ensuring sufficient iron availability to the large intestine, it may be possible to reduce dysbiosis and the gastrointestinal issues that often accompany Parkinson’s disease treatment.
“The next step is to explore how we can modify drug treatments to better support the gut microbiome,” said Wagner. “We are looking at strategies to selectively deliver iron to the large intestine, where it can benefit the microbiome without interfering with drug absorption in the small intestine.”
People diagnosed with type 2 diabetes at a younger age are at a higher risk for developing dementia than those diagnosed later in life, according to a study led by researchers at the NYU Rory Meyers College of Nursing. The findings, published in PLOS ONE, show that the increased risk is especially pronounced among adults with obesity.
“Our study suggests that there may be cognitive consequences to earlier onset type 2 diabetes, and it points to the need for strategies to prevent dementia that consider both diabetes and obesity,” said Xiang Qi, assistant professor at NYU Meyers and the study’s first author.
Type 2 diabetes is a known risk factor for dementia. Although the underlying mechanisms are not fully understood, scientists think that some of the hallmarks of diabetes, such as high blood sugar, insulin resistance, and inflammation, may encourage the development of dementia in the brain.
While type 2 diabetes was once a disease of older adults, it is increasingly prevalent among younger individuals: one in five people with type 2 diabetes worldwide is under 40 years old.
To understand how the timing of a type 2 diabetes diagnosis relates to dementia risk, the research team analyzed data from 2002 to 2016 in the Health and Retirement Study, a longitudinal study conducted by the University of Michigan Institute for Social Research. The PLOS ONE study included 1213 US adults aged 50 and over with type 2 diabetes confirmed by blood tests, without dementia at baseline. Following participants for up to 14 years, 216 (17.8%) developed dementia based on follow-up telephone interviews.
The researchers found that adults diagnosed with type 2 diabetes at younger ages were at increased risk for developing dementia, compared to those diagnosed at 70 years or older. Adults diagnosed with diabetes before age 50 were 1.9 times as likely to develop dementia as those diagnosed at 70 and older, while those diagnosed between 50–59 years were 1.72 times as likely and those diagnosed between 60–69 years were 1.7 times as likely.
Using linear trend tests, the researchers found a graded association between age at diagnosis and dementia risk: for each year younger a person is at the time of their type 2 diabetes diagnosis, their risk for developing dementia increases by 1.9%.
“While we do not know for sure why an earlier diabetes diagnosis would increase the risk for dementia, prior studies show that people diagnosed with type 2 diabetes in mid-life may experience more vascular complications, poor blood sugar control, and insulin resistance – all of which are known risk factors for cognitive impairment,” said Bei Wu, the Dean’s Professor in Global Health and vice dean for research at NYU Meyers and the study’s senior author.
In addition, obesity appeared to influence the relationship between type 2 diabetes and dementia. Individuals with obesity who were diagnosed with type 2 diabetes before age 50 had the highest dementia risk in the study.
The researchers note that this greater understanding of the connection between diabetes onset, obesity, and dementia may help inform targeted interventions to prevent dementia.
“Our study highlights the importance of one’s age at diabetes diagnosis and suggests that specifically targeting obesity – whether through diet and exercise or perhaps medication – may play a role in staving off dementia in younger adults with diabetes,” said Wu.
The question of what causes complex neurological diseases such as Alzheimer’s or multiple sclerosis continues to confound scientists and doctors, with the unknowns standing in the way of early diagnoses and effective treatments.
Even among identical twins who share the same genetic risk factors, one may develop a particular neurological disease while the other does not.
That’s because unlike diseases such as cystic fibrosis or sickle-cell anaemia, which are caused by a single gene, most neurological disorders are associated with many, sometimes hundreds, of rare genetic variants. And on their own, these variants can’t predict who will develop disease, as neurological conditions are also strongly influenced by environmental factors and vascular risks such as high blood pressure, aging, heart disease, or obesity.
But there’s one often-overlooked thread that connects most neurological diseases, says Katerina Akassoglou, PhD, a senior investigator at Gladstone Institutes: They’re marked by a toxic immune reaction caused by blood that leaks into the brain through damaged blood vessels.
“Interactions between the brain, blood vessels, and the immune system are a common thread in the development and progression of many neurological diseases that have been traditionally viewed as very different conditions,” says Akassoglou. “Knowing that leaked blood is a key driver of brain inflammation, we can now approach these diseases from a different angle.”
