Project acronym 3DBrainStrom
Project Brain metastases: Deciphering tumor-stroma interactions in three dimensions for the rational design of nanomedicines
Researcher (PI) Ronit Satchi Fainaro
Host Institution (HI) TEL AVIV UNIVERSITY
Call Details Advanced Grant (AdG), LS7, ERC-2018-ADG
Summary Brain metastases represent a major therapeutic challenge. Despite significant breakthroughs in targeted therapies, survival rates of patients with brain metastases remain poor. Nowadays, discovery, development and evaluation of new therapies are performed on human cancer cells grown in 2D on rigid plastic plates followed by in vivo testing in immunodeficient mice. These experimental settings are lacking and constitute a fundamental hurdle for the translation of preclinical discoveries into clinical practice. We propose to establish 3D-printed models of brain metastases (Aim 1), which include brain extracellular matrix, stroma and serum containing immune cells flowing in functional tumor vessels. Our unique models better capture the clinical physio-mechanical tissue properties, signaling pathways, hemodynamics and drug responsiveness. Using our 3D-printed models, we aim to develop two new fronts for identifying novel clinically-relevant molecular drivers (Aim 2) followed by the development of precision nanomedicines (Aim 3). We will exploit our vast experience in anticancer nanomedicines to design three therapeutic approaches that target various cellular compartments involved in brain metastases: 1) Prevention of brain metastatic colonization using targeted nano-vaccines, which elicit antitumor immune response; 2) Intervention of tumor-brain stroma cells crosstalk when brain micrometastases establish; 3) Regression of macrometastatic disease by selectively targeting tumor cells. These approaches will materialize using our libraries of polymeric nanocarriers that selectively accumulate in tumors.
This project will result in a paradigm shift by generating new preclinical cancer models that will bridge the translational gap in cancer therapeutics. The insights and tumor-stroma-targeted nanomedicines developed here will pave the way for prediction of patient outcome, revolutionizing our perception of tumor modelling and consequently the way we prevent and treat cancer.
Summary
Brain metastases represent a major therapeutic challenge. Despite significant breakthroughs in targeted therapies, survival rates of patients with brain metastases remain poor. Nowadays, discovery, development and evaluation of new therapies are performed on human cancer cells grown in 2D on rigid plastic plates followed by in vivo testing in immunodeficient mice. These experimental settings are lacking and constitute a fundamental hurdle for the translation of preclinical discoveries into clinical practice. We propose to establish 3D-printed models of brain metastases (Aim 1), which include brain extracellular matrix, stroma and serum containing immune cells flowing in functional tumor vessels. Our unique models better capture the clinical physio-mechanical tissue properties, signaling pathways, hemodynamics and drug responsiveness. Using our 3D-printed models, we aim to develop two new fronts for identifying novel clinically-relevant molecular drivers (Aim 2) followed by the development of precision nanomedicines (Aim 3). We will exploit our vast experience in anticancer nanomedicines to design three therapeutic approaches that target various cellular compartments involved in brain metastases: 1) Prevention of brain metastatic colonization using targeted nano-vaccines, which elicit antitumor immune response; 2) Intervention of tumor-brain stroma cells crosstalk when brain micrometastases establish; 3) Regression of macrometastatic disease by selectively targeting tumor cells. These approaches will materialize using our libraries of polymeric nanocarriers that selectively accumulate in tumors.
This project will result in a paradigm shift by generating new preclinical cancer models that will bridge the translational gap in cancer therapeutics. The insights and tumor-stroma-targeted nanomedicines developed here will pave the way for prediction of patient outcome, revolutionizing our perception of tumor modelling and consequently the way we prevent and treat cancer.
