Single-cell entrapment and microcolony development within uniform microspheres amenable to flow cytometry

Abstract

A method is presented for encapsulating single microbial cells in small spheres suitable for analysis and sorting by flow cytometry. The entrapped cells are able to multiply and form colonies contained within their respective microspheres. The system is based on ejecting the cells suspended in a gellable liquid through an orifice vibrating at ultrasonic frequencies, thus shearing the cell-containing jet into uniform droplets. When low-melting-temperature agarose was used, the droplets could be gelled into solid spheres during flight by appropriately directed colling air streams. This gelling was accompanied by significant dehydration, resulting in a twofold decrease in bead diameter and a corresponding increase in agarose concentration. Nevertheless, the microbeads obtained were highly uniform and had diameters which could be precisely controlled in the range of 10 to 40 microns. A variety of bacterial and yeast species were entrapped in agarose beads by using this system. In all cases the cells were able to develop into microcolonies containing as many as several hundred cells. This system enables one to apply the powerful method of flow cytometry to the analysis and sorting of whole microbial colonies. Potential applications of this technology in various areas of microbiology are considered.