Your search keyword '"McKendry RA"' showing total 7 results

1. Thermodynamic analysis of an entropically driven, high-affinity nanobody-HIV p24 interaction.

Author

Brookes JC, Gray ER, Loynachan CN, Gut MJ, Miller BS, P S Brogan A, and McKendry RA

Subjects

Humans, Thermodynamics, Entropy, Amino Acids metabolism, Protein Binding, Calorimetry, Single-Domain Antibodies, HIV Infections

Abstract

Protein-protein interactions are fundamental to life processes. Complementary computational, structural, and biophysical studies of these interactions enable the forces behind their specificity and strength to be understood. Antibody fragments such as single-chain antibodies have the specificity and affinity of full antibodies but a fraction of their size, expediting whole molecule studies and distal effects without exceeding the computational capacity of modeling systems. We previously reported the crystal structure of a high-affinity nanobody 59H10 bound to HIV-1 capsid protein p24 and deduced key interactions using all-atom molecular dynamics simulations. We studied the properties of closely related medium (37E7) and low (48G11) affinity nanobodies, to understand how changes of three (37E7) or one (48G11) amino acids impacted these interactions; however, the contributions of enthalpy and entropy were not quantified. Here, we report the use of qualitative and quantitative experimental and in silico approaches to separate the contributions of enthalpy and entropy. We used complementary circular dichroism spectroscopy and molecular dynamics simulations to qualitatively delineate changes between nanobodies in isolation and complexed with p24. Using quantitative techniques such as isothermal titration calorimetry alongside WaterMap and Free Energy Perturbation protocols, we found the difference between high (59H10) and medium (37E7) affinity nanobodies on binding to HIV-1 p24 is entropically driven, accounted for by the release of unstable waters from the hydrophobic surface of 59H10. Our results provide an exemplar of the utility of parallel in vitro and in silico studies and highlight that differences in entropic interactions between amino acids and water molecules are sufficient to drive orders of magnitude differences in affinity., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2023

2. Deep learning of HIV field-based rapid tests.

Author

Turbé V, Herbst C, Mngomezulu T, Meshkinfamfard S, Dlamini N, Mhlongo T, Smit T, Cherepanova V, Shimada K, Budd J, Arsenov N, Gray S, Pillay D, Herbst K, Shahmanesh M, and McKendry RA

Subjects

Algorithms, Humans, Rural Health Services organization & administration, Sensitivity and Specificity, South Africa, Time and Motion Studies, AIDS Serodiagnosis methods, Deep Learning, HIV Infections diagnosis

Abstract

Although deep learning algorithms show increasing promise for disease diagnosis, their use with rapid diagnostic tests performed in the field has not been extensively tested. Here we use deep learning to classify images of rapid human immunodeficiency virus (HIV) tests acquired in rural South Africa. Using newly developed image capture protocols with the Samsung SM-P585 tablet, 60 fieldworkers routinely collected images of HIV lateral flow tests. From a library of 11,374 images, deep learning algorithms were trained to classify tests as positive or negative. A pilot field study of the algorithms deployed as a mobile application demonstrated high levels of sensitivity (97.8%) and specificity (100%) compared with traditional visual interpretation by humans-experienced nurses and newly trained community health worker staff-and reduced the number of false positives and false negatives. Our findings lay the foundations for a new paradigm of deep learning-enabled diagnostics in low- and middle-income countries, termed REASSURED diagnostics 1 , an acronym for real-time connectivity, ease of specimen collection, affordable, sensitive, specific, user-friendly, rapid, equipment-free and deliverable. Such diagnostics have the potential to provide a platform for workforce training, quality assurance, decision support and mobile connectivity to inform disease control strategies, strengthen healthcare system efficiency and improve patient outcomes and outbreak management in emerging infections., (© 2021. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2021

3. Spin-enhanced nanodiamond biosensing for ultrasensitive diagnostics.

Author

Miller BS, Bezinge L, Gliddon HD, Huang D, Dold G, Gray ER, Heaney J, Dobson PJ, Nastouli E, Morton JJL, and McKendry RA

Subjects

Avidin chemistry, Biosensing Techniques instrumentation, Biotin chemistry, Fluorescence, Gold chemistry, HIV-1 isolation & purification, Humans, Limit of Detection, Metal Nanoparticles chemistry, Microfluidics instrumentation, Microfluidics methods, Microwaves, Nucleic Acid Amplification Techniques, Paper, Plasma virology, Quantum Theory, Sensitivity and Specificity, Single Molecule Imaging, Temperature, Biosensing Techniques methods, Early Diagnosis, HIV Infections diagnosis, HIV Infections virology, HIV-1 genetics, Nanodiamonds chemistry, RNA, Viral blood