Max ERC Funding
2 353 125 €
Duration
Start date: 2019-04-01, End date: 2024-03-31
Project acronym 4D-PET
Project Innovative PET scanner for dynamic imaging
Researcher (PI) José María BENLLOCH BAVIERA
Host Institution (HI) AGENCIA ESTATAL CONSEJO SUPERIOR DEINVESTIGACIONES CIENTIFICAS
Call Details Advanced Grant (AdG), LS7, ERC-2015-AdG
Summary The main objective of 4D-PET is to develop an innovative whole-body PET scanner based in a new detector concept that stores 3D position and time of every single gamma interaction with unprecedented resolution. The combination of scanner geometrical design and high timing resolution will enable developing a full sequence of all gamma-ray interactions inside the scanner, including Compton interactions, like in a 3D movie. 4D-PET fully exploits Time Of Flight (TOF) information to obtain a better image quality and to increase scanner sensitivity, through the inclusion in the image formation of all Compton events occurring inside the detector, which are always rejected in state-of-the-art PET scanners. The new PET design will radically improve state-of-the-art PET performance features, overcoming limitations of current PET technology and opening up new diagnostic venues and very valuable physiological information
Summary
The main objective of 4D-PET is to develop an innovative whole-body PET scanner based in a new detector concept that stores 3D position and time of every single gamma interaction with unprecedented resolution. The combination of scanner geometrical design and high timing resolution will enable developing a full sequence of all gamma-ray interactions inside the scanner, including Compton interactions, like in a 3D movie. 4D-PET fully exploits Time Of Flight (TOF) information to obtain a better image quality and to increase scanner sensitivity, through the inclusion in the image formation of all Compton events occurring inside the detector, which are always rejected in state-of-the-art PET scanners. The new PET design will radically improve state-of-the-art PET performance features, overcoming limitations of current PET technology and opening up new diagnostic venues and very valuable physiological information
Max ERC Funding
2 048 386 €
Duration
Start date: 2017-01-01, End date: 2021-12-31
Project acronym 5D Heart Patch
Project A Functional, Mature In vivo Human Ventricular Muscle Patch for Cardiomyopathy
Researcher (PI) Kenneth Randall Chien
Host Institution (HI) KAROLINSKA INSTITUTET
Call Details Advanced Grant (AdG), LS7, ERC-2016-ADG
Summary Developing new therapeutic strategies for heart regeneration is a major goal for cardiac biology and medicine. While cardiomyocytes can be generated from human pluripotent stem (hPSC) cells in vitro, it has proven difficult to use these cells to generate a large scale, mature human heart ventricular muscle graft on the injured heart in vivo. The central objective of this proposal is to optimize the generation of a large-scale pure, fully functional human ventricular muscle patch in vivo through the self-assembly of purified human ventricular progenitors and the localized expression of defined paracrine factors that drive their expansion, differentiation, vascularization, matrix formation, and maturation. Recently, we have found that purified hPSC-derived ventricular progenitors (HVPs) can self-assemble in vivo on the epicardial surface into a 3D vascularized, and functional ventricular patch with its own extracellular matrix via a cell autonomous pathway. A two-step protocol and FACS purification of HVP receptors can generate billions of pure HVPs- The current proposal will lead to the identification of defined paracrine pathways to enhance the survival, grafting/implantation, expansion, differentiation, matrix formation, vascularization and maturation of the graft in vivo. We will captalize on our unique HVP system and our novel modRNA technology to deliver therapeutic strategies by using the in vivo human ventricular muscle to model in vivo arrhythmogenic cardiomyopathy, and optimize the ability of the graft to compensate for the massive loss of functional muscle during ischemic cardiomyopathy and post-myocardial infarction. The studies will lead to new in vivo chimeric models of human cardiac disease and an experimental paradigm to optimize organ-on-organ cardiac tissue engineers of an in vivo, functional mature ventricular patch for cardiomyopathy
Summary
Developing new therapeutic strategies for heart regeneration is a major goal for cardiac biology and medicine. While cardiomyocytes can be generated from human pluripotent stem (hPSC) cells in vitro, it has proven difficult to use these cells to generate a large scale, mature human heart ventricular muscle graft on the injured heart in vivo. The central objective of this proposal is to optimize the generation of a large-scale pure, fully functional human ventricular muscle patch in vivo through the self-assembly of purified human ventricular progenitors and the localized expression of defined paracrine factors that drive their expansion, differentiation, vascularization, matrix formation, and maturation. Recently, we have found that purified hPSC-derived ventricular progenitors (HVPs) can self-assemble in vivo on the epicardial surface into a 3D vascularized, and functional ventricular patch with