LIFE SCIENCE AND MEDICINE

Providing quantitative and morphological measurements, quantitative phase imaging (QPI) is the perfect label-free live-cell imaging technique to characterize and monitor cells. With unprecedented contrast and ease of use, it gives access to the geometry, volume, mass and other phenotypic characteristics of unlabelled specimens. 

The Phasics patented QWLSI method is the only easy-to-integrate QPI technology. Compatible with any standard microscope, our camera-like instruments are easily integrated as an add-on imaging technique. Upgrade your high-content screening platform with our powerful QPI systems and monitor cell cultures over long periods of time.

Perform parallel and automated label-free drug perturbation assays thanks to Phasics' innovative QPI instruments. With a seamless integration into any laboratory or existing imaging platform, our camera-like instruments allow monitoring critical characteristics of cell cultures over extended periods of time.

Long-term non-invasive live-cell imaging of the immune system lets you observe and analyze interactions of T cells, immune system cells, and cancer cells. Phasics' QPI systems provide high contrast and quantitative information that can be monitored over extended periods of time and then combined to provide insightful observations.

Combining high resolution, unprecedented contrast, and wide field of view, Phasics' QPI systems allow precisely measuring morphology, volume, and mass of cells. It is then easy to extract statistical information from single-shot images and perform classifications among large cell populations.

With their unique high resolution, sensitivity, and contrast, Phasics' QPI systems help you explore cellular metabolism. Combined with advanced algorithms, they can track small vesicles movements and analyze intra-cellular dynamics.

Providing unrivalled contrast and quantitative measurements, the Phasics QPI label-free technique is an excellent complementary imaging modality to standard fluorescence microscopy. Easy merging between both modalities with one single instrument allows for immediate comparative study and gives access to extended knowledge while requiring less sample preparation.

With its unique quantitative measurements summarizing the global content of cells and their phenotypic response to environmental conditions, QPI gives access to more information about the imaged specimen. Coupled with advanced algorithms, QPI is enriching the available knowledge on eggs and sperm cells and can help with assessing or predicting embryo viability and IVF performance.

The laser light-controlled thermoplasmonic effect is at the core of photothermal therapy for cancer treatment. The precise control and measurement of the temperature distribution at the microscale generated by the excitation of metallic nano-structures is critical for these high-precision techniques. QPI has been proven to precisely monitor temperature changes in those configurations.