PT  - JOURNAL ARTICLE
AU  - Resulaj, Arbora
AU  - Rinberg, Dmitry
TI  - Novel Behavioral Paradigm Reveals Lower Temporal Limits on Mouse Olfactory Decisions
AID  - 10.1523/JNEUROSCI.4693-14.2015
DP  - 2015 Aug 19
TA  - The Journal of Neuroscience
PG  - 11667--11673
VI  - 35
IP  - 33
4099  - http://www.jneurosci.org/content/35/33/11667.short
4100  - http://www.jneurosci.org/content/35/33/11667.full
SO  - J. Neurosci.2015 Aug 19; 35
AB  - Temporal limits on perceptual decisions set strict boundaries on the possible underlying neural computations. How odor information is encoded in the olfactory system is still poorly understood. Here, we sought to define the limit on the speed of olfactory processing. To achieve this, we trained mice to discriminate different odor concentrations in a novel behavioral setup with precise odor delivery synchronized to the sniffing cycle. Mice reported their choice by moving a horizontal treadmill with their front limbs. We found that mice reported discriminations of 75% accuracy in 70–90 ms after odor inhalation. For a low concentration and nontrigeminal odorant, this time was 90–140 ms, showing that mice process odor information rapidly even in the absence of trigeminal stimulation. These response times establish, after accounting for odor transduction and motor delays, that olfactory processing can take tens of milliseconds. This study puts a strong limit on the underlying neural computations and suggests that the action potentials forming the neural basis for these decisions are fired in a few tens of milliseconds. SIGNIFICANCE STATEMENT Understanding how sensory information is processed requires different approaches that span multiple levels of investigation from genes to neurons to behavior. Limits on behavioral performance constrain the possible neural mechanisms responsible for specific computations. Using a novel behavioral paradigm, we established that mice can make decisions about odor intensity surprisingly fast. After accounting for sensory and motor delays, the limit on some olfactory neural computations can be as low as a few tens of milliseconds, which suggests that only the first action potentials across a population of neurons contribute to these computations.