its own extracellular matrix via a cell autonomous pathway. A two-step protocol and FACS purification of HVP receptors can generate billions of pure HVPs- The current proposal will lead to the identification of defined paracrine pathways to enhance the survival, grafting/implantation, expansion, differentiation, matrix formation, vascularization and maturation of the graft in vivo. We will captalize on our unique HVP system and our novel modRNA technology to deliver therapeutic strategies by using the in vivo human ventricular muscle to model in vivo arrhythmogenic cardiomyopathy, and optimize the ability of the graft to compensate for the massive loss of functional muscle during ischemic cardiomyopathy and post-myocardial infarction. The studies will lead to new in vivo chimeric models of human cardiac disease and an experimental paradigm to optimize organ-on-organ cardiac tissue engineers of an in vivo, functional mature ventricular patch for cardiomyopathy
Max ERC Funding
2 149 228 €
Duration
Start date: 2017-12-01, End date: 2022-11-30
Project acronym AIR-NB
Project Pre-natal exposure to urban AIR pollution and pre- and post-Natal Brain development
Researcher (PI) Jordi Sunyer
Host Institution (HI) FUNDACION PRIVADA INSTITUTO DE SALUD GLOBAL BARCELONA
Call Details Advanced Grant (AdG), LS7, ERC-2017-ADG
Summary Air pollution is the main urban-related environmental hazard. It appears to affect brain development, although current evidence is inadequate given the lack of studies during the most vulnerable stages of brain development and the lack of brain anatomical structure and regional connectivity data underlying these effects. Of particular interest is the prenatal period, when brain structures are forming and growing, and when the effect of in utero exposure to environmental factors may cause permanent brain injury. I and others have conducted studies focused on effects during school age which could be less profound. I postulate that: pre-natal exposure to urban air pollution during pregnancy impairs foetal and postnatal brain development, mainly by affecting myelination; these effects are at least partially mediated by translocation of airborne particulate matter to the placenta and by placental dysfunction; and prenatal exposure to air pollution impairs post-natal brain development independently of urban context and post-natal exposure to air pollution. I aim to evaluate the effect of pre-natal exposure to urban air pollution on pre- and post-natal brain structure and function by following 900 pregnant women and their neonates with contrasting levels of pre-natal exposure to air pollutants by: i) establishing a new pregnancy cohort and evaluating brain imaging (pre-natal and neo-natal brain structure, connectivity and function), and post-natal motor and cognitive development; ii) measuring total personal exposure and inhaled dose of air pollutants during specific time-windows of gestation, noise, paternal stress and other stressors, using personal samplers and sensors; iii) detecting nanoparticles in placenta and its vascular function; iv) modelling mathematical causality and mediation, including a replication study in an external cohort. The expected results will create an impulse to implement policy interventions that genuinely protect the health of urban citizens.
Summary
Air pollution is the main urban-related environmental hazard. It appears to affect brain development, although current evidence is inadequate given the lack of studies during the most vulnerable stages of brain development and the lack of brain anatomical structure and regional connectivity data underlying these effects. Of particular interest is the prenatal period, when brain structures are forming and growing, and when the effect of in utero exposure to environmental factors may cause permanent brain injury. I and others have conducted studies focused on effects during school age which could be less profound. I postulate that: pre-natal exposure to urban air pollution during pregnancy impairs foetal and postnatal brain development, mainly by affecting myelination; these effects are at least partially mediated by translocation of airborne particulate matter to the placenta and by placental dysfunction; and prenatal exposure to air pollution impairs post-natal brain development independently of urban context and post-natal exposure to air pollution. I aim to evaluate the effect of pre-natal exposure to urban air pollution on pre- and post-natal brain structure and function by following 900 pregnant women and their neonates with contrasting levels of pre-natal exposure to air pollutants by: i) establishing a new pregnancy cohort and evaluating brain imaging (pre-natal and neo-natal brain structure, connectivity and function), and post-natal motor and cognitive development; ii) measuring total personal exposure and inhaled dose of air pollutants during specific time-windows of gestation, noise, paternal stress and other stressors, using personal samplers and sensors; iii) detecting nanoparticles in placenta and its vascular function; iv) modelling mathematical causality and mediation, including a replication study in an external cohort. The expected results will create an impulse to implement policy interventions that genuinely protect the health of urban citizens.
