<![CDATA[Newsroom University of Manchester]]> /about/news/ en Sun, 22 Dec 2024 17:44:57 +0100 Tue, 17 Oct 2023 09:18:31 +0200 <![CDATA[Newsroom University of Manchester]]> https://content.presspage.com/clients/150_1369.jpg /about/news/ 144 Novel blood test identifies biomarkers in patients with Alzheimer’s Disease /about/news/novel-blood-test-identifies-biomarkers-in-patients-with-alzheimers-disease/ /about/news/novel-blood-test-identifies-biomarkers-in-patients-with-alzheimers-disease/60138791ֱ confirms ALZmetrixTM whole blood test can detect people at high risk of developing full Alzheimer’s DiseaseEarly results from PharmaKure, a pharmaceutical company spun out from The University of Manchester, shows a novel whole blood test developed by the company is able to quantify Alzheimer’s Disease biomarkers. PharmaKure’s proprietary can, they find, identify blood-based biomarkers in patients with Alzheimer’s Disease to provide early warning of cognitive decline. The company will undertake a larger study in which an independent laboratory will be used to validate the results before obtaining regulatory clearance for rolling out the test.

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Early results from PharmaKure, a pharmaceutical company spun out from The University of Manchester, shows a novel whole blood test developed by the company is able to quantify Alzheimer’s Disease biomarkers. PharmaKure’s proprietary can, they find, identify blood-based biomarkers in patients with Alzheimer’s Disease to provide early warning of cognitive decline. The company will undertake a larger study in which an independent laboratory will be used to validate the results before obtaining regulatory clearance for rolling out the test.

The ethics approved clinical trial, carried out in a blinded study was designed to focus on the testing of whole blood. A number of biomarkers were accessed for the stratification of Alzheimer’s subjects who had previously been tested for amyloid deposits, using either brain PET imaging or cerebrospinal fluid (CSF). Levels of biomarker proteins were measured in blood from patients at the earliest stages of Alzheimer’s Disease. The study investigated whether it is possible to accurately determine whether a patient had amyloid deposits in their brains, as well as predicting how far they had progressed along the path towards full Alzheimer’s Disease. A simple blood test such as ALZmetrix may offer an accurate and simple alternative to costly and unpleasant PET brain imaging or collection of CSF.

Blood from 54 subjects at the Glasgow Memory Clinic (Neuroclin; Motherwell, UK) was shipped to PharmaKure (91ֱ, UK) for analysis. Key biomarker proteins associated with Alzheimer’s Disease pathology are amyloid-β (Total, Aβ40 and Aβ42), α-synuclein and Tau (Total, pTAU(181) and pTAU(217)). The study evaluated the relationship of aggregated forms of these proteins in patient blood, compared to PET scans and CSF findings.  Machine learning tools were used to combine the blood biomarker and patient data (age; gender; amyloid status; ApoE4 genetics) in an optimal way to develop predictors.

The study’s results confirm that using whole blood, rather than just the blood plasma fraction, can identify people who are at high risk of developing full-blown Alzheimer’s disease. In addition, the machine learning software shows which biomarkers are most useful for this purpose.

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“We are particularly pleased to find that our ALZmetrix blood test can differentiate between patient groups that are amyloid positive or amyloid negative with 97% accuracy to predict those at highest risk of Alzheimer’s Disease,” said Professor Andrew Doig, Head of R&D at PharmaKure and researcher at The University of Manchester. “Age, APOE4 and pTau are the most useful features in the prediction. We have also shown that blood can track disease progression, primarily using levels of Tau and pTau.”

“These results represent an important step in developing whole blood tests to address a major unmet need for an alternative to PET and CSF scans”, said Dr Farid Khan, CEO at PharmaKure Limited. “This study has demonstrated how to get early warning signs of cognitive decline using whole blood. We will be using the exciting data to expand our ALZmetrix test to additional patients and new biomarkers.”

“Using the ALZmetrix test for Alzheimer’s could provide a low cost, easily accessible test for stratifying patients for clinical studies, as an alternative to expensive brain scans or other plasma-based tests,” said Dr Bob Smith, Clinical Director at PharmaKure.

One of the key advantages of using whole blood is that it may enable the development of a screening system to catch Alzheimer’s before any major memory problems become apparent. This would allow treatments to be offered earlier, thus providing better population-based health outcomes, lowering health system costs and improving the quality of life of millions of patients.

