Part 1: Principles of membrane potential-imaging. Historical overview and general methods of membrane potential-imaging
Design and use of organic voltage-sensitive dyes
Part 2: Membrane potential signals with single cell resolution. Imaging sub millisecond membrane potential changes from individual regions of single axons, dendrites and spines
Combining membrane potential imaging with other optical techniques
Monitoring spiking activity of many individual neurons in invertebrate ganglia
Part 3: Monitoring activity of networks and large neuronal populations. Monitoring integrated activity of individual neurons using fret-based voltage-sensitive dyes
Monitoring population membrane potential signals from neocortex
Voltage imaging in the study of hippocampal circuit function and plasticity
Monitoring population membrane potential signals during development of the vertebrate nervous system
Imaging the dynamics of mammalian neocortical population activity in-vivo
Imaging the dynamics of neocortical population activity in behaving and freely moving mammals
Part 4: Monitoring membrane potential in the heart. History of cardiac optical imaging
Imaging of ventricular fibrillation and defibrillation: the virtual electrode hypothesis
Optical mapping of ventricular fibrillation dynamics
Bio photonics modelling of cardiac optical imaging
Towards depth-resolved optical imaging of cardiac electrical activity
Part 5: New approaches, potentials and limitations
Two-photon excitation of fluorescent voltage-sensitive dyes: monitoring membrane potential in the infrared
Random-access multi photon microscopy for fast three-dimensional imaging
High spatial resolution microscopy using holographic illumination
Second harmonic imaging of membrane potential
Genetically encoded protein sensors of membrane potential.