Max ERC Funding
2 499 992 €
Duration
Start date: 2018-09-01, End date: 2023-08-31
Project acronym Antivessel-T-Cells
Project Development of Vascular-Disrupting Lymphocyte Therapy for Tumours
Researcher (PI) Georgios Coukos
Host Institution (HI) CENTRE HOSPITALIER UNIVERSITAIRE VAUDOIS
Call Details Advanced Grant (AdG), LS7, ERC-2012-ADG_20120314
Summary T cell engineering with chimeric antigen receptors has opened the door to effective immunotherapy. CARs are fusion genes encoding receptors whose extracellular domain comprises a single chain variable fragment (scFv) antibody that binds to a tumour surface epitope, while the intracellular domain comprises the signalling module of CD3ζ along with powerful costimulatory domains (e.g. CD28 and/or 4-1BB). CARs are a major breakthrough, since they allow bypassing HLA restrictions or loss, and they can incorporate potent costimulatory signals tailored to optimize T cell function. However, solid tumours present challenges, since they are often genetically unstable, and the tumour microenvironment impedes T cell function. The tumour vasculature is a much more stable and accessible target, and its disruption has catastrophic consequences for tumours. Nevertheless, the lack of affinity reagents has impeded progress in this area. The objectives of this proposal are to develop the first potent and safe tumour vascular-disrupting tumour immunotherapy using scFv’s and CARs uniquely available in my laboratory.
I propose to use these innovative CARs to understand for the first time the molecular mechanisms underlying the interactions between anti-vascular CAR-T cells and tumour endothelium, and exploit them to maximize tumour vascular destruction. I also intend to employ innovative engineering approaches to minimize the chance of reactivity against normal vasculature. Lastly, I propose to manipulate the tumour damage mechanisms ensuing anti-vascular therapy, to maximize tumour rejection through immunomodulation. We are poised to elucidate critical interactions between tumour endothelium and anti-vascular T cells, and bring to bear cancer therapy of unparalleled power. The impact of this work could be transforming, given the applicability of tumour-vascular disruption across most common tumour types.
Summary
T cell engineering with chimeric antigen receptors has opened the door to effective immunotherapy. CARs are fusion genes encoding receptors whose extracellular domain comprises a single chain variable fragment (scFv) antibody that binds to a tumour surface epitope, while the intracellular domain comprises the signalling module of CD3ζ along with powerful costimulatory domains (e.g. CD28 and/or 4-1BB). CARs are a major breakthrough, since they allow bypassing HLA restrictions or loss, and they can incorporate potent costimulatory signals tailored to optimize T cell function. However, solid tumours present challenges, since they are often genetically unstable, and the tumour microenvironment impedes T cell function. The tumour vasculature is a much more stable and accessible target, and its disruption has catastrophic consequences for tumours. Nevertheless, the lack of affinity reagents has impeded progress in this area. The objectives of this proposal are to develop the first potent and safe tumour vascular-disrupting tumour immunotherapy using scFv’s and CARs uniquely available in my laboratory.
I propose to use these innovative CARs to understand for the first time the molecular mechanisms underlying the interactions between anti-vascular CAR-T cells and tumour endothelium, and exploit them to maximize tumour vascular destruction. I also intend to employ innovative engineering approaches to minimize the chance of reactivity against normal vasculature. Lastly, I propose to manipulate the tumour damage mechanisms ensuing anti-vascular therapy, to maximize tumour rejection through immunomodulation. We are poised to elucidate critical interactions between tumour endothelium and anti-vascular T cells, and bring to bear cancer therapy of unparalleled power. The impact of this work could be transforming, given the applicability of tumour-vascular disruption across most common tumour types.