Though the scientific team will be publishing the results a journal in the next few months, they feel it is in the public interest to disseminate the result as soon as possible as there are no tests available to diagnose the early stages of the disease.

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Tue, 17 Oct 2023 13:22:00 +0100 https://content.presspage.com/uploads/1369/d28219b9-2056-45dd-ac64-6b0cd5d28e01/500_2301pkl17oct-pharmakureannouncesstudysuccessforalzheimerrsquosdiseasebloodtest.jpeg?10000 https://content.presspage.com/uploads/1369/d28219b9-2056-45dd-ac64-6b0cd5d28e01/2301pkl17oct-pharmakureannouncesstudysuccessforalzheimerrsquosdiseasebloodtest.jpeg?10000
My work investigating the links between viruses and Alzheimer’s disease was dismissed for years – but now the evidence is building /about/news/my-work-investigating-the-links-between-viruses-and-alzheimers-disease-was-dismissed-for-years--but-now-the-evidence-is-building/ /about/news/my-work-investigating-the-links-between-viruses-and-alzheimers-disease-was-dismissed-for-years--but-now-the-evidence-is-building/547789This article is part of the Insights Uncharted Brain series. There are many competing theories about what causes Alzheimer’s disease. Here, Ruth Itzhaki reflects on a career dedicated to one of the more controversial lines of research.

When I was about seven or eight, I asserted that I wanted to be a scientist, or so my parents told me years later, even though I would have had little idea of what that word meant. In my mind, I was perhaps associating it with making momentous discoveries that were immediately recognised and applauded by the whole world. Soon after, I avidly read , the book by Eve Curie about her mother Marie and how she overcame poverty and the many challenges faced by women in the late 19th and early 20th century to become a Nobel prize-winning scientist. Marie Curie became my lodestar for the future and thanks to my parents’ support and self-sacrifice, I did eventually become a scientist.

Marie Curie won two Nobel Prizes in 1903 for Physics and in 1911 for Chemistry.

Many years later, I found myself confronting what seemed like insuperable odds just as Curie did, though in very different circumstances. I have been an independent researcher since the age of 26 when I completed my PhD. My subsequent research in a Cambridge University department on (a complex of DNA and proteins) went well. Then, after eight years, my husband and I moved to 91ֱ where the head of the institute where I worked for 12 years decided to end my contract, leaving me jobless and lab-less.

In the decades that followed, my research into viruses as a possible cause of Alzheimer’s disease was greeted with much hostility, and almost all my funding applications were refused: a hostility that has continued for 25 years and which has only recently abated, thanks to .

 

I, along with my tiny research group, survived only through the award of a few small grants from more open-minded charities and companies interested in new approaches. Once I even managed to swap a business class ticket to the US (that was provided for me to speak at a conference) for economy class, so I could use the several thousand-dollar surplus for my lab instead.

But, after years of struggle, there is finally hope for this line of research. An for Alzheimer’s – the first ever – is now taking place at Columbia University. This study is building on the years of work done by my team. Meanwhile, our is looking into the way infectious illnesses increase the risk of Alzheimer’s.

Dementia brought home

Career and academic challenges can always be balanced with the help of a support network: a family. I was always lucky with mine. During many of these years, my husband, Shaul Itzhaki, a retired academic who had worked on nucleic acid biochemistry, supported my struggles and never once suggested that I change to a safer, more conventional and non-contentious topic. He was always touchingly happy with any successes I had, and I will always remember our celebratory days when I was awarded a for Medical Research, and later a Newnham College Fellowship, during our years in Cambridge.

Sadly, he died in April 2022, after suffering for about ten years from vascular dementia (a dementia distinct from Alzheimer’s disease but with many similar symptoms) and latterly, from a fractured femur that disabled him. The last four or so years were particularly hard to endure as he became increasingly aware of his failing memory. The term “brain fog” is often used in this context, but to me, it seemed more like a mist through which he could very dimly see or perceive what he was struggling to recall; the frustration – desperation, perhaps – that he felt at his inability to grasp, hold, then voice these elusive thoughts was pitiful.

