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3D-printed imaging device for education and microbial research

29.07.2024 - A low-cost imaging system for near-infrared fluorescence detection of phototrophic cell colonies.

Researchers at the University of Jyväskylä have developed an imaging device for schools and research centres to study microbes. The 3D-printed device “NIRis” enables schools to observe and study natural phenomena. Researchers will gain useful and new knowledge about the light-activated bacteria. The “Shared Light” project at the University of Jyväskylä aims to understand the role of photosynthetic bacteria inside plants and utilizes citizen science.

“Seven different high-schools across Finland, from Utsjoki to Turku, collected hundreds of plant samples for the researchers who then isolated bacteria from the plants,” tells project researcher Ole Franz from the University of Jyväskylä. In order to facilitate fast detection of the bacterio­chlorophyll-containing bacterial colonies of interest, the researchers developed a low-cost imaging device, a “Near-infrared imaging system” (NIRis) to analyze bacteria. NIRis has two imaging modes resulting in an overlay of all bacteria colonies and selectively identified near-infrared fluorescent colonies. The identified bacteria can then be easily isolated for further studies. The 3D-printed device houses regular flashlights and detects bacterial colonies with a small raspberry pi computer and camera module.

The aim was to keep the costs low and make it easy to operate. The low costs – less than thousend euros – and easy operation allowed production of multiple devices so they could be sent to high-schools parti­cipating in the project, says Heikki Häkkänen, the main designer of NIRis from the University of Jyväskylä. NIRis makes it possible to realize new types of multi­disciplinary research and teaching at schools and research institutes. Teachers could utilize the device for example in biology, physics, programming, material design or even art education.

“This is a great opportunity for teachers to link regular courses to relevant academic research and investigate materials collected from nature,” says Kati Heikkilä-Huhta, the coor­dinating teacher from Oulu Steiner school. The project is looking forward to continue developing courses and research projects which utilize this type of devices. As of now, the Shared Light research group has used NIRis to isolate over 1000 new strains of photo­trophic bacteria from a variety of plants in different seasons and locations.

The easy detection allowed sampling of large collections and accelerated our research considerably. This is especially exciting as the prevalence of this type of bacteria in and on plants has been very little studied, especially with culti­vation-based approaches, explains Riitta Nissinen, University lecturer from University of Turku. As a pheno­menon this is highly interesting if one thinks that inside plants exist bacteria which also perform bacterial photo­synthesis. Here, they do not produce sugars, but only chemical energy utilizing light energy, continues professor in nanosciences Janne Ihalainen from University of Jyväskylä. (Source: U. Jyväskylä)

Reference: O. Franz et al.: NIRis: A low-cost, versatile imaging system for near-infrared fluorescence detection of phototrophic cell colonies used in research and education, PLoS ONE 19, e0287088 (2024): DOI: 10.1371/journal.pone.0287088

Link: Nanoscience Center, Dept. of Biological and Environmental Science, University of Jyväskylä, Jyväskylä, Finland

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