« We are working on the generation of 3D cellular microenvironments to reproduce Hematopoietic Niches. PRIMO will be used to generate 3D photo-polymerized microenvironments and to pattern them to localize different cell populations involved in the hematopoiesis. »
Before PRIMO, we used deep UV photolithography through a chromium mask or pulsed UV laser writing to locally remove the PEG adsorbed on the surface of the sample. However, the quality of the pegylation has to be high, and sometimes some bad contact between the mask and the PEG surface may generate blurry patterns or defects on the passivation.
We initially chose to use PRIMO because it allows sequential multi patterning and makes gradient patterning possible. It works with a broad range of scale and its design creation is limitless.
The technology is reproducible and robust after good practical and highly performant to prototype designs or protein combinations.
Technical support as well as scientific support are very nice for installation and beginning of new project.
Testimonial completed with Benoit Vianay, CEA Engineer at the Physics of cytoskeleton & Morphogenesis lab (Cytomorpholab)
« My interest is to understand the role of biophysical and topological properties of tissue microenvironments, such as stem cell niches, in modulating cell fate. Thus, the ability to precisely tune and control extracellular cell/organelle shape and geometry in 2D and 3D, is of critical importance. PRIMO has been incredibly useful in this regard! »
« The main interest of the Tardieux’s laboratory and my PhD project is to decipher how forces drive the unique motile and invasive capacities of the single-celled eukaryotic parasite Toxoplasma gondii. I was able to uncover that the parasite glides by coupling polar adhesions and de-adhesion with traction and dragging forces. The PRIMO technique was needed to create composite patterns with a non-adhesive area next to an adhesive one with the crucial request of a sharp demarcation. »
« Our aim is to develop in vitro experimentation to decipher guiding mechanisms involved in vivo. PRIMO technology is particularly adapted to design in vitro microdevices patterned with controlled patches of the signaling proteins relevant for white blood cell migration. »
« We are interested in imaging subcellular localization of certain cell-surface receptors and check whether they colocalize with focal-adhesion complexes. For this purpose, we are interested in making different types of patterns of Fibronectin with subcellular dimensions. »
« My research project aims at unravelling how a T cell switches from a fast migratory state to a stationary state upon activation. To do so, I perform live cell imaging of T cells migrating inside micro-fabricated channels coated with activating molecules. However, with this approach, I do not control when and where a T cell encounters the activating molecules. »
« Protein micropatterning represents an excellent tool to probe the behavior and functions of cellular systems. PRIMO is specially suited for our experiments, in which the cell-substrate interaction needs to be precisely adjusted both throughout the substrates and in time, in order to control the dynamic behaviour of cell monolayers. »
« Our research is at the frontier of soft matter physics and process engineering. More precisely, we develop microfluidic tools to study industrial processes (mixing, flow, drying, filtration, etc.) involving soft matter systems such as polymers or colloids. We use PRIMO to integrate hydrogel membranes in microfluidic devices to mimic ultrafiltration and dialysis processes on the scale of a few nanoliters. »
Alvéole développe des outils innovants pour contrôler le microenvironnement sur les supports standards de culture cellulaire en 2D et 3D.
Notre équipe vous livre toutes ses astuces pour mener à bien vos expériences et aller encore plus loin !
Nos utilisateurs décrivent leurs projets de recherche et nous expliquent pourquoi ils ont choisi d’utiliser PRIMO !