• What’s your scholar and professional background?

I originally have a Master’s degree in Genetics and Cell Biology with a specialization in BioImaging at the University of Lyon 1. Subsequently, I had the opportunity to carry out a thesis in Saint-Étienne, on the conservation of corneal grafts integrated into bioreactors. The objective was to improve the storage conditions of the grafts, in order to provide the patient with a better quality and with a significantly increased lifespan. My experiences in the biomedical field, and in the field of lasers, led me, following my thesis, to join a core facility specialized in femtosecond lasers, named Alphanov in nearby area of Bordeaux.

For almost two years, I worked as a research engineer developing a proof of concept to integrate femtosecond lasers into operating theaters for maxillofacial bone surgeries, with the aim of replacing saws and surgical hammers, very traumatic tools for patients during operations. After my position as a research engineer, I undertook an MBA (Master of Business Administration) in marketing and business development at the ESG Bordeaux business school with the aim of developing my functions.

• Why did you move from research to business?

I have always been interested in the business side of science. Originally, even before the obtention of my PhD, I wanted to enroll in a Technical-Commercial Engineering Master’s degree, with the aim of developing a dual skill in science and commerce. Ultimately, fate decided otherwise, but in reality, this ambition never really left my mind. If anything, the many interactions I’ve had with biomedical and pharmaceutical companies have only reinforced this idea over time.

The moment when I really decided to train in commerce and the valorization of science was during a discussion with surgeons at the Bordeaux University Hospital, an experience which, in my humble opinion, illustrates the purpose of research: to be able to reach and serve society.

For humanity to truly benefit from research projects, it is necessary to involve a plurality of actors and skills. Only in this way can we hope to exploit the work of scientists to their full potential.

• What kind of missions do you have? What’s your job’s objectives?

Researchers and research engineers carry out excellent work every day, demonstrating unrivaled expertise in their respective fields. However, science is a demanding art that requires total involvement. It becomes complicated to find the time to respond to funding or to participate in the co-construction of collaboration with manufacturers who have sometimes restrictive specifications. My role is to relieve facilities and academic laboratories that wish to collaborate with industrials. In a nutshell, my overall objective is to create win-win collaborations, bringing tangible benefits, both scientifically and financially, to the platforms and laboratories integrated into France-BioImaging.

• What’s your vision about the future of core facilities and research infrastructures?

Research infrastructures represent essential tools in a scientific and technological environment that is constantly becoming more complex, especially in an increasingly demanding economic context. They offer their members valuable support by promoting the pooling of technologies and knowledge and by providing undeniable financial advantages. However, in my opinion, each research infrastructure is still missing an essential characteristic: a common culture, a true feeling of belonging, while respecting the specific identity of each entity that composes it.

If we can unify these cultures and encourage mutual understanding and effective cooperation, then research infrastructures can realize their full potential. Indeed, the best technologies and knowledge, when used individually, cannot match the potential and results that sharing and cooperation between platforms and research laboratories can offer.

• What do you expect from this new professional adventure?

This work is located at the border between the worlds of science, commerce, communication and valorization/innovation. Professionally speaking, it is a real opportunity to be at the interface of these very different but complementary fields of work. My main ambition in this professional adventure is to be able to serve as a bridge between actors and expertise coming from various professional backgrounds, and to succeed in mobilizing collaborations that are beneficial for all parties involved.

Persistent prejudices about the academic and industrial sectors can sometimes generate resistance to possible collaborations, even though they could lead to exceptional results. Having the opportunity to consolidate or establish contacts between these two worlds, with all the benefits that will ensue, represents both my greatest expectation and one of the greatest challenges of this adventure.

Samy will be happy to work with you! Contact him: samy.al-bourgol@france-bioimaging.org

Following the final decision of France-BioImaging Institutional Committee on February 27^th, 2024, we are delighted to announce that two new nodes are joining France-BioImaging: the Normandie Node and the Rhône-Alpes Node.

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The new Normandie Node is composed of one imaging facilities: PRIMACEN. The node has also six highly visible R&D teams (from COBRA, IRIB, Cyceron, GlycoMEV and SCALE) expert in microscopy techniques and tools.

Mainly located in Rouen and distributed to Caen and Le Havre, the Normandie node is offering high level technical and innovative methodological expertise in multi-scale imaging at the interface between biology, chemistry, optics and physics, from the atom to the small animal/plant.

