Deep mouse brain two-photon near-infrared fluorescence imaging using a superconducting nanowire single-photon detector array

TL;DR

This paper introduces a novel superconducting nanowire single-photon detector array for near-infrared two-photon microscopy, enabling imaging depths over 1.1mm in vivo mouse brain tissue, surpassing previous limitations.

Contribution

The work presents the first integration of SNSPD arrays with SWIR 2PM, significantly improving deep tissue imaging capabilities in biological research.

Findings

Achieved imaging depth > 1.1mm in vivo mouse brain.

Demonstrated high efficiency and low dark counts of SNSPDs in SWIR.

Enabled seamless integration with existing 2PM systems.

Abstract

Two-photon microscopy (2PM) has become an important tool in biology to study the structure and function of intact tissues in-vivo. However, adult mammalian tissues such as the mouse brain are highly scattering, thereby putting fundamental limits on the achievable imaging depth, which typically resides around 600-800um. In principle, shifting both the excitation as well as (fluorescence) emission light to the shortwave near-infrared (SWIR, 1000-1700 nm) region promises substantially deeper imaging in 2PM, yet has proven challenging in the past due to the limited availability of detectors and probes in this wavelength region. To overcome these limitations and fully capitalize on the SWIR region, in this work we introduce a novel array of superconducting nanowire single-photon detectors (SNSPDs) and associated custom detection electronics for the use in near-infrared 2PM. The SNSPD array exhibits high efficiency and dynamic range, as well as low dark-count rates over a wide wavelength range. Additionally, the electronics and software permit seamless integration into typical 2PM systems. Together with a fluorescent dye emitting at 1105 nm, we report imaging depth of > 1.1mm in the in-vivo mouse brain, limited only by available labeling density and laser power. Our work further establishes SWIR 2PM approaches and SNSPDs as promising technologies for deep tissue biological imaging.