Abstract

The quantum spin properties of nitrogen-vacancy defects in diamond enable diverse applications in quantum computing and communications 1 . However, fluorescent nanodiamonds also have attractive properties for in vitro biosensing, including brightness 2 , low cost 3 and selective manipulation of their emission 4 . Nanoparticle-based biosensors are essential for the early detection of disease, but they often lack the required sensitivity. Here we investigate fluorescent nanodiamonds as an ultrasensitive label for in vitro diagnostics, using a microwave field to modulate emission intensity 5 and frequency-domain analysis 6 to separate the signal from background autofluorescence 7 , which typically limits sensitivity. Focusing on the widely used, low-cost lateral flow format as an exemplar, we achieve a detection limit of 8.2 × 10 -19 molar for a biotin-avidin model, 10 5  times more sensitive than that obtained using gold nanoparticles. Single-copy detection of HIV-1 RNA can be achieved with the addition of a 10-minute isothermal amplification step, and is further demonstrated using a clinical plasma sample with an extraction step. This ultrasensitive quantum diagnostics platform is applicable to numerous diagnostic test formats and diseases, and has the potential to transform early diagnosis of disease for the benefit of patients and populations.

Published

2020

4. p24 revisited: a landscape review of antigen detection for early HIV diagnosis.

Author

Gray ER, Bain R, Varsaneux O, Peeling RW, Stevens MM, and McKendry RA

Subjects

Humans, Early Diagnosis, Diagnostic Tests, Routine methods, HIV Core Protein p24 blood, HIV Infections diagnosis, Point-of-Care Testing

Abstract

: Despite major advances in HIV testing, early detection of infection at the point of care (PoC) remains a key challenge. Although rapid antibody PoC and laboratory-based nucleic acid amplification tests dominate the diagnostics market, the viral capsid protein p24 is recognized as an alternative early virological biomarker of infection. However, the detection of ultra-low levels of p24 at the PoC has proven challenging. Here we review the landscape of p24 diagnostics to identify knowledge gaps and barriers and help shape future research agendas. Five hundred and seventy-four research articles to May 2018 that propose or evaluate diagnostic assays for p24 were identified and reviewed. We give a brief history of diagnostic development, and the utility of p24 as a biomarker in different populations such as infants, the newly infected, those on preexposure prophylaxis and self-testers. We review the performance of commercial p24 assays and consider elements such as immune complex disruption, resource-poor settings, prevalence, and assay antibodies. Emerging and ultrasensitive assays are reviewed and show a number of promising approaches but further translation has been limited. We summarize studies on the health economic benefits of using antigen testing. Finally, we speculate on the future uses of high-performance p24 assays, particularly, if available in self-test format.

Published

2018

5. Platinum Nanocatalyst Amplification: Redefining the Gold Standard for Lateral Flow Immunoassays with Ultrabroad Dynamic Range.

Author

Loynachan CN, Thomas MR, Gray ER, Richards DA, Kim J, Miller BS, Brookes JC, Agarwal S, Chudasama V, McKendry RA, and Stevens MM

Subjects

Catalysis, Equipment Design, Gold chemistry, HIV Infections diagnosis, HIV Infections virology, Humans, Metal Nanoparticles ultrastructure, Porosity, Antibodies, Immobilized chemistry, HIV isolation & purification, HIV Core Protein p24 analysis, HIV Infections blood, Immunoassay instrumentation, Metal Nanoparticles chemistry, Platinum chemistry, Point-of-Care Testing

Abstract

Paper-based lateral flow immunoassays (LFIAs) are one of the most widely used point-of-care (PoC) devices; however, their application in early disease diagnostics is often limited due to insufficient sensitivity for the requisite sample sizes and the short time frames of PoC testing. To address this, we developed a serum-stable, nanoparticle catalyst-labeled LFIA with a sensitivity surpassing that of both current commercial and published sensitivities for paper-based detection of p24, one of the earliest and most conserved biomarkers of HIV. We report the synthesis and characterization of porous platinum core-shell nanocatalysts (PtNCs), which show high catalytic activity when exposed to complex human blood serum samples. We explored the application of antibody-functionalized PtNCs with strategically and orthogonally modified nanobodies with high affinity and specificity toward p24 and established the key larger nanoparticle size regimes needed for efficient amplification and performance in LFIA. Harnessing the catalytic amplification of PtNCs enabled naked-eye detection of p24 spiked into sera in the low femtomolar range (ca. 0.8 pg·mL -1 ) and the detection of acute-phase HIV in clinical human plasma samples in under 20 min. This provides a versatile absorbance-based and rapid LFIA with sensitivity capable of significantly reducing the HIV acute phase detection window. This diagnostic may be readily adapted for detection of other biomolecules as an ultrasensitive screening tool for infectious and noncommunicable diseases and can be capitalized upon in PoC settings for early disease detection.

