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SAFe-nSCAN: more accurate analysis for cancer treatment

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Visualising how molecules interact within their three-dimensional environment is essential in cell and tissue screening procedures used in therapies for cancer treatment. However, most current imaging technologies of this type lack spatial resolution and quantitative molecular profiling capabilities. Moreover, there is no single quantitative tissue imaging instrument today that can perform analysis on several complementary scales, from tissue to molecule, with high levels of speed, throughput and accuracy.

To overcome these limitations, the European nanoSCAN project was set up, coordinated by the French CNRS (Centre National de la Recherche Scientifique), of which Politecnico di Milano is a member via its Department of Physics. The five project partners are developing the innovative SAFe-nSCAN imaging platform, which will combine multi-scale optical microscopy solutions: from structured illumination microscopy for rapid inspection and classification of cells and tissues to single-molecule localisation microscopy techniques for more accurate 3D nanoscopic investigations of pre-selected regions.

The goal is to develop the first platform capable of providing imaging at all scales, from tissue to sub-molecule, via a single machine.

The nanoSCAN project is funded by the EU (European Innovation Council) with EUR 2.49 million. 

The project website

iBeChange project kicks off

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iBeChange (Addressing Psychosocial and Lifestyle Risk Factors to Promote Primary Cancer Prevention: An Integrated Platform to Promote Behavioural Change) kicks off: the project funded by the European Union under the Horizon Europe programme aims to design, develop and test an innovative platform, a user-oriented management system that enables people to behave in healthy and sustainable ways.

A working team from the Department of Electronics, Information and Bioengineering of the Politecnico di Milano, coordinated by Prof. Francesco Trovò and Prof. Emilia Ambrosini, will participate in the project together with experts in clinical and health psychology, oncology, epidemiology, ICT, data science and health policy.

The project will combine practice-based and evidence-based knowledge from clinical psychology and behavioural change theories with the potential of adaptive digital technologies and artificial intelligence. Therefore, the iBeChange system will be able to dynamically observe, learn from user behaviour and provide personalised and effective healthcare interventions. The iBeChange project aims to help achieve the objectives of the European Plan Against Cancer and the European Code Against Cancer by improving long-term primary cancer prevention through information, support and empowerment of EU citizens.

The project consortium includes universities (University of Palermo, TU Eindhoven), medical institutes (European Institute of Oncology, Institut Catala d’Oncologia) and industries (Eurecat, Sporedata).

3D personalized model of biliary tract cancer

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It is only a few centimeters in size and can be held between two fingers, but in the micro-channels carved inside it, it’s hidden a three-dimensional and highly faithful model of a biliary tract cancer called cholangiocarcinoma, complete with its tumor microenvironment.

This 3D model is built starting from a sample of patient’s cancer cells and thus it represents a patient-specific “organ-on-chip”: a technology made possible only through a multidisciplinary approach that merges biomedicine, physics and engineering.

The innovative prototype is the result of the collaboration between Ana Lleo De Nalda, Full Professor at Humanitas University and head of the Hepatobiliary Immunopathology Laboratory at Humanitas Research Hospital, and Marco Rasponi, Associate Professor at Politecnico di Milano and head of the Laboratory of Microfluidics and Biomimetic Microsystems.

The study was made possible thanks to the collaboration with the group of Prof. Guido Torzilli, Director of the Department of General Surgery and head of the Hepatobiliary Surgery Unit of the IRCCS Istituto Clinico Humanitas.

The ultimate goal of the device is to accelerate research on cholangiocarcinoma by providing a new laboratory model that better mimics what we observe in patients. At the same time, it will help advancing precision medicine, since it could be potentially used as a personalized drug-testing platform, helping predict patients’ response to therapies.

Ana Lleo and Marco Rasponi

The study was funded by AIRC – the Italian Foundation for Cancer Research, and was published in the Journal of Hepatology Reports.

What is cholangiocarcinoma

Cholangiocarcinoma is a rare cancer of the liver (it affects about 5,500 people in Italy alone, each year) and it derives from a malignant transformation of cholangiocytes, the cells lining the biliary tract.

