Carbon content and rate of dark respiration was determined on individual Strombidium capitatum (Leegard) Kahl cells uniformly labelled with ¹⁴C in culture. Isolated individuals were incubated in sterile medium in the dark for periods of up to 24h, and cumulative respired ¹⁴CO₂ was retained in an alkaline trap. Cell carbon varied by more than an order of magnitude and followed a bi-modal distribution. Small cells of 2 to 7 ng C cell^-1 respired at specific rates of 3 to 5% cell C h^-1, whereas large cells of 7 to 25 ng C cell^-1 respired at 1 to 2% cell C h^-1. Mortality was greater for small cells than for large ones, and was greatest during the first few hours. Small cells accounted for 40% of all cells at initial time, T ₀, whereas none of these survived a 16 h incubation. It is proposed that the rates of carbon-specific dark respiration observed for small cells compromise their ability to survive more than a few hours in the dark without food. The combination of influence of size (carbon content) together with differential proportions of small cells resulting from mortality contributed to considerable variance in carbon-specific respiration rates. When smaller and larger modal groups were considered separately, this variance was significantly reduced for both groups. Using this refined data, there was no significant starvation-induced reduction in carbon-specific rates. The mean rate remained at between 1.1 and 1.4% cell C h^-1 for large cells over the 24 h period, and between 3.8 and 4.1% cell C h^-1 for small cells over the 8 h of their survival. This observation for a planktonic mixotrophic ciliate contrasts with published observations for heterotrophic protists which have reported reduction of carbon-specific respiration rate with starvation.