The author in her laboratory. Author provided

I often took him to talks on topics such as the climate, migration, history and ageing, hoping to keep his mind occupied. He seemed to understand many of them, but afterwards, he was quite unable to discuss them, as his memory and ability to speak were declining inexorably. Communication of any type between us was slowly becoming impossible, although he was the person with whom I had once shared my thoughts and hopes, just as he had done with me, and it became particularly sad and unsettling, as we had had so many interests in common. Eventually came the realisation that I had “lost” him. It was a bereavement – the loss of him as a person, loss of a mind, not the death of a body; he was existing but not really living.

Another common feature of dementia – sudden changes of mood – affected him during these years. He had been a generally gentle, courteous person. But when, at times, the illness overcame his natural traits, he became violently angry, often for no obvious reason. Part of the problem was that his sense of location had faltered and often during the evenings he became convinced that we were about to leave and go “home” to 91ֱ, a place we had left in 2013. He would ask repeatedly and anxiously when we had to leave to catch the train to get there. Television programmes, even those on historical events, which would have been of particular interest to him, had to be vetted as he lost himself within them. So that after watching one that dealt with, say, the horrors of war, he thought that he was actually living in that frightening world.

Of course, there are so many families going through what my family went through. And there will be many more. That fact has provided one of the main motives for my pursuing my research, despite all the difficulties that have come with it.

Early challenges

During the last five years, studies supporting the idea of a viral role in Alzheimer’s disease have . Despite this, there is still much opposition to the concept, while many in the field still ignore it.

I am often asked why there has been such hostility. A charitable explanation is that the possible role of a virus in dementia is difficult for others to assess because it straddles two very different topics: virology and Alzheimer’s disease. Also, many cannot grasp the concept that people can be infected but not affected (asymptomatic, when the virus resides in the brain without causing symptoms) so they dismiss the data. Either way, I have always stressed that many possible factors lead to Alzheimer’s disease – a viral role is just one of them.

My interest in this particular area began, rather unpromisingly, in 1978 when the aforementioned head of institute ended my work contract. The reason he cited was that my research on chromatin, and on the effects of carcinogens on chromatin, was “rather individualistic”. I thought this was an extraordinarily inept criticism, as I had generally been acknowledged as being an innovative researcher, and innovation is surely the key to good research. The funding body offered me a post in Glasgow, but that would have meant leaving my husband and children in 91ֱ.

Luckily, I was immediately given a home in the lab of a medical virologist friend, Richard Sutton. Sutton was an eccentric and pioneering man. He was dogged and wiley, in an endearing way. It was Sutton who first suggested to me the possibility of viral involvement in Alzheimer’s disease.

The argument for the role of the cold sore virus, herpes simplex type 1 (HSV1), in Alzheimer’s disease was first suggested by American neuropathologist in 1984. But he did not pursue the idea in any practical way. Sutton and I carried out what was probably the first convincing experiment seeking the DNA of HSV1 in the human brain. We had predicted that it might be detectable in the brain of immunosuppressed patients because in the absence of an adequate immune system to keep it under control, the virus would be able to multiply. We did indeed find it, and published our in 1986.

The central concept

is mainly transmitted by oral-to-oral contact, causing oral herpes (cold sores). Globally, an estimated 3.7 billion people under age 50 (67%) have HSV1 infection. Most infections are asymptomatic.

Over the years, the supportive data we gathered for the key role of HSV1 in Alzheimer’s led me to propose a central concept: that HSV1 is a major cause of Alzheimer’s disease; that in many people, the virus travels to the brain, probably in middle age, and remains present there in latent (dormant) form, but is frequently activated by episodes of stress, head injury, immuno- suppression and infections. These “reactivations” lead to productive HSV1 infection and inflammation (and consequent damage to the brain) over the years. The accumulated damage leads eventually to the development of the disease.

The possible role of HSV1, specifically, was proposed for three main reasons. The locations of the damage the virus causes in the brain during the rare but extremely serious acute disease herpes simplex encephalitis (HSE) – caused by HSV1 – are precisely the main sites of damage found in the brains of patients with Alzheimer’s disease.

The other reasons for implicating HSV1 were that it is very common, affecting of the population (in earlier decades more probably 90%), and its ability to remain dormant in the body for years.

These features meet two main characteristics of Alzheimer’s disease: that it is all too common, and that it almost always waits until old age to strike its victims. Certain other infectious agents are probably involved too, perhaps individually or in combination, but so far these have been less well studied than HSV1.

