%0 Generic
%A Oh, Jeong-Joo
%A Ammu, Satya
%A Vriend, Vivian
%A Kieffer, Roland
%A Kleiner, Friedrich
%A Balasubramanian, Srikkanth
%A Karana, Elvin
%A Masania, Kunal
%A Aubin-Tam, Marie-Eve
%D 2023
%T Data underlying the publication: Growth, Distribution, and Photosynthesis of Chlamydomonas reinhardtii in 3D Hydrogels
%U 
%R 10.4121/dbac218d-fca8-4c53-b39a-b7ebed3344ea.v1
%K Microalgae
%K hydrogel
%K 3D printing
%K spatial organization
%K functional living surface
%K CO2 consumption
%K engineered living material
%X <p class="ql-align-justify">Engineered living materials (ELMs) are a novel class of functional materials that typically feature spatial confinement of living components within an inert polymer matrix to recreate biological functions. Understanding the growth and spatial configuration of cellular populations within a matrix is crucial to predicting and improving their responsive potential and functionality. Here, we investigate the growth, spatial distribution, and photosynthetic productivity of eukaryotic microalga <em>Chlamydomonas reinhardtii</em> in three-dimensionally shaped hydrogels in dependence of geometry and size. The embedded<em> C. reinhardtii </em>cells photosynthesize and form confined cell clusters, which grow faster when located close to the ELM periphery due to favorable gas exchange and light conditions. Taking advantage of location-specific growth patterns, we successfully design and print photosynthetic ELMs with increased CO<sub>2</sub> capturing rate, featuring high surface to volume ratio. This strategy to control cell growth for higher productivity of ELMs resembles the already established adaptations found in multicellular plant leaves.</p>
%I 4TU.ResearchData