This work presents a novel tool, the Continuous Flow Microspotter (CFM) and its use in patterning cellular microarrays of multiple cell types into the bottom of a tissue culture well. The CFM uses a system of isolated microfluidic channels to make an array of localized microspots of adhesion dependent cells in the bottom of a conventional tissue culture well. With this device we have created micropatterns of multiple cell lines in a single tissue culture well and used this system to conduct simultaneous cytotoxicity tests and recover dose survival curves in a parallel study. This mechanism of parallel testing allows the researcher to employ the use of positive and negative controls, as well as compare the chemical response of phenotypes in a tightly controlled microenvironment. For the experiments presented in this paper we have fabricated a CFM with a set of ten microchannels (five inlet channels and five outlet channels) to pattern a row of five microspots consisting of four cellular microspots and one empty spot for background measurements. Micropatterns containing a set of four different Chinese hamster ovarian cell (CHO) mutant phenotypes were deposited into the bottom of commercially available tissue culture wells then interrogated with mitomycin C, a chemotherapeutic agent. This study shows statistically significant (P < 0.05) hypersensitivity of the UV20 CHO mutant to a DNA interstrand cross-linking agent (mitomycin C). Because the CFM is also capable of depositing proteins and other biomolecules to the individual microspots of the array we foresee capabilities of the 48 microspot CFM to multiplex 48 cell types with 48 chemical reagents all within the confines of a 60 mm(2) area.