The laboratory work

I was offered a more long-term prospect for my research in a department of the University of Manchester’s Institute of Science and Technology. The head of the department, John Cronley Dillon, was a larger-than-life character, a bon viveur and art lover, full of novel ideas and wild enthusiasm. He encouraged me to build up a research group (minuscule though it was) and eventually we started the research on HSV1 and Alzheimer’s.

It was known that when a person is infected with HSV1, the virus resides lifelong in the peripheral nervous system (PNS) – the part of the nervous system that doesn’t include the brain and the spinal cord — in a latent state. It is dormant until it is activated by events such as stress. In 1989 we decided to look for HSV1 in the brain, using the technique of polymerase chain reaction, or PCR. We used to examine DNA extracted from autopsy specimens of Alzheimer’s disease patients.

This was the first time PCR, then a new technique, had been used for this purpose. The principle of PCR is to detect a specific sequence in the target DNA by chemically amplifying it, thereby making it vastly more sensitive than the methods used in the previous few studies seeking HSV1 DNA in the brain. However, this method was prone to contamination and could produce spurious data. This meant that my poor PhD student, Gordon Jamieson, spent many frustrating months trying to get it to work satisfactorily. So we were overjoyed when , unambiguously, the DNA of the virus in the brain in 1991.

This was the first microbe to be detected in the human brain (in controls, in the absence of a disease). We were puzzled, though, as to why the virus was present in a high proportion of brains – both control brain specimens (people who had not been diagnosed with Alzheimer’s) as well as the brains of patients who had died with the disease. This near equality of prevalence does not undermine the role of HSV1 in Alzheimer’s, as some in the field have asserted. Many of the control brains were, in fact, infected with HSV1 but were asymptomatic.

So people can be infected but be asymptomatic, indicating that infection alone is not sufficient to cause disease. A very relevant example is that of cold sores which afflict only a proportion (ranging from 20-40%) of those infected with HSV1. The other 60-80% are asymptomatic. Clearly, another factor determines the degree of damage caused by the virus.

Other supporting factors

That was something we identified in 1997 when that the virus confers a high risk of Alzheimer’s disease when in the brains of people who carry a specific genetic factor. We were extremely excited by this finding, but also apprehensive about adverse reactions of some in the field, as had occurred before when we discovered HSV1 DNA in elderly brains.

So we were even more excited when, after I’d suggested examining cold sore sufferers (via a small blood sample), to find what variant of the specific genetic factor they carried, we discovered that it was the same variant as for Alzheimer’s. In other words, the same variant of the genetic factor conferred a risk of damage in the peripheral nervous system, as well as the central nervous system.

Of course, the question arose as to what it is doing, if anything, in the brain. Is it residing there merely as a passenger, doing little or nothing, or does it cause damage?

We by examining cerebrospinal fluid (the liquid that bathes the brain) looking for antibodies to the virus. We detected these antibodies in most samples of cerebrospinal fluid, again, consistently, in both Alzheimer’s patients and those in the age-matched control groups. This showed that indeed the virus was not just a passive fellow traveller.

We then decided to find if there were direct links between the effects of HSV1 infection and Alzheimer’s. Very hesitantly, like explorers in a new continent, we infected human brain cells with HSV1, then stained the cells with antibodies to the specific abnormal proteins seen in Alzheimer’s brains – and .

To our surprise and delight we saw accumulations of both types of protein. Also, we found amyloid deposition in the brains of infected mice. However, getting the results published was a Sisyphean task and journal reviewers’ comments were often incredulous.

We subsequently used a very complex technique (in-situ PCR) which revealed that in tissue sections of brain, most of the viral DNA was located very specifically within amyloid plaques. This suggested that amyloid might act to cage the virus, thereby inactivating it. All this work provided strong support for a major role of HSV1 in Alzheimer’s, and much has since been extended by .

that anti-herpes treatment was protective because it substantially reduced the damage level in the cell cultures we were testing. This further supported a role for the virus in the disease – and pointed to a potential treatment.

A heretic shunned

But a viral role in the development of Alzheimer’s was still seen as heretical by many researchers, so our papers continued to be rejected by one journal after another.

For academics, having research published in top journals is often central to keeping your job and career progression because of the perceived value to universities (related to university league table rankings, supposed research quality and performance management).