She and her collaborators share their insights on this topic in a commentary article published in Cell’s 50th anniversary “Focus on Neuroscience” issue.
Neutralising the Culprit
Akassoglou and her lab have long investigated how blood that leaks into the brain triggers neurologic diseases, essentially by hijacking the brain’s immune system and setting off a cascade of harmful often-irreversible effects that result in damaged neurons.
One blood protein in particular, fibrin, normally involved in blood coagulation, is responsible for setting off this detrimental cascade. The process has been observed in conditions as diverse as Alzheimer’s, traumatic brain injury, multiple sclerosis, premature birth, and even COVID-19. However, Akassoglou and her team found that the process could be prevented or interrupted by “neutralising” fibrin to deactivate its toxic properties – an approach that appears to protect against many neurological diseases when tested in animal models.
“As a first step, we know that neutralizing fibrin reduces the burden posed by vascular dysfunction,” Akassoglou says. Regardless of what initially caused the blood leaks, be it a head injury, autoimmunity, genetic mutations, brain amyloid or infection, neutralizing fibrin appears to be protective in multiple animal models of disease.
The scientists previously developed a drug, a therapeutic monoclonal antibody, that specifically targets fibrin’s inflammatory properties without affecting its essential role in blood coagulation. This fibrin-targeting immunotherapy has shown, in mice, to protect from multiple sclerosis and Alzheimer’s, and to treat neurological effects of COVID-19. A humanized version of this first-in-class fibrin immunotherapy is already in Phase 1 safety clinical trials by Therini Bio, a biotech company launched to advance discoveries from Akassoglou’s lab.
A New Era of Brain Research
In the Cell commentary, Akassoglou and her colleagues make the case that seemingly disparate neurological diseases must be viewed differently in light of new research on the blood-brain-immune interface.
They say that in the coming decade, scientific breakthroughs will emerge from collaborative networks of immunologists, neuroscientists, haematologists, geneticists, computer scientists, physicists, bioengineers, drug developers, and clinical researchers. These partnerships, forged across academia, industry, and foundations, will catalyse innovation in drug discovery and transform medical practice for neurological diseases.
“This is a new opportunity for drug discovery that goes beyond addressing genes alone or environmental factors alone,” Akassoglou says. “To usher in this new era, we must leverage new technologies and embrace an interdisciplinary approach that accounts for the important roles of immune and vascular systems in neurodegeneration.”
Over 30% of older adults take five or more medications daily, which is termed polypharmacy. It is associated with poor health outcomes like falls, medication interactions, hospitalisations and even death. Multiple chronic conditions in older adults increases the risk of polypharmacy. While polypharmacy is more common in older adults with Alzheimer’s disease and related dementias, there is little research examining the impact on symptoms, health outcomes and physical function.
Researchers from Drexel University’s College of Nursing and Health Professions recently published a study in Biological Research For Nursing examining symptoms, health outcomes and physical function over time in older adults with and without Alzheimer’s disease and related dementias and polypharmacy.
Led by Martha Coates, PhD, the research team found that individuals who are experiencing polypharmacy and have Alzheimer’s disease and related dementias experience more symptoms, falls, hospitalisations, mortality and had lower physical function – indicating that polypharmacy can also negatively impact quality of life for older adults with Alzheimer’s disease and related dementias.
“The cut-off of point of five or more medications daily has been associated with adverse health outcomes in previous research, and as the number of medications increase the risk of adverse drug events and harm increases,” said Coates.
The research team used a publicly available dataset from the National Health and Aging Trends Study – a nationally representative sample of Medicare beneficiaries in the United States from Johns Hopkins University. Since 2011, data is collected yearly to examine social, physical, technological and functional domains that are important in aging.
For this study, the research team used data from 2016 through 2019 to compare changes in symptoms, health outcomes and physical function among four groups: 1) those with Alzheimer’s disease and related dementias and polypharmacy; 2) those with Alzheimer’s disease and related dementias only; 3) those with polypharmacy only; and 4) those without either Alzheimer’s disease and related dementias or polypharmacy.
Coates explained that the researchers used analytic weights to analyse the data, which generates national estimates, making the sample of 2052 individuals representative of 12 million Medicare beneficiaries in the US, increasing the generalisability of the findings.
