Fluorescent nanodiamonds for characterization of nonlinear microscopy systems.
Mantas ZurauskasAneesh AlexJaena ParkSteve R HoodStephen A BoppartPublished in: Photonics research (2021)
Characterizing the performance of fluorescence microscopy and nonlinear imaging systems is an essential step required for imaging system optimization and quality control during longitudinal experiments. Emerging multimodal nonlinear imaging techniques require a new generation of microscopy calibration targets that are not susceptible to bleaching and can provide a contrast across the multiple modalities. Here, we present a nanodiamond-based calibration target for microscopy, designed for facilitating reproducible measurements at the object plane. The target is designed to support day-to-day instrumentation development efforts in microscopy laboratories. The images of a phantom contain information about the imaging performance of a microscopy system across multiple spectral windows and modalities. Since fluorescent nanodiamonds are not prone to bleaching, the proposed imaging target can serve as a standard, shelf-stable sample to provide rapid reference measurements for ensuring consistent performance of microscopy systems in microscopy laboratories and imaging facilities.
Keyphrases
- high resolution
- single molecule
- optical coherence tomography
- high speed
- high throughput
- label free
- magnetic resonance imaging
- quantum dots
- magnetic resonance
- hydrogen peroxide
- quality improvement
- cross sectional
- chronic pain
- working memory
- contrast enhanced
- deep learning
- convolutional neural network
- pain management
- fluorescent probe