We evaluated a microelectromechanical systems (MEMS) microsensor array with temperature-controlled chemi-resistive elements for use as a noninvasive clinical diagnostic tool to detect the presence or absence of trace amounts of disease biomarkers in simulated breath samples. The microsensor environment was periodically altered between air (78% N₂, 21% O₂ by volume, 20% relative humidity) and simulated breath (77% N₂, 16% O₂, 4% CO₂ by volume, 80% relative humidity) samples creating a dynamic background. Acetone, a disease marker for diabetes, was spiked into select simulated breath samples at relevant concentrations ( 0.5 ¿mol/mol to 8 ¿mol/mol) to pose a diagnostic problem for the sensor array. Using standard statistical dimensionality reduction and classification algorithms, we compared the ability of a variety of sensing materials to detect and recognize the disease marker. Our analyses indicate that the porous, doped nanoparticle materials (Sb:SnO₂ microshell films and Nb :TiO₂ nanoparticle films) are best for the recognition problem (acetone present versus absent), but that WO₃ and SnO₂ films are better at the quantification task (high versus low concentrations of acetone).