“We found that older adults with Alzheimer’s disease and related dementias and polypharmacy experienced more unpleasant symptoms, increased odds of falling, being hospitalised and mortality compared to those without Alzheimer’s disease and related dementias and polypharmacy,” said Coates. “They also experienced more functional decline, required more assistance with activities of daily living like eating, bathing and dressing, and were more likely to need an assistive device like a cane or walker.”
Coates noted that there are tools available to help health care providers review and manage medication regimens for older adults experiencing polypharmacy and possibly taking medications that are potentially inappropriate or no longer provide benefit. However, currently there are no specific tools like that for older adults with Alzheimer’s disease and related dementias.
The findings from this research shed light on the negative impact polypharmacy can have on older adults with Alzheimer’s disease and related dementias. But Coates added that further research is needed to develop strategies to reduce the occurrence of polypharmacy in people with Alzheimer’s disease and related dementias.
The research team anticipates this study will help guide future analysis of the impact of specific medications on health outcomes in individuals with Alzheimer’s disease and related dementias and that it provides a foundation to support intervention development for medication optimisation in older adults with Alzheimer’s disease and related dementias and polypharmacy.
The treatment of certain neurodegenerative diseases and the pages of neuroscience textbooks may soon be in need of a major update. A research team has discovered that a molecule in the brain – ophthalmic acid – unexpectedly acts like a neurotransmitter similar to dopamine in regulating motor function, offering a new therapeutic target for Parkinson’s and other movement diseases.
As reported in the journal Brain, researchers observed that ophthalmic acid binds to and activates calcium-sensing receptors in the brain, reversing the movement impairments of Parkinson’s mouse models for more than 20 hours.
Parkinson’s disease (PD) symptoms, which include tremors, shaking and lack of movement, are caused by decreasing levels of dopamine in the brain as those neurons die. L-dopa, the front-line drug for treatment, acts by replacing the lost dopamine and has a duration of two to three hours. While initially successful, the effect of L-dopa fades over time, and its long-term use leads to dyskinesia – involuntary, erratic muscle movements in the patient’s face, arms, legs and torso.
“Our findings present a groundbreaking discovery that possibly opens a new door in neuroscience by challenging the more-than-60-year-old view that dopamine is the exclusive neurotransmitter in motor function control,” said co-corresponding author Amal Alachkar, School of Pharmacy & Pharmaceutical Sciences professor. “Remarkably, ophthalmic acid not only enabled movement, but also far surpassed L-dopa in sustaining positive effects. The identification of the ophthalmic acid-calcium-sensing receptor pathway, a previously unrecognised system, opens up promising new avenues for movement disorder research and therapeutic interventions, especially for Parkinson’s disease patients.”
Alachkar began her investigation into the complexities of motor function beyond the confines of dopamine more than two decades ago, when she observed robust motor activity in Parkinson’s mouse models without dopamine. In this study, the team conducted comprehensive metabolic examinations of hundreds of brain molecules to identify which are associated with motor activity in the absence of dopamine. After thorough behavioural, biochemical and pharmacological analyses, ophthalmic acid was confirmed as an alternative neurotransmitter.
“One of the critical hurdles in Parkinson’s treatment is the inability of neurotransmitters to cross the blood-brain barrier, which is why L-DOPA is administered to patients to be converted to dopamine in the brain,” Alachkar said. “We are now developing products that either release ophthalmic acid in the brain or enhance the brain’s ability to synthesise it as we continue to explore the full neurological function of this molecule.”
Almost 3 million people worldwide have multiple sclerosis (MS) – an autoimmune disease caused by the immune system mistakenly attacking the brain and central nervous system.
While treatments for MS have improved over the years, there’s still no cure. This is largely because researchers still don’t fully understand what goes wrong in the immune system to cause MS. But our latest research has revealed new insights into the way certain immune cells behave in people with MS. This discovery brings us closer to understanding why some people get MS – and may also be a crucial step in developing better treatments and even cures.
EBV typically infects people during childhood without causing any symptoms – so most early infections go unnoticed. But if the infection occurs during adolescence, it may cause glandular fever (infectious mononucleosis) which, although debilitating in the short-term, usually has no long-term effects.
