Tag Archives: Pharmaceutical

Aducanumab, an antibody developed by the University of Zurich, has been shown to trigger a meaningful reduction of harmful beta-amyloid plaques in patients with early-stage Alzheimer’s disease. These protein deposits in the brain are a classic sign of Alzheimer’s disease and contribute to the progressive degeneration of brain cells. The researchers furthermore demonstrated in an early-stage clinical study that, after one year of treatment with Aducanumab, cognitive decline could be significantly slowed in antibody-treated patients as opposed to the placebo group.

Although the causes of Alzheimer’s disease are still unknown, it is clear that the disease commences with progressive amyloid deposition in the brains of affected persons between ten and fifteen years before the emergence of initial clinical symptoms such as memory loss. Researchers have now been able to show that Aducanumab, a human monoclonal antibody, selectively binds brain amyloid plaques, thus enabling microglial cells to remove the plaques. A one-year treatment with the antibody, as part of a phase Ib study, resulted in almost complete clearance of the brain amyloid plaques in the study group patients. The results, which were realized by researchers at UZH together with the biotech company “Biogen” and the UZH spin-off “Neurimmune,” have been published in Nature.

Reduction of brain amyloid plaque is dependent on treatment duration and dosage

“The results of this clinical study make us optimistic that we can potentially make a great step forward in treating Alzheimer’s disease,” says Roger M. Nitsch, professor at the Institute for Regenerative Medicine at UZH. “The effect of the antibody is very impressive. And the outcome is dependent on the dosage and length of treatment.” After one year of treatment, practically no beta-amyloid plaques could be detected in the patients who received the highest dose of the antibody.

The antibody was developed with the help of a technology platform from “Neurimmune.” Using blood collected from elderly persons aged up to one hundred and demonstrating no cognitive impairment, the researchers isolated precisely those immune cells whose antibodies are able to identify toxic beta-amyloid plaques but not the amyloid precursor protein that is present throughout the human body and that presumably plays an important role in the growth of nerve cells. The good safety profile of Aducanumab in patients may well be attributed to the antibody’s specific capacity to bond with the abnormally folded beta-amyloid protein fragment as well as the fact that the antibody is of human origin.

Investigational treatment also curbs cognitive decline

165 patients with early-stage Alzheimer’s disease were treated in the phase 1b clinical trial. Although not initially planned as a primary study objective, the good results encouraged researchers to additionally investigate how the treatment affected the symptoms of disease. This was evaluated via standardized questionnaires to assess the cognitive abilities and everyday activities of the patients. “Aducanumab also showed positive effects on clinical symptoms,” is how Nitsch sums up the findings. “While patients in the placebo group exhibited significant cognitive decline, cognitive ability remained distinctly more stable in patients receiving the antibody.”

Some of the trial participants temporarily suffered from amyloid-related imaging abnormality (ARIA), an adverse effect that can be detected via magnetic resonance imaging. In a minority of cases, this was accompanied by temporary mild to moderate headaches. The UZH researchers believe that ARIA is a measurable biological effect of amyloid clearance.

The promising effects of Aducanumab are currently being investigated in two large phase-three clinical studies to further evaluate safety and efficacy. Involving over 300 centers in 20 countries throughout North America, Europe, and Asia, these studies are evaluating the effectiveness and safety of the antibody on a total of 2,700 patients with early-stage Alzheimer’s disease.

Paper: “The antibody aducanumab reduces Aβ plaques in Alzheimer’s disease”
Reprinted from materials provided by the University of Zurich.

While research has identified hundreds of genes required for normal memory formation, genes that suppress memory are of special interest because they offer insights into how the brain prioritizes and manages all of the information, including memories, that it takes in every day. These genes also provide clues for how scientists might develop new treatments for cognitive disorders such as Alzheimer’s disease.

Scientists have identified a unique memory suppressor gene in the brain cells of Drosophila, the common fruit fly, in a study published in the journal Neuron.

The researchers screened approximately 3,500 Drosophila genes and identified several dozen new memory suppressor genes that the brain has to help filter information and store only important parts. One of these suppressor genes, in particular, caught their attention.

“When we knocked out this gene, the flies had a better memory—a nearly two-fold better memory,” said Ron Davis, chair of the Department of Neuroscience at The Scripps Research Institute and leader of the study. “The fact that this gene is active in the same pathway as several cognitive enhancers currently used for the treatment of Alzheimer’s disease suggests it could be a potential new therapeutic target.”

When the scientists disabled this gene, known as DmSLC22A, flies’ memory of smells (the most widely studied form of memory in this model) was enhanced—while overexpression of the gene inhibited that same memory function.

“Memory processes and the genes that make the brain proteins required for memory are evolutionarily conserved between mammals and fruit flies,” said Research Associate Ze Liu, co-first author of the study. “The majority of human cognitive disease-causing genes have the same functional genetic counterparts in flies.”

The gene in question belongs to a family of “plasma membrane transporters,” which produce proteins that move molecules, large and small, across cell walls. In the case of DmSLC22A, the new study indicates that the gene makes a protein involved in moving neurotransmitter molecules from the synaptic space between neurons back into the neurons. When DmSLC22A functions normally, the protein removes the neurotransmitter acetylcholine from the synapse, helping to terminate the synaptic signal. When the protein is missing, more acetylcholine persists in the synapse, making the synaptic signal stronger and more persistent, leading to enhanced memory.

“DmSLC22A serves as a bottleneck in memory formation,” said Research Associate Yunchao Gai, the study’s other co-first author. “Considering the fact that plasma transporters are ideal pharmacological targets, drugs that inhibit this protein may provide a practical way to enhance memory in individuals with memory disorders.”

