Edward B. Samson scite author profile

Goldschmidt

Whiteside

et al. 2012

J. Opt.

Malaria affects over 200 million individuals annually, resulting in 800,000 fatalities. Current tests use blood smears and can only detect the disease when 0.1–1% of blood cells are infected. We are investigating the use of photoacoustic flowmetry to sense as few as one infected cell among 10 million or more normal blood cells, thus diagnosing infection before patients become symptomatic. Photoacoustic flowmetry is similar to conventional flow cytometry, except that rare cells are targeted by nanosecond laser pulses to induce ultrasonic responses. This system has been used to detect single melanoma cells in 10 ml of blood. Our objective is to apply photoacoustic flowmetry to detection of the malaria pigment hemozoin, which is a byproduct of parasite-digested hemoglobin in the blood. However, hemozoin is difficult to purify in quantities greater than a milligram, so a synthetic analog, known as β-hematin was derived from porcine haemin. The specific purpose of this study is to establish the efficacy of using β-hematin, rather than hemozoin, for photoacoustic measurements. We characterized β-hematin using UV-vis spectroscopy, TEM, and FTIR, then tested the effects of laser irradiation on the synthetic product. We finally determined its absorption spectrum using photoacoustic excitation. UV-vis spectroscopy verified that β-hematin was distinctly different from its precursor. TEM analysis confirmed its previously established nanorod shape, and comparison of the FTIR results with published spectroscopy data showed that our product had the distinctive absorbance peaks at 1661 and 1206 cm−1. Also, our research indicated that prolonged irradiation dramatically alters the physical and optical properties of the β-hematin, resulting in increased absorption at shorter wavelengths. Nevertheless, the photoacoustic absorption spectrum mimicked that generated by UV-vis spectroscopy, which confirms the accuracy of the photoacoustic method and strongly suggests that photoacoustic flowmetry may be used as a tool for diagnosis of malaria infection.

Total internal reflection photoacoustic spectroscopy for the detection of β-hematin

et al. 2012

Abstract. Evanescent field sensing methods are currently used to detect many different types of disease markers and biologically important chemicals such as the HER2 breast cancer receptor. Hinoue et al. used Total Internal Reflection Photoacoustic Spectroscopy (TIRPAS) as a method of using the evanescent field to detect an optically opaque dye at a sample interface. Although their methods were successful at detecting dyes, the results at that time did not show a very practical spectroscopic technique, which was due to the less than typical sensitivity of TIRPAS as a spectroscopy modality given the low power (∼1 to 2 W) lasers being used. Contrarily, we have used an Nd:YAG laser with a five nanosecond pulse that gives peak power of 1 MW coupled with the TIRPAS system to increase the sensitivity of this technique for biological material sensing. All efforts were focused on the eventual detection of the optically absorbing material, hemozoin, which is created as a byproduct of a malarial infection in blood. We used an optically analogous material, β-hematin, to determine the potential for detection in the TIRPAS system. In addition, four properties which control the sensitivity were investigated to increase understanding about the sensor's function as a biosensing method.

Total internal reflection photoacoustic detection spectroscopy

Sudduth

Goldschmidt

et al. 2011

The coordinating role of IQGAP1 in the regulation of local, endosome-specific actin networks

Tsao

Zimak

et al. 2017

IQGAP1 is a large, multi-domain scaffold that helps orchestrate cell signaling and cytoskeletal mechanics by controlling interactions among a spectrum of receptors, signaling intermediates, and cytoskeletal proteins. While this coordination is known to impact cell morphology, motility, cell adhesion, and vesicular traffic, among other functions, the spatiotemporal properties and regulatory mechanisms of IQGAP1 have not been fully resolved. Herein, we describe a series of super-resolution and live-cell imaging analyses that identified a role for IQGAP1 in the regulation of an actin cytoskeletal shell surrounding a novel membranous compartment that localizes selectively to the basal cortex of polarized epithelial cells (MCF-10A). We also show that IQGAP1 appears to both stabilize the actin coating and constrain its growth. Loss of compartmental IQGAP1 initiates a disassembly mechanism involving rapid and unconstrained actin polymerization around the compartment and dispersal of its vesicle contents. Together, these findings suggest IQGAP1 achieves this control by harnessing both stabilizing and antagonistic interactions with actin. They also demonstrate the utility of these compartments for image-based investigations of the spatial and temporal dynamics of IQGAP1 within endosome-specific actin networks.

Coordinating Role of IQGAP1 in the Regulation of Multivesicular Endosomal Compartment Dynamics

Schweikhard

Tsao

et al. 2017

Biophysical Journal

binding to the fibers obtained only when multiple holoenzyme subunits are engaged (Khan et al. 2016. Biophys. J.111,395-408). We have now measured the binding of GFP-CaMKII molecules to rhodamine-phalloidin labeled, single F-actin filaments and characterized the architectural transitions of the formed filament networks to mechano-osmotic stress. CaMKII induced formation of mechanically-resilient networks with aster-like nodes. Cryo-electron tomography showed CaMKII localized in small clusters (n < 5) at the nodes. Although nodes disappeared rapidly upon addition of calcium calmodulin, the network structure took several minutes to dissipate. Both C. elegans and human CaMKIIs formed networks at stoichiometric concentrations, revealing an evolutionary-conserved interaction. At the micromolar concentrations investigated, CaMKII-actin bundles were sparsely distributed in the networks. Macromolecular crowding by addition of polyethylene glycol or force generated by addition of myosin motors plus ATP bundled the filaments; but CaMKII retarded, rather than assisted, this transition. CaMKII also protected against filament fragmentation by motor forces. We propose that stimulationtriggered disruption of spine CaMKII-actin interactions has two distinct effects, formation of a compliant F-actin network primarily due to loss of nodal contacts and polymerization of the released G-actin. We are simulating these processes in a 3-dimensional ''virtual'' spine to determine CaMKII, G and F-actin concentrations and affinities that best mimic the observed spine dynamics upon stimulation.