Multispectral Imaging for Microchip Electrophoresis Enables Point-of-Care Newborn Hemoglobin Variant Screening

Introduction: Hemoglobin (Hb) disorders are among the world's most common monogenic diseases. Nearly 7% of the world's population carry Hb gene variants. Sickle cell disease (SCD) arises when hemoglobin variant mutations are inherited homozygously (HbSS) or paired with another β-globin gene mutation. Epidemiological modeling shows that universal screening could save the lives of up to 9.8 million newborns with SCD by 2050 with 85% born in sub-Saharan Africa (SSA). The World Health Organization (WHO) estimates that early diagnosis of SCD coupled with intervention programs would prevent 70% of existing SCD mortality. SCD newborn screening performed in centralized laboratories has dramatically reduced SCD mortality in resource-rich countries. SCD newborn screening requires sensitive detection of low levels of certain Hb variants (i.e., sickle Hb, HbS) in the context of high levels of expression of other Hb variants (i.e., fetal Hb, HbF). The current centralized tests used for newborn screening for SCD are high performance liquid chromatography (HPLC) and isoelectric focusing. However, in SSA and central India, where >90% of annual SCD births occur, newborn screening programs have not been implemented universally due to the cost and logistical burden of laboratory diagnostic tests. As a result, there is a need for affordable, portable, easy-to-use, accurate, point-of-care (POC) tests to facilitate decentralized hemoglobin testing in low-resource settings to enable nationwide newborn screening. Methods: We have leveraged the WHO listed Hb electrophoresis test and developed a POC electrophoresis microchip, Gazelle-Multispectral (Fig. 1A) that enables sensitive detection and identification of Hb types under both white and ultraviolet (UV-410nm) light illumination. We hypothesized that the high absorbance of Hb at UV wavelength would enhances the limit of detection and allow the detection of Hb types at low concentrations thus enabling SCD screening in newborns. To test this hypothesis, we have conducted clinical testing of over 321 subjects under the age of 6 months many with Hb variants including HbA (normal hemoglobin), HbF, HbS, and HbC (hemoglobin C variant) at Korle Bu Teaching Hospital, the largest public hospital in Ghana, under IRB-approved protocol. Results and Discussion: Separated Hb variants are imaged under both white light illumination (Fig. 1B) and UV light illumination (Fig. 1C). The acquired data under white light illumination demonstrates the natural red color of hemoglobin but does not have good enough sensitivity to detect low concentration Hb types (Fig. 1B). The acquired data under UV light illumination is used for sensitive and accurate identification and quantification of Hb variants (Fig. 1C&D), and to automatically generate report for result interpretation (Fig. 1E). Following the Standards for Reporting of Diagnostic Accuracy Studies guideline, 294 out of 321 (91.6%) tests were recognized as 'Valid', while 27 out of 321 (8.4%) tests were recognized as 'Inconclusive'. Gazelle-Multispectral determined Hb variant levels demonstrated high association with Person Correlation Coefficients of 0.97, 0.97, 0.89, and 0.94 for Hb A, Hb F, HbS, and HbC compared to HPLC. Bland-Altman analysis demonstrated high reproducibility with mean bias±1.96×standard deviation of 2.3%±11.4%, -2.7%±-13.3%, 0.8%±6.2%, and -0.3%±2.7%, for HbA, HbF, HbS, and HbC, respectively. Subjects with disease were identified at 100% sensitivity and specificity from normal subjects and subjects with trait. Additionally, subjects with trait were identified at 98.1% sensitivity and 97.0% specificity from normal subjects (Fig 1. Table). Conclusion: In summary, Gazelle-Multispectral imaging enables affordable and rapid identification of common Hb variants in newborns at the point-of-need. The Gazelle-Multispectral reader provide animated on-screen instructions with step-by-step guidance for test procedures to minimize user errors. The internally integrated data analysis algorithm automatically reports Hb type identification and quantification results in an objective and easily understandable manner. Gazelle-Multispectral is a versatile, mass-producible, multispectral detection-based electrophoresis platform for affordable, rapid, and accurate diagnostic and newborn screening programs for SCD at the POC in low resource settings where the prevalence of SCD is high. Figure 1 Figure 1. Disclosures An: Hemex Health: Consultancy, Patents & Royalties. Rocheleau: Hemex Health: Current Employment. Avanaki: Hemex Health: Current Employment. Thota: Hemex Health: Current Employment. Odame: Novartis: Other: Steering Committee; Global Blood Therapeutics: Other: DSMB; Novo Nordisk: Membership on an entity's Board of Directors or advisory committees. Gurkan: Hemex Health, Inc.: Current Employment, Patents & Royalties; Biochip Labs: Patents & Royalties; Dx Now Inc.: Patents & Royalties; Xatek Inc.: Patents & Royalties.