Published

2018

6. Towards an ultra-rapid smartphone- connected test for infectious diseases.

Author

Turbé V, Gray ER, Lawson VE, Nastouli E, Brookes JC, Weiss RA, Pillay D, Emery VC, Verrips CT, Yatsuda H, Athey D, and McKendry RA

Subjects

Humans, Sensitivity and Specificity, Time, Biosensing Techniques methods, HIV Infections diagnosis, Point-of-Care Systems, Smartphone

Abstract

The development is reported of an ultra-rapid, point-of-care diagnostic device which harnesses surface acoustic wave (SAW) biochips, to detect HIV in a finger prick of blood within 10 seconds (sample-in-result-out). The disposable quartz biochip, based on microelectronic components found in every consumer smartphone, is extremely fast because no complex labelling, amplification or wash steps are needed. A pocket-sized control box reads out the SAW signal and displays results electronically. High analytical sensitivity and specificity are found with model and real patient blood samples. The findings presented here open up the potential of consumer electronics to cut lengthy test waiting times, giving patients on the spot access to potentially life-saving treatment and supporting more timely public health interventions to prevent disease transmission.

Published

2017

7. Platinum nanocatalyst amplification: redefining the gold standard for lateral flow immunoassays with ultra-broad dynamic range

Author

Loynachan, C, Thomas, MR, Gray, ER, Richards, DA, Kim, J, MIller, BS, Brookes, JC, Chudasama, V, McKendry, RA, Stevens, MM, Engineering & Physical Science Research Council (E, Medical Research Council (MRC), Commission of the European Communities, and Engineering & Physical Science Research Council (EPSRC)

Subjects

Technology, Chemistry, Multidisciplinary, Materials Science, HIV Core Protein p24, Metal Nanoparticles, Materials Science, Multidisciplinary, HIV Infections, DIAGNOSTICS, HIGHLY EFFICIENT, Catalysis, enzyme mimic, porous platinum core−shell nanoparticles, broad dynamic range, NANOPARTICLES, DETECTION LIMITS, Humans, Nanoscience & Nanotechnology, HIV detection, Platinum, porous platinum core-shell nanoparticles, PEROXIDASE-LIKE ACTIVITY, Immunoassay, Science & Technology, Chemistry, Physical, lateral flow immunoassay, HIV, biorthogonal chemistry, Equipment Design, nanobodies, ACUTE HIV-INFECTION, Chemistry, ANTIBODY FRAGMENTS, point-of-care, P24 ANTIGEN, Point-of-Care Testing, Physical Sciences, Science & Technology - Other Topics, Gold, POINT, Antibodies, Immobilized, Porosity, SYSTEM

Abstract

Paper-based lateral flow immunoassays (LFIAs) are one of the most widely used point-of-care (PoC) devices; however, their application in early disease diagnostics is often limited due to insufficient sensitivity for the requisite sample sizes and the short time frames of PoC testing. To address this, we developed a serum-stable, nanoparticle catalyst-labeled LFIA with a sensitivity surpassing that of both current commercial and published sensitivities for paper-based detection of p24, one of the earliest and most conserved biomarkers of HIV. We report the synthesis and characterization of porous platinum core–shell nanocatalysts (PtNCs), which show high catalytic activity when exposed to complex human blood serum samples. We explored the application of antibody-functionalized PtNCs with strategically and orthogonally modified nanobodies with high affinity and specificity toward p24 and established the key larger nanoparticle size regimes needed for efficient amplification and performance in LFIA. Harnessing the catalytic amplification of PtNCs enabled naked-eye detection of p24 spiked into sera in the low femtomolar range (ca. 0.8 pg·mL–1) and the detection of acute-phase HIV in clinical human plasma samples in under 20 min. This provides a versatile absorbance-based and rapid LFIA with sensitivity capable of significantly reducing the HIV acute phase detection window. This diagnostic may be readily adapted for detection of other biomolecules as an ultrasensitive screening tool for infectious and noncommunicable diseases and can be capitalized upon in PoC settings for early disease detection.

Published

2017