Understanding how sensory inputs are dynamically mapped onto the functional activity of neuronal populations and how their processing leads to cognitive functions and behaviour requires tools for non-invasive interrogation of neuronal circuits with high spatiotemporal resolution. However most of the existing tools suffer from low temporal resolution as they rely on scanning in space in one or more dimensions.
Light-field microscopy (LFM) is an imaging technique that allows capturing 3D information about a sample simultaneously, i.e. without scanning in space. In contrast to conventional imaging schemes, a light-field microscope captures both the 2D location and 2D angle of the incident light. This is done by placing a microlens array in the native image plane such that sensor pixels capture the rays of the light field simultaneously. Such 4D light fields allow the synthesis of a focal stack computationally, making it possible to capture a whole volume with one snapshot.
In our recent paper we showed, that LFM combined with deconvolution leads to enhanced spatial resolution making Light-field deconvolution microscopy (LFDM) a versatile tool for high-speed volumetric calcium imaging of entire brains at single neuron resolution. We demonstrate this by applying our technique to functional imaging of entire C. elegans and whole-brains of zebrafish larvae.
We used transgenic worms expressing the Ca2+-sensor GCaMP5K in a pan-neuronal and nucleus- bound fashion and custom-designed microfluidic devices to restrain the worms while imaging the worm. Doing so we were able to simultaneously record activity from about 70 neurons located in the head of the worm at the same time with neurons in the ventral cord region sending signals to the mussels. Overall we could capture activity of neurons in a volume of 350um x 350 um x 24 um at 50Hz volume rate (see video below).
The identities of a number of these neurons could be determined using the worm atlas (see figure):
In order to highlight the temporal resolution and the broader applicability of our technique for capturing dynamics of large populations of spiking neurons, we performed Ca2+ imaging in live zebrafish larvae brains expressing the Ca2+ indicator GCaMP5 pan-neuronally. Employing a 20× objective, we demonstrated whole-brain Ca2+ imaging for volumes spanning ~700 μm × 700 μm × 200 μm at a 20-Hz volume rate (see video). In this case we could recover spatially resolved cellular signals over the entire time series using standard signal extraction and unmixing techniques. Implementing this approach, we extracted neuronal activity for ~5,000 cells across the brain and followed their fast Ca2+ transients on a millisecond timescale (see figure).
By applying an aversive odor to the fish, we evoked neuronal activity and inferred dynamics of Ca2+ signals across the olfactory system, the midbrain and parts of the hindbrain, results consistent with previous demonstrations of the neuronal dynamics in these regions. The high temporal resolution of the LFDM revealed subtle differences in the exact timing of the onset of the response for different groups of neurons located close to each other (see figure). Whereas the neurons in each group exhibited a nearly synchronous onset of their activity, the collective response of each group was delayed with respect to those of the other groups.
Robert Prevedel, Young-Gyu Yoon, Maximilian Hoffmann, Nikita Pak, Gordon Wetzstein, Saul Kato, Tina Schrödel, Ramesh Raskar,Manuel Zimmer,Edward S Boyden and Alipasha Vaziri (2014) Simultaneous whole-animal 3D imaging of neuronal activity using light-field microscopy