The Normandie Node has expertise in vascular sciences, microalgal biosciences and intercellular communication. Moreover, they are in a strong collaboration with the International master program in cell imaging where students are intensively trained on PRIMACEN equipment and have the opportunity to go abroad thanks to a cooperation with Finland.

The node provides cutting-edge technologies and methodologies, with among others:

• STED, FLIM and combination of STED-FLIM for fixed and living cells to study in particular cell-to-cell connections such as Tunneling NanoTubes (TNTs) in PC12, HBEC, H28, MCF-7 cells.
• Complementary heart advanced light imaging including confocal micro- and macroscopy, light-sheet microscopy and image analysis to study microvascular and lymphatic dysfunction.
• New multimodal probes to study vascular brain diseases: reporter fusion proteins to track tPA, biodegradable and ultrasensitive microprobes, contrast agent that is targeted to adhesion molecules such as p-selectin, V-CAM1 (Vascular cell adhesion protein 1) and mucosal vascular addressin cell adhesion molecule 1 (MAdCAM-1).
• Advanced light microscopy and TEM imaging to study microalgae as a cell factory including morphotypes characterization, subcellular localization of molecular actors involved in the N-glycosylation pathway (GDP-Fucose transporter, Fucosyltransferase and GnT I located in the Golgi apparatus).
• New organic fluorophores and new chemobiology tools: 3-Benzoylquinoxalinone, Fluorophore-assisted click chemistry through copper(I) complexation, Epicocconone-hemicyanine hybrids and Indazole merocyanines.

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The new Rhône-Alpes node is composed of two core facilities: LyMIC in Lyon and ISDV in Grenoble. Gathered into one entity, LyMIC consists of three core facilities providing advanced photonic, atomic force and advanced electron microscopies. ISDV comprises five photonic microscopy facilities and three electron microscopy experts. Moreover, six R&D teams complete the node and supports the facility (from ILM, LiPHY, IAB, ENS-Lyon and GIN).

The Rhône-Alpes node aims to maintain the level of scientific excellence in response to the needs of users and the concerns of host laboratories. Four scientific axes are conducted: imaging, quantifying and controlling cell metabolism; biomechanics from molecules to tissues; spatial transcriptomic; and 3D multiscale imaging.

The node provides cutting-edge technologies and methodologies, with among others:

• The project Confobright (Adaptive Optics for Quantitative Confocal Microscopy-AOQCM) has been designed to correct for optical aberrations, making deeper, better resolved and more sensitive confocal and multiphoton imaging in optically heterogeneous tissues.
• The project Quantifret is a new calibration and analysis method allowing for quantitative FRET imaging in living cells with a simple fluorescence microscope, giving absolute FRET values, independent of the instrument or the expression level, and usable confidently by non-specialists.
• Eternity buffer, launched as Everspark by Idylle in 2021 is distributed worldwide (20 countries) to more than 100 researchers (80% abroad including 20% in the States). It represents a major breakthrough in the field due to its long lasting life (several weeks against 2 hours for classical GLOX).
• FluoRef calibration beads, renamed SpheroRuler by Idylle, is under ß-testing program until the end of January. These 1 µm beads are coated with a fluorophore emitting in the far red channel suitable to blink in dSTORM buffer for calibration imaging on 2D and 3D super-resolution microscopes.
• An integrated service of methods to measure forces and elastic properties in plants and insect models (through coupling of AFM and confocal imaging).
• The pipe-line for analysis of deep 3D EM data (FIB-SEM +/- Cryofixation) with the easily accessible integration of multiple aspects of segmentation, training of dedicated IA network and export of characteristic quantitative parameters.

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Welcome to the FBI Normandie Node and the FBI Rhône-Alpes Node!

We would like to introduce to you one of our France-BioImaging external users: Sonhita Chakraborty! Post doctoral researcher at the Umeå Plant Science Center, in Sweden, she is interested in studying how plant can adapt to temperature stresses in a context of climate change.

As she needed high-end imaging technology and expertise to move her research to the next step, Sonhita has asked for access to one of France-BioImaging core facilities, the Bordeaux Imaging Center.

Meet her in this short video and see how it was a great experience both scientifically and humanly!

You can now apply for a new call to get free open access to instruments and services at one of our nodes’ core facility!