Similarly, almost all of our grant applications over that 25 years were refused, too, which was even more serious as without funding, the people in my lab couldn’t be paid nor materials bought. I was very fortunate in having three successive post-doctoral researchers, Woan-Ru Lin, Curtis Dobson, and especially Matthew Wozniak, who were so dedicated that they were willing to continue to work even when on repeated short-term contracts (sometimes for less than 12 months).

So most of my time was taken up in writing research proposals and filling in application forms, interspersed with writing and submitting articles to journals, and when rejected, trying another. I had to face derision and hostile rants unaccompanied by any meaningful, scientific criticism from reviewers. A typical example was: “This grant essentially centres on a question of belief; are viruses important in Alzheimer’s disease, in my view they are not.”

Each rejection seemed like the end of the world. It was a heart-stopping moment when opening the envelope or email from the funding body and scanning the lines in the hope of finding the words, “I’m pleased to tell you …” – though all too often, I found the words, “I regret to tell you”. I hid, weeping tears of despair, while a part of my brain questioned whether the work really was nonsensical and whether the ideas were just wild fantasies.

At conferences, I was often shunned by prominent people in the field. My poster presentations were too (posters were the poor man’s alternative to giving a talk, a privilege I was rarely given). Although, hearteningly, I found that younger people were interested and excited by the research.

Later, I benefited from the generosity of a colleague, . Kulikowski was another eccentric who lived an upside-down life, working at night and either sleeping during the day or else amusing himself by lobbing provocative remarks at colleagues. He was really interested in our research, despite working in the totally different field of vision research.

I do realise of course that many others have suffered refusals of grant applications, and I understand how especially heartbreaking it is for those at the start of their career, as it usually means the end of all their hopes and dreams of becoming a scientist. I realise too that I had been exceptionally lucky in being able to do such utterly engrossing work – a continuous, totally fascinating puzzle and challenge – and in having a loving family.

But after each rejection my fear that the work would end was overwhelming. When I did get a grant – any grant – I was elated: the world sparkled. I was so happy and exuberant, not just with the funding but with the fact that some people in the field were supportive of, or at least willing to consider, a possible role for HSV1. I felt so encouraged, vindicated and ready to face any challenge in my work or from fellow scientists, and brimming over with ideas for new approaches.

Quite often in the later years, some strongly supported our central concept. But there was a huge divide between them and its opponents. And the hostility continues to this day. In 2019, an application by a colleague to a US funding body for a clinical trial of an antiviral for Alzheimer’s was refused. I was involved as an adviser because it was based on my lab’s research, though I was not an applicant.

One reviewer said: “This application is peripherally related to the idea that Human Herpes Virus (HHV) infection could play a role in Alzheimer’s disease pathogenesis … the evidence is weak, the supporting data are weak.” The second reviewer proclaimed: “The novelty of this approach appears to be quite lacking. The suggestion of latent microbe-based activation by (unknown) factors coincident with a ‘deteriorating immune system’ as the cause for Alzheimer’s seems like hand waving”: poetic perhaps, but hardly a brilliant display of scientific disputation. In fact, no adverse comments had ever been supported by any scientific argument, despite a public assertion once by a senior government official that the HSV1/Alzheimer’s work had been refuted (though when challenged, he was unable to cite any such article).

Most researchers acknowledge that new, surprising and challenging ideas should be viewed with caution. But ideas should not be dismissed without any deliberation. Perhaps another major reason for the hostility is that many people in the field have been working for several decades on amyloid as a cause, and so are understandably distressed on learning that it might not be a direct cause, except in rare familial cases. This occurs despite our repeatedly stressing that numerous factors contribute to Alzheimer’s and amyloid is clearly an important feature.

Exciting developments

But, as the Columbia University study shows, attitudes to the topic of Alzheimer’s and HSV1 are slowly, but steadily, improving. Of course, I am very happy about this, for the sake of patients and their carers. And I have to admit that recognition of the work on HSV1 is personally gratifying as, like most people, I am heartened to know that my work has achieved something.

I am pleased that the research that I and others are carrying out is now moving forwards in even more exciting directions, including the use of a 3D bioengineered human which, when infected with HSV1, displays many Alzheimer’s-like characteristics.

We are now investigating the effects of and a possible role for vaccinations. This follows an explanation I with my then-senior post-doctoral associate, Curtis Dobson, to account for that certain vaccines decreased the risk of Alzheimer’s disease. We suggested that infections might reactivate latent HSV1 in the brain and that vaccines might decrease the consequent risk of Alzheimer’s disease by reducing the occurrence of such infectious diseases.