Unfortunately, the disease is often diagnosed at an advanced stage, because patients show very few symptoms. This is also why treatments are often ineffective: at the time of diagnosis, only 10-30% of patients are eligible to undergo surgical removal of the tumor.

Precisely because of the reduced therapeutic options and high mortality of cholangiocarcinoma, we need new in vitro models that can recapitulate the characteristics of the disease and in particular the interaction between tumor cells and cells of the immune system, which play a key role in its progression and response to drugs.

Ana Lleo

A 3D platform for advancing research and personalized medicine

Now, for the first time, researchers from Humanitas and Politecnico di Milano developed a personalized 3D model of the disease.

It is a microfluidic chip a few centimeters in size. Inside the device, in the micrometer channels realized using advanced photolithographic techniques, we seeded cancer cells sampled from patients affected by cholangiocarcinoma. The cells successfully reproduced the tumor architecture in vitro.

Marco Rasponi

In a series of experiments, the team of researchers demonstrated that the device faithfully recapitulates what we observe in individual patients, both in terms of T-cell activation, that correlates with tumor infiltration, and in terms of therapeutic response to different drugs, based on the characteristics of cancer recurrence.

We are very happy with the result obtained, which was only possible thanks to the combination of different expertise and knowledge.

The next steps will be to further optimize and improve the device, both as a research model and as a personalized drug-testing platform.

Ana Lleo and Marco Rasponi

We want to add cells of innate immune system, such as macrophages, which play an important role in tumor progression, and introduce micro-pumps that can mimic blood flow and vascularization. We also need to test it on larger groups of patients, to confirm its ability to recapitulate the phenomena we observe in the clinical setting.

Results on the Journal of Hepatology Reports

Pioneering study sheds light on poorly understood aspect of cancer

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A new scientific study published in the journal Science Advances has investigated a still poorly understood aspect of cancer, therapy-induced senescence in tumor cells. The study, the result of collaboration between researchers from Politecnico di Milano, Johns Hopkins University in Baltimore, the National Cancer Institute in Milan, and the National Research Council, expands our understanding of cancer biology and paves the way for future therapeutic advancements.

The team worked to uncover the biological mechanisms behind the formation of “therapy-induced senescent” (TIS) cells, a small percentage of treated tumor cells that exhibits resistance to conventional therapies (chemotherapy and radiation therapy), leading to tumor quiescence and ultimately, recurrence.

This result is a clear example of how cutting-edge technologies, multidisciplinary expertise, and strong international collaborations are crucial in addressing the most pressing biological questions, such as the early reaction mechanisms of tumor cells to anticancer therapies.

Arianna Bresci, first author of the study and doctoral student at Department of Physics

Researchers utilized advanced optical microscopy techniques, combining three-dimensional holograms of tumor cells with ultra-short pulses of laser light. They explored both the chemical and morphological aspects of TIS cells in human tumors, without the use of invasive techniques, preserving the natural state of the cells.

The research group was able to distinguish key features of TIS cells in human tumor cells: the reorganization of the mitochondrial network, overproduction of lipids, cell flattening, and enlargement. By analyzing a considerable number of cells, researchers established a clear timeline for the development of these distinctive signs.

This discovery may lead to applications in the development of personalized treatments and the possibility of refining current screening protocols for oncology therapy.

Our findings provide important insights into the complex world of TIS in human tumor cells. In our laboratory at Politecnico di Milano, we have developed a new non-invasive laser microscope that has allowed us to understand the initial stages of this phenomenon.

Dario Polli, associate professor at Department of Physics and coordinator of the study 

Diagnosing prostate cancer using an “electronic nose”

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The Diag-Nose experimental project, the result of a collaboration between Humanitas and the Politecnico di Milano, aims to develop a method for diagnosing prostate cancer that is non-invasive and more accurate than traditional procedures

It is an electronic nose that is capable of detecting a tumour by analysing a urine sample and identifying specific volatile molecules. 