Max ERC Funding
2 500 000 €
Duration
Start date: 2013-08-01, End date: 2018-07-31
Project acronym ARTimmune
Project Programmable ARTificial immune systems to fight cancer
Researcher (PI) Carl FIGDOR
Host Institution (HI) STICHTING KATHOLIEKE UNIVERSITEIT
Call Details Advanced Grant (AdG), LS7, ERC-2018-ADG
Summary Immunotherapy has entered centre stage as a novel treatment modality for cancer. Notwithstanding this major step forward, toxicity and immunosuppression remain major obstacles, and illustrate the pressing need for more powerful and specific immunotherapies against cancer. To overcome these roadblocks, in ARTimmune, I propose to follow a radically different approach by developing local rather than systemic immunotherapies. Taking advantage of the architecture of a lymph node (LN), I aim to design fully synthetic immune niches to locally instruct immune cell function. I hypothesize that programmable synthetic immune niches, when injected next to a tumour, will act as local powerhouses to generate bursts of cytotoxic T cells for tumour destruction, without toxic side effects. Single cell transcriptomics on LN, obtained from patients that are vaccinated against cancer, will provide unique insight in communication within immune cell clusters and provide a blueprint for the intelligent design of synthetic immune niches. Chemical tools will be used to build branched polymeric structures decorated with immunomodulating molecules to mimic LN architecture. These will be injected, mixed with sponge-like scaffolds to provide porosity needed for immune cell infiltration. Programming of immune cell function will be accomplished by in vivo targeting- and proteolytic activation- of immunomodulators for fine-tuning, and to extend the life span of these local powerhouses. The innovative character of ARTimmune comes from: 1) novel fundamental immunological insight in complex communication within LN cell clusters, 2) a revolutionary new approach in immunotherapy, by the development of 3) injectable- and 4) programmable- synthetic immune niches by state-of-the-art chemical technology. When successful, it will revolutionize cancer immunotherapy, moving from maximal tolerable dose systemic treatment with significant toxicity to local low dose treatment in the direct vicinity of a tumour
Summary
Immunotherapy has entered centre stage as a novel treatment modality for cancer. Notwithstanding this major step forward, toxicity and immunosuppression remain major obstacles, and illustrate the pressing need for more powerful and specific immunotherapies against cancer. To overcome these roadblocks, in ARTimmune, I propose to follow a radically different approach by developing local rather than systemic immunotherapies. Taking advantage of the architecture of a lymph node (LN), I aim to design fully synthetic immune niches to locally instruct immune cell function. I hypothesize that programmable synthetic immune niches, when injected next to a tumour, will act as local powerhouses to generate bursts of cytotoxic T cells for tumour destruction, without toxic side effects. Single cell transcriptomics on LN, obtained from patients that are vaccinated against cancer, will provide unique insight in communication within immune cell clusters and provide a blueprint for the intelligent design of synthetic immune niches. Chemical tools will be used to build branched polymeric structures decorated with immunomodulating molecules to mimic LN architecture. These will be injected, mixed with sponge-like scaffolds to provide porosity needed for immune cell infiltration. Programming of immune cell function will be accomplished by in vivo targeting- and proteolytic activation- of immunomodulators for fine-tuning, and to extend the life span of these local powerhouses. The innovative character of ARTimmune comes from: 1) novel fundamental immunological insight in complex communication within LN cell clusters, 2) a revolutionary new approach in immunotherapy, by the development of 3) injectable- and 4) programmable- synthetic immune niches by state-of-the-art chemical technology. When successful, it will revolutionize cancer immunotherapy, moving from maximal tolerable dose systemic treatment with significant toxicity to local low dose treatment in the direct vicinity of a tumour
Max ERC Funding
2 500 000 €
Duration
Start date: 2019-11-01, End date: 2024-10-31
Project acronym AsthmaPhenotypes
Project Understanding asthma phenotypes: going beyond the atopic/non-atopic paradigm
Researcher (PI) Neil Pearce
Host Institution (HI) LONDON SCHOOL OF HYGIENE AND TROPICAL MEDICINE ROYAL CHARTER
Call Details Advanced Grant (AdG), LS7, ERC-2014-ADG
Summary Fifteen years ago it was widely believed that asthma was an allergic/atopic disease caused by allergen exposure in infancy; this produced atopic sensitization and continued exposure resulted in eosinophilic airways inflammation, bronchial hyper-responsiveness and reversible airflow obstruction. It is now clear that this model is at best incomplete. Less than one-half of asthma cases involve allergic (atopic) mechanisms, and most asthma in low-and-middle income countries is non-atopic. Westernization may be contributing to the global increases in asthma prevalence, but this process appears to involve changes in asthma susceptibility rather than increased exposure to “established” asthma risk factors. Understanding why these changes are occurring is essential in order to halt the growing global asthma epidemic.This will require a combination of epidemiological, clinical and basic science studies in a variety of environments.