Most viral infections are rapidly cleared by the body’s immune system, but EBV is cleverer than most viruses. Although the immune system controls the infection, it is unable to completely eradicate the virus as it hides inside a type of immune cell called a B cell (which normally produce antibodies that bind to and destroy invading viruses or bacteria). Once you’re infected with EBV you carry it for life – although for most people this causes no problems.
By adulthood about 95% of people are infected with EBV, but in people with MS nearly 100% are infected. Large epidemiological studies have shown that EBV infection increases the risk of developing MS over 30-fold. For people who have had glandular fever the risk is even higher. Research has also shown that in people with MS, EBV infection occurs before the very earliest stages of disease.
Many researchers now believe being infected with EBV is more than a risk factor in MS – it’s essential.
But how does EBV cause MS – and why does a common virus only cause MS in a few people? Several theories are currently being investigated.
One theory is that in some people the immune cells activated by EBV mistakenly attack parts of the brain and central nervous system. This process, called molecular mimicry, also occurs in other autoimmune diseases, such as Guillain-Barré syndrome. This could explain why drugs which prevent immune cells from entering the brain are shown to dramatically improve MS symptoms.
Research into EBV molecular mimicry in MS has mainly focused on the viral protein EBNA1. Without EBNA1 EBV cannot live in B cells, and MS patients have higher levels of antibodies towards EBNA1.
But EBV makes over 80 different proteins during its life cycle. In our latest work we investigated immune responses to these other viral proteins in people with MS.
Altered immunity
We compared the immune responses of 31 people with MS, 33 healthy people and 11 people who had recently recovered from glandular fever. We wanted to see if each group reacted to EBV infections differently.
We found that antibodies targeting EBNA1 and another viral protein called VCA were higher in people with MS compared to the other groups. People with MS were also more likely to have antibodies targeting several other viral proteins. This suggests EBV antibodies are more altered in MS than previously thought – but it isn’t certain whether these antibodies are fighting infection or if they have a role in MS disease.
Antibodies aren’t the full story. Previous research has suggested another type of immune cell, called a T cell, may also play an important role as they’re found in high numbers in MS brain lesions. As such, we wanted to understand whether T cells which fight EBV were different in people with MS.
By analysing blood samples we found that, although EBV T cell numbers were similar in MS and healthy people, these cells behaved differently in people with MS. T cells from people with MS produced slightly higher amounts of an inflammatory substance called interleukin-2. The body normally produces this substance in response to injury or infection, but too much interleukin-2 can cause chronic disease.
We also looked at molecular mimicry, wondering whether EBV T-cells mistakenly target brain proteins rather than fighting the virus.
Surprisingly, we found that in both people with MS and healthy people, their EBV T cells reacted to multiple proteins found in the brain. Notably, most people had EBV T cells that targeted a protein called myelin oligodendrocyte glycoprotein, or Mog, which surrounds the nerves.
Looking at one person with MS in more detail, we found individual T cells that directly recognised both EBNA1 and Mog. This means that, rather than just fighting infection, some EBV T cells could also target nerve cells in the brain.
This widespread misdirection between EBV T cells and the brain goes some way to suggest how infection with this common virus can lead to MS. But its presence in healthy people is slightly confusing. One possible explanation could be that EBV T cells are better able to cross the blood-brain barrier (a tight-knit lining of cells that protect the brain) in people with MS. This idea is something we’re keen to explore in future research.
While there’s still much we don’t know about these misdirected EBV T cells in the brain, our latest findings provide fresh evidence for researchers and hopefully will lead to the development of new, targeted treatments for MS.
Alzheimer’s disease may damage the brain in two distinct phases, based on new research funded by the National Institutes of Health (NIH) using sophisticated brain mapping tools. According to researchers who discovered this new view, the first, early phase happens slowly and silently – before people experience memory problems – harming just a few vulnerable cell types. In contrast, the second, late phase causes damage that is more widely destructive and coincides with the appearance of symptoms and the rapid accumulation of plaques, tangles, and other Alzheimer’s hallmarks.
“One of the challenges to diagnosing and treating Alzheimer’s is that much of the damage to the brain happens well before symptoms occur. The ability to detect these early changes means that, for the first time, we can see what is happening to a person’s brain during the earliest periods of the disease,” said Richard J. Hodes, MD, director, NIH National Institute on Aging. “The results fundamentally alter scientists’ understanding of how Alzheimer’s harms the brain and will guide the development of new treatments for this devastating disorder.”