The results of the first trials, which have been published in the International Journal of Urology, are encouraging: the test correctly determines the presence of a tumour in cancer patients in 85.2% of cases and correctly gives a negative result for healthy patients in 79.1% of cases. The accuracy is significantly better than that of traditional diagnostic methods; indeed, biopsies have a tumour detection rate of 48.5% at most. 

Furthermore, the prototype has other significant benefits when compared to a biopsy: in addition to being an invasive procedure, biopsies have a particularly high rate of false negatives for early-stage tumours due to the fact that only a small portion of tissue is collected and analysed.

The study, conducted between March 2020 and March 2021 at Humanitas Mater Domini in Castellanza and the Humanitas Research Hospital in Rozzano, involved 174 people divided into two groups: 88 patients with prostate cancer of varying grades and stages confirmed by a histological examination, and 86 people in a “control” group comprising men and women of different ages with no history of the disease who had undergone medical examinations. A urine sample was collected from each person and analysed at the laboratories of Professor Laura Capelli at the Politecnico di Milano’s Department of Chemistry, Materials and Chemical Engineering, whose research group was also responsible for building the prototype of the instrument

The electronic nose is the evolution of a study conducted in 2012 by Humanitas with the collaboration of the Military Veterinary Centre in Grosseto (Cemivet) and supported by the Italian Ministry of Defence, which revealed how dogs, once properly trained, are able to detect prostate cancer by smelling patients’ urine.  

The electronic nose developed as part of the Diag-Nose project is therefore a prototype created by reproducing the canine sense of smell, built using a series of sensors that are capable of analysing the volatile substances released into the air by urine samples.

TROPHY project kicks off

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Activities related to the TROPHY (ulTRafast hOlograPHic FT-IR microscopY) project have officially started. TROPHY is a research project, funded by the European Commission under the Horizon Europe programme, which aims to develop a novel label-free vibrational microscopy approach for cancer diagnosis.

Cancer diagnosis is traditionally done on intraoperative frozen tissue sections by post-surgical histopathologic analysis and, in selected cases, by elaborated and time-consuming molecular diagnosis. The analysis of the biopsy is performed through the staining of the tissue and the evaluation of the morphology of its cells under an optical microscope. This approach is neither fast nor quantitative, has an intrinsic variability in the interpretation depending on the experience of the histopathologist, and provides limited molecular information.

The microscope developed thanks to the TROPHY project will image molecular biomarkers with unprecedented speed and chemical selectivity for a rapid, precise, and non-biased tumor analysis. To this purpose, it will blend in a unique fashion elements of several microscopies developed in the past decades, namely photo-thermal infrared, Fourier transform infrared and Digital Holography Microscopy, bringing them to the unprecedented ultrafast timescale. It will also integrate Artificial Intelligence to produce fast results and assist in the tumour grading process even during surgery.

This microscope will be used to assist healthcare professionals during tumor biopsy diagnostics, provide an accurate diagnosis for curative oncosurgery, guarantee complete resection during intervention, determine the best therapeutic approach tailored to the patient, and identify resistant tumor clones under targeted therapy, paving the way for continual precision medicine in cancer.

The project is coordinated by the Politecnico di Milano with Prof. Marco Marangoni from the Department of Physics as scientific coordinator. The other project partners are Fundacio Institut de Ciences Fotoniques (ICFO, Spain), Consiglio Nazionale delle Ricerche (CNR, Italy), Lyncee Tec SA (LT, Switzerland), Universtaetsklinikum Jena (JUH, Germany), University of Exeter (UNEXE, UK), University of Cambridge (UCAM, UK).

AI-based personalized medical care for lung cancer patients

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I3LUNG is a new research initiative that aims to create a cutting-edge decision-making tool to aid both clinicians and patients in selecting the best lung cancer treatment plan, tailored to the specific needs and situation of each individual patient.