Nanoplasmonic Structure of a Polycarbonate Substrate Integrated with Parallel Microchannels for Label-Free Multiplex Detection

In this study, a multiplex detection system was proposed by integrating a localized surface plasmon resonance (LSPR) sensing array and parallel microfluidic channels. The LSPR sensing array was fabricated by nanoimprinting and gold sputter on a polycarbonate (PC) substrate. The polydimethylsiloxane (PDMS) microfluidic channels and PC LSPR sensing array were bound together through (3-aminopropyl)triethoxysilane (APTES) surface treatment and oxygen plasma treatment. The resonant spectrum of the LSPR sensing device was obtained by broadband white-light illumination and polarized wavelength measurements with a spectrometer. The sensitivity of the LSPR sensing device was measured using various ratios of glycerol to water solutions with different refractive indices. Multiplex detection was demonstrated using human immunoglobulin G (IgG), IgA, and IgM. The anti-IgG, anti-IgA, and anti-IgM were separately modified in each sensing region. Various concentrations of human IgG, IgA, and IgM were prepared to prove the concept that the parallel sensing device can be used to detect different targets.

One Pot and Facile Preparation of Pure ZnO and Cudoped Au-ZnO Nano-particles : Photocatalytic Properties

In this present work, a new synthesis process, named hydrothermal method, of hybrid Au-ZnO nanoparticles (Au-Zn1-xCuxO; where 0<x<1%) was presented and discussed in detail. Nanocrystals of copper doped zinc oxide in the presence of diethylene glycol (DEG) as solvent were synthesized using the One Pot and Facile new proposed synthesis process. The photocatalytic activities of the synthesized nanoparticles were tested and analyzed for the degradation of methylene blue (MB) under white light illumination. The performances of the synthesized Au-ZnO nanoparticles showed a pronounced enhancement compared to either pure ZnO nanoparticles or to undoped Au-ZnO nanocomposites. Various key parameters such a photocatalyst loading, the MB concentration, and type current gas have been systematically investigated on the catalytic activities of the as-prepared.

Are Sunglasses Proper for Driving? Investigation and Prototype for Public Testing

Background: Sunglasses safety is important regarding driving conditions and is requirement of sunglasses standard ISO 12312-1, for testing traffic light and visible transmittances on lenses. Methods: We have spectroscopically investigated 232 sunglasses regarding compliance with standard, in the 380 nm – 780 nm range, with 5nm steps. Category (0 – 4) were determined as well as Q factors, which evaluate color distortion for the vision on sunglasses. Furthermore, we developed a prototype for public to self-check sunglasses regarding safety for driving. Combination of white light illumination, 4-channels photo sensor detection and calculation, allows testing simultaneously the colors of traffic light, as well as the visible light transmittances (categories). Q factors are provided by the prototype. Results: Spectroscopy shows that 75.43% complies with ISO 12312-1:2013. Prototype was validated by testing 232 sunglasses, with trained user and 60 from this set were double-checked with non-trained users, and compared to spectroscopic measurements. Bland-Altman analysis presented non-significant biases and narrow 95 % limits of agreement within pre-defined tolerances, for all measurements. Only 2 samples differed in category measurement. Conclusions: Sunglasses on the market should adjust for driving conditions. Prototype it is a fine set up for guiding users on checking proper sunglasses for safe driving Significance: Immediate attention on checking sunglasses for driving conditions is needed.

Metallophilicity-Induced Clusterization: Single-Component White-Light Clusteroluminescence with Stimuli Responses

<p>The single-component white-light-emitting materials play an essential role in the next-generation solid-state lighting technology. Herein, linear gold(I) complex TPPGPA with conglobate trimer configuration trigged by aurophilic interactions in crystalline state was prepared to emit dual phosphorescent white-light emission, which also exhibited multi-stimuli responsive luminescent properties including thermochromism and mechanochromism. Specifically, the molecular packing mode and aurophilic interactions regulation were subtly taken as a functional relationship of the experimental correlation with emission. The results showed that the regulated aurophilic interactions and restriction of molecular motion were determined to be the precipitating factor and as a function of the wavelength and intensity, which is significant for the design guide about intelligent stimuli-responsive white-light emissive luminescent materials. Furthermore, their application in temperature-responsive white-light illumination was successfully demonstrated. </p>