For example, in the case of shingles – which is caused by another type of herpes virus, varicella zoster virus (VZV) – I carried out with 91ֱ University epidemiologists showed that vaccination against the disease may protect against the development of Alzheimer’s. Two subsequent studies showed the same result. However, much further work needs to be done to elucidate the findings that certain types of vaccine appear to reduce the risk of Alzheimer’s.

Scraping of a skin lesion showing characteristic giant cells in a patient with chicken pox (Varicella Zoster Virus), a type of herpes.

I, along with researchers at Tufts University, then if VZV (which also causes chickenpox) plays a role similar to HSV1 in causing brain damage leading to the development of Alzheimer’s.

showed that VZV infection of the cells does not lead to the formation of the main characteristic Alzheimer’s features in the brain. However, VZV infection does result in certain other Alzheimer’s-like features, including increased inflammation. And – importantly – VZV was seen to reactivate the latent HSV1 infection in the brain model, with the consequent occurrence of Alzheimer’s-like characteristics. This is consistent with our suggestion that infections reactivate latent HSV1 in the brain.

The that another herpes virus, Epstein Barr, is a cause of another brain disease (multiple sclerosis) strengthens the likelihood of viral involvement in certain other such diseases.

We now plan to find out if other infections cause HSV1 reactivation from latency. If they do, the obvious corollary would be to try to limit infections by vaccination, and by improving standards of hygiene and living conditions – a particular need in developing countries – to reduce microbial transmission.

In addition, we now have some exciting preliminary findings suggesting that percussive brain injury (for example, concussion) can cause HSV1 reactivation. This is a very different type of injury from infection and the results suggest that the virus might be pivotal in the brain’s response to diverse types of damage.

This is an exciting field of study and I hope bright young scientists will enter it. Nobody said being a scientist was easy, but with the right encouragement from family, friends and open-minded peers, it is amazing what challenges can be overcome.

, Professor Emeritus of Molecular Neurobiology at the University of Manchester and a Visiting Professorial Fellow,

This article is republished from under a Creative Commons license. Read the . For you: more from our :

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Wed, 16 Nov 2022 08:44:59 +0000 https://content.presspage.com/uploads/1369/500_ruthitzhaki.jpg?10000 https://content.presspage.com/uploads/1369/ruthitzhaki.jpg?10000
Researcher wins award for film raising awareness of Deaf people affected by dementia. /about/news/researcher--wins--award-for-film-raising-awareness-of-deaf-people-affected-by-dementia/ /about/news/researcher--wins--award-for-film-raising-awareness-of-deaf-people-affected-by-dementia/523355A gallery of “breath-taking” images and videos which shine a light on crucial dementia research have been released today by Alzheimer’s Society’s first ever research image competition which was won by a University of Manchester researcher.

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A gallery of “breath-taking” images and videos which shine a light on crucial dementia research have been released today by Alzheimer’s Society’s first ever research image competition which was won by a University of Manchester researcher.

Spotlight on Dementia challenges researchers funded by the charity to showcase their vital work through creative images and video. Entries explored diverse topics such as detecting dementia using virtual reality, the impact of young-onset dementia on people’s careers, and the potential involvement of the brain’s immune system in the processes behind dementia.

Dr Emma Ferguson-Coleman is a Research Fellow at the University of Manchester and is being funded by Alzheimer’s Society for her current research study into the support needs of Deaf carers who care for people with dementia.

Emma won the Research in Motion category for her video called Losing my Language, which is about Deaf man who has been living with dementia for a few years. In this video, which is composed from qualitative research data after she interviewed a native BSL Deaf man and his family members, the actor representing the Deaf man shares his perception of living with dementia and what the future might mean for him. This is portrayed in a moment where he uses one sign (rather than a few full sentences in BSL) to describe his in-depth emotions about the possibility of fading away as a person and losing his language, BSL.

Emma said about winning the Research in Motion category: “It’s an absolute honour for me to see the story of Harold and his family represented in the wider mainstream – it is amazing.

‘As a Deaf BSL user myself, I am privileged to represent the stories of Deaf people living with dementia and their carers

‘This video took about three months to develop. I contacted Ilan (ILAN) Dwek (a famous Deaf actor) and discussed this conversation with him; sharing a video of myself mimicking Harold’s signs (for the purpose of research confidentiality) and Ilan filmed himself at home representing Harold’s story. Ilan did an amazing job in reflecting Harold’s emotions. 