A key task is to reclassify asthma phenotypes. These are important to: (i) better understand the aetiological mechanisms of asthma; (ii) identify new causes; and (iii) identify new therapeutic measures. There are major opportunities to address these issues using new techniques for sample collection from the airways (sputum induction, nasal lavage), new methods of analysis (microbiome, epigenetics), and new bioinformatics methods for integrating data from multiple sources and levels. There is an unprecedented potential to go beyond the old atopic/non-atopic categorization of phenotypes.
I will therefore conduct analyses to re-examine and reclassify asthma phenotypes. The key features are the inclusion of: (i) both high and low prevalence centres from both high income countries and low-and-middle income countries; (ii) much more detailed biomarker information than has been used for previous studies of asthma phenotypes; and (iii) new bioinformatics methods for integrating data from multiple sources and levels.
Summary
Fifteen years ago it was widely believed that asthma was an allergic/atopic disease caused by allergen exposure in infancy; this produced atopic sensitization and continued exposure resulted in eosinophilic airways inflammation, bronchial hyper-responsiveness and reversible airflow obstruction. It is now clear that this model is at best incomplete. Less than one-half of asthma cases involve allergic (atopic) mechanisms, and most asthma in low-and-middle income countries is non-atopic. Westernization may be contributing to the global increases in asthma prevalence, but this process appears to involve changes in asthma susceptibility rather than increased exposure to “established” asthma risk factors. Understanding why these changes are occurring is essential in order to halt the growing global asthma epidemic.This will require a combination of epidemiological, clinical and basic science studies in a variety of environments.
A key task is to reclassify asthma phenotypes. These are important to: (i) better understand the aetiological mechanisms of asthma; (ii) identify new causes; and (iii) identify new therapeutic measures. There are major opportunities to address these issues using new techniques for sample collection from the airways (sputum induction, nasal lavage), new methods of analysis (microbiome, epigenetics), and new bioinformatics methods for integrating data from multiple sources and levels. There is an unprecedented potential to go beyond the old atopic/non-atopic categorization of phenotypes.
I will therefore conduct analyses to re-examine and reclassify asthma phenotypes. The key features are the inclusion of: (i) both high and low prevalence centres from both high income countries and low-and-middle income countries; (ii) much more detailed biomarker information than has been used for previous studies of asthma phenotypes; and (iii) new bioinformatics methods for integrating data from multiple sources and levels.
Max ERC Funding
2 348 803 €
Duration
Start date: 2016-01-01, End date: 2020-12-31
Project acronym AVATAR
Project Integrating Genomics and Avatar Mouse Models to Personalize Pancreatic Cancer Treatment
Researcher (PI) Manuel HIDALGO MEDINA
Host Institution (HI) HOSPITAL UNIVERSITARIO DE FUENLABRADA
Call Details Advanced Grant (AdG), LS7, ERC-2014-ADG
Summary The prognosis of patients with metastatic pancreatic cancer (PDAC) is very poor. Recent studies have started to elucidate the genetic landscape of this disease to show that PDAC is a genetically complex, unstable, and heterogeneous cancer. However, in-depth analysis of individual patient genomes couple with personalize Avatar mouse models is providing highly effective therapeutic opportunities for the individual patient. Thus, metastatic PDAC appears a candidate disease to implement a genomics-base, personalized treatment approach. In this project, we will conduct an open label, multicenter, randomized phase III study in patients with standard of care resistant metastatic pancreatic cancer aiming to test the hypothesis that an integrated personalized treatment approach improves survival compare to a conventional treatment. Patients randomized to the personalize treatment arm will undergo a biopsy of a metastatic lesion to perform a targeted genome analysis using next generation sequencing. In addition, we will generate a personalize Avatar mouse model from the same patient. We will employ sophisticated bioinformatic analysis as well as mining of drug response-genetic databases to select, for each individual patient, candidate therapeutic targets that will be experimentally tested in the patient´s Avatar model to select the most effective regimen that will ultimately applied to the patient. In addition, based on the genomic data, we will design an individualized monitoring plan for each patient using BEAMing technology to monitor circulating levels of mutated genes. Furthermore, with a discovery goal, we will perform in depth genomic analysis of metastatic PDAC lesions in this cohort of clinically well-annotated patients with Avatar mouse models for therapeutic validation. Overall we expect this work will contribute to our understanding of PDAC and will favourably impact the treatment of this dismal cancer.
