Tomographic-Encoded Multiphoton Microscopy

Axial scanning in multiphoton microscopy (MPM) is typically realized by mechanically shifting either the objective or the sample. However, the scan speed is usually hindered by the mechanical inertia of the bulky mass. Although the extended depth of field provided by the non-diffracting beam allows fast volumetric imaging, it abandons the axial resolution. Here, we demonstrate a novel and powerful tomographic technique using the Bessel droplet in MPM, termed tomographic-encoded multiphoton (TEMP) microscopy, for structural illumination in the axial direction. We show that benefiting from the high-order nonlinear excitation in MPM, the side-lobe cancellation and smaller beam focus of the Bessel droplet realize better image quality. TEMP microscopy allows fast axial scanning, less risks of photodamage and photobleaching, and high-resolution and high-contrast imaging. Furthermore, fewer raw images are required for the 3D image reconstruction. To demonstrate its usability and advantages for scattering tissues and biomedical applications, we showcase TEMP microscopy with highly scattering fluorescence microspheres and mouse brain slice. More details can be visualized by the Bessel droplet compared with the conventional Gaussian and Bessel beam. The depth-resolving performance of the Bessel droplet has an excellent consistency with the Gaussian beam. More importantly, the TEMP technique is an easy-plug-in method for the current microscopy system. TEMP microscopy is promising for fast volumetric multiphoton imaging, especially for highly scattering tissues.