‘It was critical that Ilan was able to represent Harold’s position in all its’ entirety. If Ilan had just signed the one sign, there would be no context and no appreciation of the many layers of emotion that Harold was portraying in that moment.

‘I hope that from seeing this brief film, that the wider mainstream community come to understand and appreciate the rich complexities of communicating in BSL, especially with a Deaf BSL user living with dementia. This film will raise awareness of this minority community that use BSL as their first or preferred language and hopefully remove barriers in learning how to communicate either in BSL, or with a BSL interpreter to assist with two-way conversations.”

Emma entered academia as a research assistant in 2010 and studied for her PhD between 2010-2016. Her PhD was focussed on Deaf British Sign Language (BSL) users’ understanding and knowledge of dementia, as well as interviewing, for the first time, Deaf BSL users living with dementia with their carers about their everyday experiences.

Emma also has a personal link to dementia as her grandmother lived with vascular dementia after having had a stroke.

Dr Richard Oakley, Associate Director of Research at Alzheimer’s Society, said:

“Spotlight on Dementia brings together science and art to reveal the wonder and variety of the research we fund. Each breath-taking entry tells a different story about the drive and enthusiasm of our stellar researchers working across dementia diagnosis, treatment and care.

“Alzheimer’s Society is a vital source of support and a powerful force for change for people with dementia. The charity only funds the most cutting-edge dementia research and currently we fund over 155 projects worth over £29.5m. We do this because we know research will beat dementia and improve the lives of people affected by the condition.

“Times are hard at the moment, but more funding is desperately needed to help us find breakthroughs and a cure. Decades of underfunding mean dementia research lags about twenty years behind the progress we’ve made in cancer, and we’re still waiting for the Government to act on its commitment over two years ago to double dementia research funding.”

17 hi-res photos from the overall winners and Emma’s video is available *

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Biggest ever map of human Alzheimer’s brain published /about/news/biggest-ever-map-of-human-alzheimers-brain-published/ /about/news/biggest-ever-map-of-human-alzheimers-brain-published/320101A study of the differences between healthy brains and those with Alzheimer’s Disease has produced largest dataset of its type ever.

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A study of the differences between healthy brains and those with Alzheimer’s Disease has produced largest dataset of its type ever.

And the data, developed by a team of researchers led by Dr Richard Unwin at The University of Manchester, is now freely available for any scientist to use.

The team included researchers from the Universities 91ֱ, Bristol, Liverpool and Auckland.

The development is an important advance for scientists researching Alzheimer’s.

The team also show that one region of the brain previously thought to be unaffected by the disease, the cerebellum, displayed a series of changes which they think might protect it from damage caused by Alzheimer’s.

The Alzheimer’s Research UK funded study is published in the journal Communications Biology today.

The analysis, mapping the relative levels of over 5,825 distinct proteins across six regions of the brain, generated a massive 24,024 data points.

The brain regions in the study included the more heavily affected Hippocampus, Entorhinal cortex, Cingulate gyrus and the less affected Motor Cortex, Sensory Cortex, and Cerebellum

The samples were donated for research by patients at the New Zealand Brain Bank in Auckland.

Dr Unwin said: “This database provides a huge opportunity for dementia researchers around the world to progress and to follow-up new areas of biology and develop new treatments.

“It could also help validate observations seen in in animal or cell disease models in humans.

”It’s very exciting to be able to make these data public so scientists can access and use this vital information.”

Alzheimer’s Disease arises in the hippocampus and spreads through pathways in the brain.

But by looking at different parts of that pathway, the team were able to observe, for the first time, how Alzheimer’s progresses in more detail.

“We think that the changes we see in the regions affected later on-represent early disease changes, present before cells die,” he said

“These represent good new targets for drug developers, as we know it’s important to try to intervene early.”

In the course of the study, the team hit upon new molecules not previously associated with the disease, representing more targets to develop new drugs.

They also confirm that researchers looking at a range of pathways - including inflammation, Wnt signalling, and metabolic changes in human tissue - are on the right track.

The team identified 129 protein changes which were present in all areas of the brain studied, with at least 44 not previously associated with the disease.

But there were hundreds others which change only in the late-affected regions.

