Photoswitching-Enabled Novel Optical Imaging: Innovative Solutions for Real-World Challenges in Fluorescence Detections

Because of its ultrasensitivity, fluorescence offers a noninvasive means to investigate biomolecular mechanisms, pathways, and regulations in living cells, tissues, and animals. However, real-world applications of fluorescence technologies encounter many practical challenges. For example, the intrinsic heterogeneity of biological samples always generates optical interferences. High background such as autofluorescence can often obscure the desired signals. Finally, the wave properties of light limit the spatial resolution of optical microscopy. The key to solving these problems involves using chemical structures that can modulate the fluorescence output. Photoswitchable fluorescent molecules that alternate their emissions between two colors or between bright-and-dark states in response to external light stimulation form the core of these technologies. For example, molecular fluorescence modulation can switch fluorophores on and off. This feature supports super-resolution, which enhances resolution by an order of magnitude greater than the longstanding diffraction-limit barrier. The reversible modulation of such probes at a particular frequency significantly amplifies the frequency-bearing target signal while suppressing interferences and autofluorescence. In this Account, we outline the fundamental connection between constant excitation and oscillating fluorescence. To create molecules that will convert a constant excitation into oscillating emission, we have synthesized photoswitchable probes and demonstrated them as proofs of concept in super-resolution imaging and frequency-domain imaging. First, we introduce the design of molecules that can convert constant excitation into oscillating emission, the key step in fluorescence modulation. Then we discuss various technologies that use fluorescence modulation: super-resolution imaging, dual-color imaging, phase-sensitive lock-in detection, and frequency-domain imaging. Finally, we present two biological applications to demonstrate the power of photoswitching-enabled fluorescence imaging. Because synthetic photoswitchable probes can be much smaller, more versatile, and more efficient at high-performance modulation experiments, they provide a complement to photoswitchable fluorescent proteins. Although new challenges remain, we foresee a bright future for photoswitching-enabled imaging and detection.