The next step, Davis added, is to develop a screen for inhibitors of this pathway that, independently or in concert with other treatments, may offer a more effective way to deal with the problems of memory loss due to Alzheimer’s and other neurodegenerative diseases.

“One of the major reasons for working with the fly initially is to identify brain proteins that may be suitable targets for the development of cognitive enhancers in humans,” said Davis. “Otherwise, we would be guessing in the dark as to which of the more than 23,000 human proteins might be appropriate targets.”

Source: Reprinted from materials provided by Eric Sauter at The Scripps Research Institute.

Paper: “Drosophila SLC22A Transporter Is a Memory Suppressor Gene that Influences Cholinergic Neurotransmission to the Mushroom Bodies.”

The European Medicines Agency (EMA) has released draft revised guidelines on medicines for the treatment of Alzheimer’s disease and other types of dementias for a six-month public consultation.

EMA follows a multi-stakeholder approach to facilitate research and development of more effective medicines. The revised guidelines take into account comments received at EMA’s workshop on the clinical investigation of medicines for the treatment of Alzheimer’s disease in November 2014. This workshop brought together a wide range of stakeholders, including patient representatives, regulators, pharmaceutical industry and independent experts. The aim of the workshop was to ensure that during the revision of its guidelines, EMA would be able to consider the most up-to-date scientific developments in understanding and treating Alzheimer’s disease and views from experts in the field. The revised guidelines also build on EMA scientific advice provided for a number of specific development plans for Alzheimer’s disease in recent years, as well as the qualification of several biomarkers for the selection of patients in clinical trials.

The revised guideline specifically addresses the:

impact of new diagnostic criteria for Alzheimer’s disease, including early and even asymptomatic disease stages, on clinical trial design
choice of parameters to measure trial outcomes and the need for distinct assessment tools for the different disease stagesin Alzheimer’s (different signs and symptoms, differences in changes over time, severity)
potential use of biomarkers and their temporal relationship with the different phases of Alzheimer’s disease at different stages of medicine development (mechanism of action, use as diagnostic test, enrichment of study populations, stratification of subgroups, safety and efficacy markers etc.)
design of long-term efficacy and safety studies

Comments received during the consultation will be taken into account in the finalisation of the guideline.

Stakeholders are invited to send their comments by 31 July 2016. To learn more, visit the EMA website.

Source: EMA

The Innovative Medicines Initiative (IMI) has launched a new call for research proposals that will aim to accelerate the development of medicines in a number of key areas, including neurological disorders.

The Alzheimer’s disease and Parkinson’s disease topic of the call focuses on better understanding how the protein tangles found in both diseases spread through the brain, with the ultimate goal of establishing new drug targets.

The IMI initiative, a partnership between the European Union and the pharmaceutical industry association EFPIA, aims to stimulate the development of safer and more effective medicines.

Other topics in the call, known as IMI 2 – Call 7, include safety, pain, cancer, eye diseases, and big data. Call 7 has a budget of €46.8 million from IMI, which will be matched by €46.8 million from the EFPIA companies in the projects. The submission deadline for this call is March 17, 2016.

IMI simultaneously launched a second call, known as IMI 2 – Call 8, for research proposals on Ebola and related diseases.

Visit the IMI website to learn more about the call topics and to apply.

Three former top researchers at Genentech (now part of Roche Holding), have raised $217 million in venture capital to start a new company, Denali Therapeutics, focused on treating and curing neurodegenerative diseases like Alzheimer’s, ALS, and Parkinson’s.

The news is sign of a financial turnaround for research efforts against these brain diseases that have been tough to beat.

NeuroPerspective, a newsletter that tracks neurological treatments, says in the past five years the number of drugs being developed by large drug makers for brain and nervous system disorders fell 50% to 129 – but that last year, investors poured $3.3 billion into the field, more than in any of the last ten years.

The raise for Denali is a series A, the very first round of getting funding for a new company. It is the largest such round in biotech history.

Eli Lilly and Company and AstraZeneca announced the start of recruitment of patients for the Phase II/III AMARANTH clinical trial of an inhibitor of beta secretes cleaving enzyme (BACE), currently under development as a promising therapy for Alzheimer’s disease.

The AMARANTH Phase II/III clinical trial will evaluate the safety and efficacy of oral AZD3293/LY3314814 against placebo and will assess if this drug can be designated as disease-modifying therapy for patients with early Alzheimer’s disease. The state of early Alzheimer’s disease includes patients with mild cognitive impairment (MCI) associated with Alzheimer’s disease and patients with mild Alzheimer’s dementia. This new study will include more than 1,500 patients in 15 countries, and the treatment will be for 2 years.

Source: Alzheimer’s News Today

Pharmaceutical companies, AstraZeneca and Eli Lilly and Co (Lilly) announced on 16 September having reached an agreement to jointly develop and commercialise AZD3293, an oral BACE inhibitor currently in development as a potential treatment for Alzheimer’s disease (AD).

In Phase I studies, AZD3293 had been shown to significantly and dose-dependently reduce levels of amyloid beta in the cerebro-spinal fluid of trial participants with Alzheimer’s disease as well as in healthy volunteers. AstraZeneca announced its plan to move AZD3293 into registration trials earlier this year.

This alliance has been formed with the aim of progressing AZD3293 rapidly into a Phase II/III clinical trial in patients with early Alzheimer’s disease.

Lilly will lead clinical development, working with researchers from AstraZeneca’s Innovative Medicines Unit for neuroscience, while AstraZeneca will be responsible for manufacturing. The companies will take joint responsibility for the commercialisation of AZD3293.