We are happy to announce the 2nd Open Call from the Horizon Europe-funded CanSERV project! Cancer Researchers are invited to apply for FREE state-of-the-art services and training at several European Research Infrastructures, including Euro-BioImaging ERIC. Within this project, 28 Euro-Bioimaging Nodes (- Yes, France-BioImaging is part of it too! -) offer access to their expertise. It’s an amazing opportunity for the cancer research community to access a wide-ranging portfolio of services.

All user projects – ranging from basic discovery science to translational science and into personalised oncology on any type of cancer –  are eligible. The total indicative funding volume of this call is 1 Million Euro across the entire canSERV consortium.

The full call text, including user guidelines and other useful information, and the canSERV catalog of services are linked here and can be accessed via canserv.eu and via eurobioimaging.eu/content/canserv.

Submission deadline is May 21st, 2024, 14:00 CEST.

Phase 1 submissions for the Light My Cells challenge are now open to participants! This is a preliminary test phase to prepare for the final phase and familiarize participants with the algorithm submission procedure, with the possibility of making five submissions up to March 30.

Would you like to take part? Registration is open until March 30!

What is the challenge?

The Light My Cells France-Bioimaging challenge aims to contribute to the development of new image-to-image ‘deep-label’ methods in the fields of biology and microscopy. Basically, the goal is to predict the best-focused output-images of several fluorescently labelled organelles from label-free transmitted light input-images. And we need you for that!

More information about the challenge: lightmycells.grand-challenge.org/lightmycells

How to participate

We have defined the challenge as a single task with two phases:

• A preliminary test phase (on 30 images) to familiarize with the algorithm submission procedure, with the possibility to have five submissions (with a maximum of one by week)
• The final test phase (on 300 images) with only one submission accessible will not give the possibility to evaluate their algorithms before submitting.

So, you have until the end of the first phase, on March 21, 2024, to register and participate at this Light My Cells challenge.

Register now! lightmycells.grand-challenge.org/lightmycells

Prizes

For top 3 winners:

• Award certificate
• A challenge paper will be written with the organizing team’s members for submission to journals
• Invitation to publish their methods in the proceedings of the IEEE International Symposium on Biomedical Imaging 2024s
• Support and integration of open source code into open science image processing and analysis software (e.g. BioImage Model Zoo, Napari)

For the 1st: 

• Invitation to 2024 France-Bioimaging annual meeting
• Graphic card
• Android tablet

For the 2nd:

• Graphic card
• Android tablet

For the 3rd:

• Android tablet

Why launching a challenge?

To develop powerful methods that will then end up in creating public databases, standards & benchmarks in the field of bioimaging! The FBI challenge is hinged on a double contribution: from core facilities engineers and from data scientists. The first group acquired a large number of images to build a dataset, that will later be used by the algorithms. These images were produced by microscopy engineers & technicians from FBI’s platforms. As for the second contribution, this is where the challenge starts! The challenge is then published to have a maximum of data scientists to work on the algorithms that best fulfill the analysis task.

The first project is also based on four pillars:

• Open source + FAIR (Findable, Accessible, Interoperable, Reusable)
• Supervised learning, it involves annotated datasets to maintain control over performances.
• In silico annotations, a computer labeling method to avoid manual annotation and its drawbacks.
• Image-to-image analysis tasks, an image analysis tasks which aim to predict an output image from the input one.

For any questions, please contact Dorian Kauffmann: dorian.kauffmann@france-bioimaging.org.

The LCI core facility at Karolinska Institutet has the pleasure to invite you to follow the microscopy course called Microscopy: improve your imaging skills – from sample preparation to image analysis.

The course starts next Monday (29 Jan) and runs until the 16^th of February.

As usual, all the course lectures are broadcasted live on Zoom. It is free of charge and you do not need to register.

The aim for this course is to improve the microscopy skills of students and researchers who have already used a microscope to acquire digital images of fluorescent samples but feel that more knowledge could help them.

Here is a selection of what we will talk about:

• Optics and image formation,
• Anatomy of a microscope
• Objectives and refraction index
• Cameras and detectors, Noise and background, Bit depth and saturation
• Sample preparation, Immunostaining, Clearing and expansion
• Resolution and contrast, Nyquist sampling, Microscope settings
• Data handling, OMERO.figure, Requirements for image analysis, Colocalization
• Image processing and analysis

More information: https://ki.se/en/bionut/lci-microscopy-course