Scientists analysed the brains of 84 people, and the results, published in Nature Neuroscience, suggest that damage to one type of cell, called an inhibitory neuron, during the early phase may trigger the neural circuit problems that underlie the disease. Additionally, the study confirmed previous findings about how Alzheimer’s damages the brain and identified many new changes that may happen during the disease.
Specifically, the scientists used advanced genetic analysis tools to study the cells of the middle temporal gyrus, a part of the brain that controls language, memory and vision. The gyrus has been shown to be vulnerable to many of the changes traditionally seen during Alzheimer’s. It is also a part of the brain that researchers have thoroughly mapped for control donors. By comparing control donor data with that from people who had Alzheimer’s, the scientists created a genetic and cellular timeline of what happens throughout the disease.
Traditionally, studies have suggested that the damage caused by Alzheimer’s happens in several stages characterized by increasing levels of cell death, inflammation and the accumulation of proteins in the form of plaques and tangles. In contrast, this study suggests that the disease changes the brain in two “epochs” – or phases – with many of the traditionally studied changes happening rapidly during the second phase. This coincides with the appearance of memory problems and other symptoms.
The results also suggest that the earliest changes happen gradually and “quietly” in the first phase before any symptoms appear. These changes include slow accumulation of plaques, activation of the brain’s immune system, damage to the cellular insulation that helps neurons send signals and the death of cells called somatostatin (SST) inhibitory neurons.
The last finding was surprising to the researchers. Traditionally, scientists have thought that Alzheimer’s primarily damages excitatory neurons, which send activating neural signals to other cells. Inhibitory neurons send calming signals to other cells. The paper’s authors hypothesised how loss of SST inhibitory neurons might trigger the changes to the brain’s neural circuitry that underlie the disease.
Recently, a separate NIH-funded brain mapping study by researchers at MIT found that a gene called REELIN may be associated with the vulnerability of some neurons to Alzheimer’s. It also showed that star-shaped brain cells called astrocytes may provide resilience to or resist the harm caused by the disease.
Researchers analysed brains that are part of the Seattle Alzheimer’s Disease Brain Cell Atlas, which is designed to create a highly detailed map of the brain damage that occurs during the disease. The project was led by Mariano I. Gabitto, PhD, and Kyle J. Travaglini, PhD, from the Allen Institute, Seattle. The scientists used tools – developed as part of the NIH’s BRAIN Initiative – Cell Census Network – to study more than 3.4 million brain cells from donors who died at various stages of Alzheimer’s disease.
“This research demonstrates how powerful new technologies provided by the NIH’s BRAIN Initiative are changing the way we understand diseases like Alzheimer’s. With these tools, scientists were able to detect the earliest cellular changes to the brain to create a more complete picture of what happens over the entire course of the disease,” said John Ngai, Ph.D., director of The BRAIN Initiative®. “The new knowledge provided by this study may help scientists and drug developers around the world develop diagnostics and treatments targeted to specific stages of Alzheimer’s and other dementias.”
A new study has found some cancers to be slightly more frequent in people with multiple sclerosis (MS) than in people without MS. The study is published online in Neurology®, the medical journal of the American Academy of Neurology. Types of cancers found to have a small increased risk include bladder, brain and cervical cancers.
“People with MS undergo an increased number of tests to monitor MS, making it more likely to detect other diseases,” said study author Emmanuelle Leray, PhD, of Rennes University in France. “We found an association between some types of cancer and MS which may have different explanations depending on a person’s age and the types of cancer. Overall, our study found the increased risk of cancer was quite small.”
For the study, researchers reviewed 10 years of data in the French national health care database. Researchers identified 140 649 people with MS and matched them for factors such as age, sex and residence to 562 596 people without MS. All participants were cancer free three years before the study. They were followed for an average of eight years.
During the study, 8,368 people with MS and 31,796 people without MS developed cancer.
Researchers determined there were 799 cancers per 100 000 person-years for people with MS and 736 cancers per 100 000 person-years for people without MS. Person-years represent both the number of people in the study and the amount of time each person spends in the study.
