13C-Breath testing is increasingly used in physiology and ecology research because of what it reveals about the different fuels that animals oxidize to meet their energetic demands. Here we review the practice of 13C-breath testing in humans and other animals and describe the impact that contamination that ambient/background CO 2 in the air can have on the accuracy of 13C-breath measurements. We briefly discuss physical methods to avoid sample contamination as well as the Keeling plot approach that researchers have been using for the past two decades to estimate δ 13C from breath samples mixed with ambient CO 2. Unfortunately, Keeling plots are not suited for 13C breath testing in common situations where 1) a subject’s VCO 2 is dynamic 2) ambient [CO 2] may change, 3) a subject is sensitive to hypercapnia, or 4) in any flow-through indirect calorimetry system. As such, we present a mathematical solution that addresses these issues by using information about the instantaneous [CO 2] and the δ 13CO 2 of ambient air as well as the diluted breath sample to back-calculate the δ 13CO 2 in the CO 2 exhaled by the animal. We validate this approach by titrating a sample of 13C-enriched gas into an air stream and demonstrate its ability to provide accurate values across a wide range of breath and air mixtures. Researchers can now instantaneously calculate the δ 13C of alveolar gas of humans or animals in real time without having to scrub ambient CO 2 or rely on estimated values.