Lung cancer was the leading cause for cancer deaths in men and the second for women in 2020, with 370000 deaths in Europe alone. The consortium has thought out and developed this project to address the primary unmet clinical need in the field of non-small cell lung cancer (NSCLC), which is the lack of biomarkers predicting the response of affected patients to immunotherapy (IO)-based treatments.

The project will use artificial intelligence (AI), in particular deep and machine learning methodologies (DL and ML) to analyze a wide range of information such as baseline clinical features, radiomics, and available biological characteristics of the tumor.

I3LUNG and its partners will have a timeframe of 5 years and a €10M budget to turn their project’s hypothesis in a tangible tool and a new clinical reality. I3LUNG is the first platform enrolling such an important number of patients in both a retrospective (2,000) and prospective (200) manner including such a diversity of multiomic data, arising as an innovative and promising technology to provide an answer to the unmet clinical need of translational research data integration and AI use.

This project is envisioned to both generate novel therapeutic guidelines for clinical practice in lung cancer and support the growth of digital diagnostic tools. AI will push the standard of care towards a more personalized approach for each individual cancer patient. If successful, the approach presented in I3LUNG could in the near future be extended to other cancer types.

The team of the Politecnico di Milano, which combines computer science and biomedical engineering experts, aims to study together with medical partners if and how Artificial Intelligence can become an actor in the complex path of therapy selection. The goal is to develop artificial intelligent solutions that are not only capable of accuracy and precision, but also an understandable interlocutor, at the service of clinical experts, their knowledge and experience and worthy of trust for patients.

Prof. Alessandra Pedrocchi of the Department of Electronics, Information and Bioengineering, project coordinator for our university

The partners in the consortium I3LUNG are: 

  • Fondazione IRCCS Istituto Nazionale dei Tumori(INT, Milano, Italia) with Dr Arsela Prelaj as coordinator of the Consortium
  • Politecnico di Milano(POLIMI, Milano, Italia)
  • Istituto di Ricerche Farmacologiche Mario Negri (IRFMN, Milano, Italia)
  • Istituto Europeo di Oncologia (IEO; Milano, Italia)
  • ML Cube(Milano, Italia)
  • LungenClinic Grosshansdorf GmbH (GHD, Grosshansdorf, Germania)
  • Universitaetsklinikum Hamburg-Eppendorf (UKE, Amburgo, Germania)
  • Vall d’Hebron Instituteof Oncology (VHIO, Barcellona, Spagna)
  • Medica Scientia Innovation Research (MEDSIR, Barcellona, Spagna & New Jersey, USA)
  • Metropolitan Hospital (MH, Pireo, Grecia)
  • Shaare Zedek Medical Center (SZMC, Gerusalemme, Israele)
  • Katholieke Universiteit Leuven (KUL, Leuven, Belgio)
  • Institutet for Halso-OCH Sjukvardsekonomi Aktiebolag (IHE, Lund, Svezia)
  • University of Chicago (UOC, Chicago, USA)
  • Aalborg Universitet (AAU, Aalborg, Danimarca)
  • Lung Cancer Europe (LUCE, Bern, Svizzera)

ERC Advanced Grant to Manuela Raimondi with Beaconsandegg

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Manuela Raimondi, professor at the Department of Chemistry, Materials and Chemical Engineering “Giulio Natta”, will work on BEACONSANDEGG (Mechanobiology of cancer progression), a project that combines mechanobiology with bioengineering, oncology, genetics, microtechnology, biophysics and pharmacology in order to develop an innovative platform capable of recapitulating tumour fibrosis by exploiting the vascularisation of a living organism.

In breast cancer, aggressiveness is related to fibrotic stiffening of the tumour tissue. Fibrosis progressively prevents drugs from reaching the tumour cells, due to the formation of a matrix with mechanical properties that stabilise the tumour’s vascular network. However, the hierarchy and stability of the tumour vascular network are not reproducible in vitro.

The BEACONSANDEGG research will model microtumours at various levels of fibrosis. Human breast cancer cells adhered to 3D polymeric microplates will be used. The microtumours will be implanted in vivo in the respiratory membrane of embryonated avian eggs in order to elicit a fibrotic foreign body reaction in the microtumours. The geometry of the 3D microsupports will be manipulated to condition the infiltration of the microtumours by the vessels and cells of the embryo.