He added: “These new protein changes represent further targets for scientists developing new drugs

“The cerebellum, previously thought be unaffected, displays a significant response at the molecular level.

“Many of the changes here are not seen in other regions and this could imply that this region actively protects itself from disease. We won’t know for sure until we carry out more research.”

Dr Rosa Sancho, Head of Research at Alzheimer’s Research UK, said: “By studying thousands of individual proteins, this exciting research has generated a detailed molecular map of changes that get underway in the brain in Alzheimer’s disease. Making this information freely available online will help researchers to navigate the complex and changing environment of the brain in Alzheimer’s and identify processes that could be targeted by future drugs.

“There are over half a million people in the UK living with Alzheimer’s and there are currently no treatments that can slow or stop the disease from progressing in the brain. Pioneering research like this is driving progress towards new breakthroughs that will change people’s lives.”

The paper ‘Regional protein expression in human Alzheimer’s brain correlates with disease severity’ is publihsed in 

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Alzheimer's disease: mounting evidence that herpes virus is a cause /about/news/alzheimers-disease-mounting-evidence-that-herpes-virus-is-a-cause/ /about/news/alzheimers-disease-mounting-evidence-that-herpes-virus-is-a-cause/305316File 20181017 41153 xdfg3e.jpg?ixlib=rb 1.1

, Professor Emeritus of Molecular Neurobiology, writes

More than 30m people worldwide suffer from Alzheimer’s disease – the most common form of dementia. Unfortunately, there is no cure, only drugs to ease the symptoms. However, my , suggests a way to treat the disease. I found the strongest evidence yet that the herpes virus is a cause of Alzheimer’s, suggesting that effective and safe antiviral drugs might be able to treat the disease. We might even be able to vaccinate our children against it.

The virus implicated in Alzheimer’s disease, herpes simplex virus type 1 (HSV1), is better known for causing cold sores. It infects most people in infancy and then remains dormant in the peripheral nervous system (the part of the nervous system that isn’t the brain and the spinal cord). Occasionally, if a person is stressed, the virus becomes activated and, in some people, it causes cold sores.

We discovered in that in many elderly people HSV1 is also present in the brain. And in we showed that it confers a strong risk of Alzheimer’s disease when present in the brain of people who have a specific gene known as APOE4.

The virus can become active in the brain, perhaps repeatedly, and this probably causes cumulative damage. The likelihood of developing Alzheimer’s disease is 12 times greater for APOE4 carriers who have HSV1 in the brain than for those with neither factor.

Later, and found that HSV1 infection of cell cultures causes beta-amyloid and abnormal tau proteins to accumulate. An accumulation of these proteins in the brain is characteristic of Alzheimer’s disease.

Most people are infected with the herpes simplex virus by the time they reach old age.

We believe that HSV1 is a major contributory factor for Alzheimer’s disease and that it enters the brains of elderly people as their immune system declines with age. It then establishes a latent (dormant) infection, from which it is reactivated by events such as stress, a reduced immune system and brain inflammation induced by infection by other microbes.

Reactivation leads to direct viral damage in infected cells and to viral-induced inflammation. We suggest that repeated activation causes cumulative damage, leading eventually to Alzheimer’s disease in people with the APOE4 gene.

Presumably, in APOE4 carriers, Alzheimer’s disease develops in the brain because of greater HSV1-induced formation of toxic products, or less repair of damage.

New treatments?

The data suggest that antiviral agents might be used for treating Alzheimer’s disease. The main antiviral agents, which are safe, prevent new viruses from forming, thereby limiting viral damage.

In an earlier study, we that the anti-herpes antiviral drug, acyclovir, blocks HSV1 DNA replication, and reduces levels of beta-amyloid and tau caused by HSV1 infection of cell cultures.

It’s important to note that all studies, including our own, only show an association between the herpes virus and Alzheimer’s – they don’t prove that the virus is an actual cause. Probably the only way to prove that a microbe is a cause of a disease is to show that an occurrence of the disease is greatly reduced either by targeting the microbe with a specific anti-microbial agent or by specific vaccination against the microbe.

Excitingly, successful prevention of Alzheimer’s disease by use of specific anti-herpes agents has in a in Taiwan. Hopefully, information inother countries, if available, will yield similar results.The Conversation

, Professor Emeritus of Molecular Neurobiology,

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

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