WindSTORM: Robust online image processing for high-throughput nanoscopy

High-throughput nanoscopy becomes increasingly important for unraveling complex biological processes from a large heterogeneous cell population at a nanoscale resolution. High-density emitter localization combined with a large field of view and fast imaging frame rate is commonly used to achieve a high imaging throughput, but the image processing speed and the presence of heterogeneous background in the dense emitter scenario remain a bottleneck. Here, we present a simple non-iterative approach, referred to as WindSTORM, to achieve high-speed high-density emitter localization with robust performance for various image characteristics. We demonstrate that WindSTORM improves the computation speed by two orders of magnitude on CPU and three orders of magnitude upon GPU acceleration to realize online image processing, without compromising localization accuracy. Further, WindSTORM is highly robust to maximize the localization accuracy and minimize the image artifacts in the presence of nonuniform background. WindSTORM paves the way for next generation high-throughput nanoscopy.

WindSTORM: Robust online image processing for high-throughput nanoscopy

High-throughput nanoscopy becomes increasingly important for unraveling complex biological processes from a large heterogeneous cell population at a nanoscale resolution. High-density emitter localization combined with a large field of view and fast imaging frame rate is commonly used to achieve a high imaging throughput, but the image processing speed in the dense emitter scenario remains a bottleneck. Here we present a simple non-iterative approach, referred to as WindSTORM, to achieve high-speed high-density emitter localization with robust performance for various image characteristics. We demonstrate that WindSTORM improves the computation speed by two orders of magnitude on CPU and three orders of magnitude upon GPU acceleration to realize online image processing, without compromising localization accuracy. Further, due to the embedded background correction, WindSTORM is highly robust in the presence of high and non-uniform background. WindSTORM paves the way for next generation of high-throughput nanoscopy.

Application of qualitative biospeckle methods for the identification of scar region in a green orange

This study demonstrates the feasibility of a view-based method, the motion history image (MHI) to map biospeckle activity around the scar region in a green orange fruit. The comparison of MHI with the routine intensity-based methods validated the effectiveness of the proposed method. The results show that MHI can be implementated as an alternative online image processing tool in the biospeckle analysis.

A Photoelastic Tactile Sensor to Measure Contact Pressure Distributions on Object Surfaces

This paper describes the development of a tactile sensor that measures contact pressure distribution (CPD) within a sensor probe that emulates the human fingertip. The aim of development is to provide CPDs plausible enough to be utilized in performance evaluation or parameter calibration of a tactile softness display. The developed sensor system observes twodimensional photoelasticity of the finger-shaped sensor probe in a circular polariscope setup and visualizes CPDs using online image processing. Through considerations of sensor probe design and material, the sensor visualized CPDs on various surfaces with a spatial resolution of 2 mm and up to 2 N of contact force. Experimental results demonstrate the capability of the sensor to discriminate among given soft samples by different CPDs.