Summary
The prognosis of patients with metastatic pancreatic cancer (PDAC) is very poor. Recent studies have started to elucidate the genetic landscape of this disease to show that PDAC is a genetically complex, unstable, and heterogeneous cancer. However, in-depth analysis of individual patient genomes couple with personalize Avatar mouse models is providing highly effective therapeutic opportunities for the individual patient. Thus, metastatic PDAC appears a candidate disease to implement a genomics-base, personalized treatment approach. In this project, we will conduct an open label, multicenter, randomized phase III study in patients with standard of care resistant metastatic pancreatic cancer aiming to test the hypothesis that an integrated personalized treatment approach improves survival compare to a conventional treatment. Patients randomized to the personalize treatment arm will undergo a biopsy of a metastatic lesion to perform a targeted genome analysis using next generation sequencing. In addition, we will generate a personalize Avatar mouse model from the same patient. We will employ sophisticated bioinformatic analysis as well as mining of drug response-genetic databases to select, for each individual patient, candidate therapeutic targets that will be experimentally tested in the patient´s Avatar model to select the most effective regimen that will ultimately applied to the patient. In addition, based on the genomic data, we will design an individualized monitoring plan for each patient using BEAMing technology to monitor circulating levels of mutated genes. Furthermore, with a discovery goal, we will perform in depth genomic analysis of metastatic PDAC lesions in this cohort of clinically well-annotated patients with Avatar mouse models for therapeutic validation. Overall we expect this work will contribute to our understanding of PDAC and will favourably impact the treatment of this dismal cancer.
Max ERC Funding
2 498 688 €
Duration
Start date: 2015-10-01, End date: 2020-09-30
Project acronym BARCODE
Project The use of genetic profiling to guide prostate cancer targeted screening and cancer care
Researcher (PI) Rosalind Anne Eeles
Host Institution (HI) THE INSTITUTE OF CANCER RESEARCH: ROYAL CANCER HOSPITAL
Call Details Advanced Grant (AdG), LS7, ERC-2013-ADG
Summary "Prostate cancer is the commonest solid cancer in men in the European Community. There is evidence for genetic predisposition to the development of prostate cancer and our group has found the largest number of such genetic variants described to date worldwide. The next challenge is to harness these discoveries to advance the clinical care of populations and prostate cancer patients to improve screening and target treatments. This proposal, BARCODE, aims to be ground-breaking in this area. BARCODE has two components (1) to profile a population in England using the current 77 genetic variant profile and compare screening outcomes with those from population based screening studies to determine if genetics can target screening more effectively in this disease by identifying prostate cancer that more often needs treatment and (2) genetically profiling men with prostate cancer in the uro-oncology clinic for a panel of genes which predict for worse outcome so that these men can be offered more intensive staging and treatment within clinical trials. This will use next generation sequencing technology using a barcoding system which we have developed to speed up throughput and reduce costs. The PI will spend 35% of her time on this project and she will not charge for her time spent on this grant as she is funded by The University of London UK. The research team at The Institute Of Cancer Research, London, UK is a multidisciplinary team which leads the field of genetic predisposition to prostate cancer and its clinical application and so is well placed to deliver on this research. This application will have a dramatic impact on other researchers as it is ground –breaking and state of the art in its application of genetic findings to public health and cancer care. It will therefore influence the work being undertaken in both these areas to integrate genetic profiling and gene panel analysis into population screening and cancer care respectively."