This study model will be validated with anticancer drugs whose clinical outcome is known to depend on the level of tumour fibrosis.

This project will also provide a standardised and ethical platform to promote the clinical translation of new therapeutic products in oncology.

Our university once again proves to be at the forefront, having outperformed its scholarly competitors in a very competitive selection process, with only 14.6% of the 1735 projects submitted receiving funding. With this project, the Politecnico di Milano has been awarded a total of 86 European Individual Grants (including ERC and Marie Curie).

Researcher Cristina Chirizzi wins the brainy 2021 call

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Cristina Chirizzi, a postdoc researcher at the Department of Chemistry, Materials and Chemical Engineering “Giulio Natta” at the Politecnico di Milano, has won a scholarship worth €30,000 awarded by Brainy, an association that supports research into brain diseases and neuroscience and which last November published a call for young researchers to finance research projects focused on investigating the reasons leading to the onset of brain tumours in order to be able to fight and treat them in the best possible way.

The project presented by Dr Chirizzi, in collaboration with the Carlo Besta Neurological Institute, is focused on developing technical advances for the visualisation of tumour margins during neurosurgery for the removal of one of the most aggressive forms of malignant brain tumour, glioblastoma. An alternative to the fluorescent biomarkers currently used in the intraoperative setting was therefore proposed, with the aim of increasing their specificity for tumour tissues.

The winner was presented with her award by the association on 21 February 2022 at the Politecnico.

Dr Chirizzi studied Molecular Biotechnology in Turin, where she obtained her Laurea Magistrale (equivalent to Master of Science) in 2013. She took her Ph.D. at the San Raffaele Hospital, where she studied and analysed the development of methods based on magnetic resonance for the visualization of immune cell activity during neuroinflammation processes. She is currently a postdoctoral researcher at the Politecnico di Milano, where she has focused her research on the development of biomaterials and nanosystems for biological applications.

A revolution in the diagnosis and treatment of cancer

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CHARM is a project aiming to develop a medical device based on high-speed, low-cost Raman digital imaging technology and artificial intelligence to transform cancer diagnosis and treatment.

The technology will analyse the molecular composition of patient tissue samples to distinguish cancerous from healthy cells without the need for chemical staining.

CHARM’s Raman imaging technology uses graphene-based ultra-fast fibre lasers to generate digital images of patient tissue for automatic analysis by artificial intelligence to support diagnosis. Because the images are digital, they can be viewed remotely, allowing histopathologists to work more efficiently and to support regions and countries short of qualified staff. The technology also potentially opens the way for personalised treatments for cancer.

The partners involved are Cambridge Raman Imaging Ltd. (CRI), a polimi spin-off, the University of Cambridge, Consiglio Nazionale delle Ricerche, Politecnico Di Milano, the Jena University Hospital (Germany) and the firms INsociety (Italy) and Inspiralia (Spain). The project coordinator is Dr Matteo Negro, CRI’s Chief Technology Officer.

CHARM is one of the 42 projects selected for a €3.3 million funding from 292 submitted in the first ever EIC (European Innovation Council) Transition Challenges, intended to support moving technologies from laboratories into the real world. The EIC is Europe’s flagship innovation programme to identify, develop and scale up breakthrough technologies and game changing innovations. In the case of CHARM, it aims to develop medical devices to the preclinical validation phase.

Politecnico di Milano, who pioneered the high-speed Raman imaging technology, will be responsible for the development of the microscope and the detection system.

I am excited to contribute to the translation of the results of our scientific studies into a commercial product which promises to significantly improve cancer diagnosis and therapy and have an important societal impact. To foster a close link between fundamental research and technological innovation is one of our main missions as academics and lies at the core of the EIC.

Prof. Giulio Cerullo, head of the ultrafast spectroscopy laboratory at Politecnico di Milano

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