Researchers found people with MS had a 6% increased risk of developing any type of cancer regardless of age, sex and residence. They also found cancer risk was higher in those under 55 and lower in people 65 and older when compared to people without MS.
Researchers then looked at cancer types. People with MS had a 71% increased risk for bladder cancer, a 68% increased risk for brain cancer and a 24% increased risk for cervical cancer. However, they also had a 20% lower risk of prostate cancer, a 10% lower risk of colorectal cancer and a 9% lower risk of breast cancer.
“While our study found a higher risk for brain cancer, it may be due in part to earlier detection in those with MS since they regularly have brain scans which may detect cancers earlier, before a person has symptoms,” said Leray. “Frequent urinary tract infections in people with MS and the use of immunosuppressant drugs may contribute to their higher risk of bladder and cervical cancers.”
Leray added, “The lower risk for colorectal and breast cancers may be due in part to fewer people with MS getting screened for cancer in older age when they may be experiencing more MS symptoms. More research is needed, including studies that look at more closely at how cancer screenings may play a role.”
A limitation of the study was that researchers were unable to adjust for factors such as education, income, smoking and alcohol consumption since this information was not available in the national database.
Researchers from have found a potential new way to improve the treatment of multiple sclerosis (MS) using a novel combined therapy. The results, published in the Journal of Clinical Investigation, builds on two harmonised Phase I clinical trials, focusing on the use of Vitamin D3 tolerogenic dendritic cells (VitD3-tolDCs) to regulate the immune response in MS patient.
Multiple Sclerosis (MS) is a long-term disease where the immune system mistakenly attacks the protective myelin sheath around nerve cells. This leads to nerve damage and worsening disability. Current treatments, like immunosuppressants, help reduce these harmful attacks but also weaken the overall immune system, leaving patients vulnerable to infections and cancer. Scientists are now exploring a more targeted therapy using special immune cells, called tolerogenic dendritic cells (tolDCs), from the same patients.
TolDCs can restore immune balance without affecting the body’s natural defences. However, since a hallmark of MS is precisely the dysfunction of the immune system, the effectiveness of these cells for auto transplantation might be compromised. Therefore, it is essential to better understand how the disease affects the starting material for this cellular therapy before it can be applied.
In this study, researchers from Barcelona’s Germans Trias i Pujol Institute and Josep Carreras Leukaemia Research Institute, examined CD14+ monocytes, mature dendritic cells (mDCs), and Vitamin D3-treated tolerogenic dendritic cells (VitD3-tolDCs) from MS patients who had not yet received treatment, as well as from healthy individuals. The clinical trials (NCT02618902 and NCT02903537) are designed to assess the effectiveness of VitD3-tolDCs, which are loaded with myelin antigens to help “teach” the immune system to stop attacking the nervous system. This approach is groundbreaking as it uses a patient’s own immune cells, modified to induce immune tolerance, in an effort to treat the autoimmune nature of MS.
The study, led by Dr Eva Martinez-Cáceres and Dr Esteban Ballestar, with Federico Fondelli as first author, found that the immune cells from MS patients (monocytes, precursors of tolDCs) have a persistent “pro-inflammatory” signature, even after being transformed into VitD3-tolDCs, the actual therapeutic cell type. This signature makes these cells less effective compared to those derived from healthy individuals, missing part of its potential benefits.
Using state-of-the-art research methodologies, the researchers identified a pathway, known as the Aryl Hydrocarbon Receptor (AhR), that is linked to this altered immune response. By using an AhR-modulating drug, the team was able to restore the normal function of VitD3-tolDCs from MS patients, in vitro. Interestingly, Dimethyl Fumarate, an already approved MS drug, was found to mimic the effect of AhR modulation and restore the cells’ full efficacy, with a safer toxic profile.
Finally, studies in MS animal models showed that a combination of VitD3-tolDCs and Dimethyl Fumarate led to better results than using either treatment on its own. This combination therapy significantly reduced symptoms in mice, suggesting enhanced potential for treating human patients.
These results could lead to a new, more potent treatment option for multiple sclerosis, offering hope to the millions of patients worldwide who suffer from this debilitating disease. This study represents a significant step forward in the use of personalised cell therapies for autoimmune diseases, potentially revolutionising how multiple sclerosis is treated.
The team is now preparing to move into Phase II trials to further explore these findings.