Summary
"Prostate cancer is the commonest solid cancer in men in the European Community. There is evidence for genetic predisposition to the development of prostate cancer and our group has found the largest number of such genetic variants described to date worldwide. The next challenge is to harness these discoveries to advance the clinical care of populations and prostate cancer patients to improve screening and target treatments. This proposal, BARCODE, aims to be ground-breaking in this area. BARCODE has two components (1) to profile a population in England using the current 77 genetic variant profile and compare screening outcomes with those from population based screening studies to determine if genetics can target screening more effectively in this disease by identifying prostate cancer that more often needs treatment and (2) genetically profiling men with prostate cancer in the uro-oncology clinic for a panel of genes which predict for worse outcome so that these men can be offered more intensive staging and treatment within clinical trials. This will use next generation sequencing technology using a barcoding system which we have developed to speed up throughput and reduce costs. The PI will spend 35% of her time on this project and she will not charge for her time spent on this grant as she is funded by The University of London UK. The research team at The Institute Of Cancer Research, London, UK is a multidisciplinary team which leads the field of genetic predisposition to prostate cancer and its clinical application and so is well placed to deliver on this research. This application will have a dramatic impact on other researchers as it is ground –breaking and state of the art in its application of genetic findings to public health and cancer care. It will therefore influence the work being undertaken in both these areas to integrate genetic profiling and gene panel analysis into population screening and cancer care respectively."
Max ERC Funding
2 499 123 €
Duration
Start date: 2014-10-01, End date: 2019-09-30
Project acronym Bio-Phononics
Project Advanced Microfluidics & Diagnostics using Acoustic Holograms – Bio-Phononics
Researcher (PI) Jonathan Cooper
Host Institution (HI) UNIVERSITY OF GLASGOW
Call Details Advanced Grant (AdG), LS7, ERC-2013-ADG
Summary This proposal seeks to develop a novel technique for fluid and particle manipulations, based upon exploiting the mechanical interactions between acoustic waves and phononic. The new platform involves generating surface acoustic waves (SAWs) on piezoelectric chips, but, unlike previous work, the ultrasonic waves are first coupled into a phononic lattice, which is placed in the path of the ultrasonic wave. The phononic lattice comprises a miniaturised array of mechanical elements which modulates the sound in a manner analogous to how light is “patterned” using a hologram. However, whilst in an optical hologram, the pattern is created by exploiting the differences in refractive indices of the elements of the structure, here the ultrasonic field is modulated both by the elastic contrast between the elements in the array, as well as by the dimensions of the array and its surrounding matrix (including the size and pitch of the features within the array). The result of passing the acoustic wave through a phononic crystal is the formation of new and complex ultrasonic landscapes.
As part of the proposed work we aim to understand the physics of this technology and to exploit its development in a range of medical devices. We will show that by using phononic crystals it is possible to create highly controllable patterns of acoustic field intensities, which propagate into the fluid, creating pressure differences that result in unique flow patterns to enable a new platform for including biological sample processing, medical diagnostics, drug delivery and blood clotting devices – all on low cost disposable devices. Different frequencies of ultrasound will interact with different phononic structures to give different functions, providing a toolbox of different functions. Just as in electronics, where discrete components are combined to create circuits, so we propose to combine different phononic lattices to create fluidic microcircuits with important new applications.
Summary
This proposal seeks to develop a novel technique for fluid and particle manipulations, based upon exploiting the mechanical interactions between acoustic waves and phononic. The new platform involves generating surface acoustic waves (SAWs) on piezoelectric chips, but, unlike previous work, the ultrasonic waves are first coupled into a phononic lattice, which is placed in the path of the ultrasonic wave. The phononic lattice comprises a miniaturised array of mechanical elements which modulates the sound in a manner analogous to how light is “patterned” using a hologram. However, whilst in an optical hologram, the pattern is created by exploiting the differences in refractive indices of the elements of the structure, here the ultrasonic field is modulated both by the elastic contrast between the elements in the array, as well as by the dimensions of the array and its surrounding matrix (including the size and pitch of the features within the array). The result of passing the acoustic wave through a phononic crystal is the formation of new and complex ultrasonic landscapes.
As part of the proposed work we aim to understand the physics of this technology and to exploit its development in a range of medical devices. We will show that by using phononic crystals it is possible to create highly controllable patterns of acoustic field intensities, which propagate into the fluid, creating pressure differences that result in unique flow patterns to enable a new platform for including biological sample processing, medical diagnostics, drug delivery and blood clotting devices – all on low cost disposable devices. Different frequencies of ultrasound will interact with different phononic structures to give different functions, providing a toolbox of different functions. Just as in electronics, where discrete components are combined to create circuits, so we propose to combine different phononic lattices to create fluidic microcircuits with important new applications.
Max ERC Funding
2 208 594 €
Duration
Start date: 2014-04-01, End date: 2019-03-31
