Application of Long-Range Surface Plasmon Resonance for ABO Blood Typing

Tangkawsakul, Wanida; Srikhirin, Toemsak; Shinbo, Kazunari; Kato, Keizo; Kaneko, Futao; Baba, Akira

doi:10.1155/2016/1432781

Cited by 19 publications

(6 citation statements)

References 32 publications

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“…The D-antigen was validated as an example for quantitative blood grouping (79). Using the long-range SPR biosensor in a long-range SPR blood group typing, the results were in full accordance with those of the agglutination test (70). In a word, this method has high accuracy and sensitivity and requires a small sample quantity and little time.…”

Section: Surface Plasmon Resonance Testingmentioning

confidence: 62%

“…Surface plasmon resonance (SPR) is a sensitive technique and is a label-free method for tracking molecular interactions in real-time (69). In some applications, the sensitivity and versatility of the label-free, real-time technique outperform traditional methods like enzyme-linked immunosorbent assays or fluorescence (70). Generally, RBC antigen-specific IgM or IgG antibodies immobilized on the surface of SPR can be used to identify blood groups (71,72).…”

Section: Surface Plasmon Resonance Testingmentioning

confidence: 99%

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Blood Group Testing

Guo

2022

Front. Med.

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Red blood cell (RBC) transfusion is one of the most frequently performed clinical procedures and therapies to improve tissue oxygen delivery in hospitalized patients worldwide. Generally, the cross-match is the mandatory test in place to meet the clinical needs of RBC transfusion by examining donor-recipient compatibility with antigens and antibodies of blood groups. Blood groups are usually an individual's combination of antigens on the surface of RBCs, typically of the ABO blood group system and the RH blood group system. Accurate and reliable blood group typing is critical before blood transfusion. Serological testing is the routine method for blood group typing based on hemagglutination reactions with RBC antigens against specific antibodies. Nevertheless, emerging technologies for blood group testing may be alternative and supplemental approaches when serological methods cannot determine blood groups. Moreover, some new technologies, such as the evolving applications of blood group genotyping, can precisely identify variant antigens for clinical significance. Therefore, this review mainly presents a clinical overview and perspective of emerging technologies in blood group testing based on the literature. Collectively, this may highlight the most promising strategies and promote blood group typing development to ensure blood transfusion safety.

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Section: Surface Plasmon Resonance Testingmentioning

confidence: 62%

Section: Surface Plasmon Resonance Testingmentioning

confidence: 99%

Blood Group Testing

Guo

2022

Front. Med.

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“…Surface plasmon resonance (SPR) spectroscopy is a technique that has a powerful ability to detect and provide real-time information of probe molecules deposited on thin metal films. − It has become a popular optical biosensing phenomenon that is widely used in the fields of biochemistry, biology, and medical science. − Since the 1990s, when SPR was first used for studying biomolecules, ,, it has been extensively applied to investigate the association of proteins, antigen–antibody interactions, ,− DNA–drug bindings, and carbohydrate–RNA interactions . Furthermore, the SPR technology has been recently adapted to a plottable SPR platform in which a smartphone is coupled with special custom-design optics.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Miniature Surface Plasmon Resonance Sensor Chips by Using Confined Sessile Drop Technique

Nootchanat

Jaikeandee

Yaiwong

et al. 2019

ACS Appl. Mater. Interfaces

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In this study, we demonstrate a simple and efficient method to fabricate miniature surface plasmon resonance (SPR) sensor chips by using confined sessile drop technique. A liquid optical adhesive (NOA 61) was dropped on the circular flat surface of cylindrical substrates made of poly(dimethylsiloxane) (PDMS). The formation of hemispherical optical prisms was accomplished by taking advantage of the sharp edges of cylindrical PDMS substrates that prevented the overflow of liquid NOA 61 at the edge of substrates. The size of the hemispherical optical prisms can be controlled by changing the diameter of the cylindrical PDMS substrates. After UV curing, the SPR sensor chips were obtained by the deposition of 3 nm thick chromium and 47 nm thick gold on the flat side of the prisms. The fabricated miniature SPR sensor chips were then mounted on a three-dimensional-printed flow cell to complete the microfluidic SPR sensor module. The miniature SPR sensor chips provided a comparable sensitivity to the conventional high-refractive-index glass SPR chips. To demonstrate the detection capability of nanometer-sized materials, we applied the miniature microfluidic SPR system for monitoring the deposition of layer-by-layer ultrathin films of poly(diallyldimethylammonium chloride)/poly(sodium 4styrenesulfonate) and for detecting human immunoglobulin G.

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“…(60) The glycoprofiling can be performed more rapidly and label-free using the specific binding characteristics of the Nglycans to for example lectins and monitoring them with imaging SPR. (61)(62)(63)(64) These publications focus on small glycan structures rather than the higher-order structures of Nglycans found on glycoproteins or use a single lectin interaction to study glycan interactions.…”

Section: Propertymentioning

confidence: 99%

“…LRSPR has been successfully applied in cell sensing experiments, for example by cell stimulation under influence of lipopolysaccharides (53) or cellular responses to osmotic stress. (41) Furthermore, applications for blood group typing (61,62) , leukemia biomarker detection in serum (63) or diagnosis of dengue infection by virus sensing in blood (64) have recently been described based on LRSPR. The principle of long-range SPR is to increase the propagation of surface plasmons further down the sensing solution, thereby increasing the sensitivity and evanescent field for measurements.…”

Section: Advanced Spr Technologiesmentioning

confidence: 99%

Surface plasmon resonance imaging as a screening platform in biopharmaceutical development

Geuijen¹

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Abbreviations and terminology Chapter 1 General introduction and thesis outline Chapter 2 High-throughput and multiplexed regeneration buffer scouting for affinity-based interactions Chapter 3 Rapid buffer and ligand screening for affinity chromatography by multiplexed Surface Plasmon Resonance imaging Chapter 4 Label-free glycoprofiling with multiplex surface plasmon resonance: A tool to quantify sialylation of Erythropoietin 69 Chapter 5 Characterization of low affinity Fcγ receptor biotinylation under controlled reaction conditions by mass spectrometry and ligand binding analysis Chapter 6 Rapid screening of IgG quality attributes: effects on Fc receptor binding

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Application of Long-Range Surface Plasmon Resonance for ABO Blood Typing

Cited by 19 publications

References 32 publications

Blood Group Testing

Blood Group Testing

Fabrication of Miniature Surface Plasmon Resonance Sensor Chips by Using Confined Sessile Drop Technique

Surface plasmon resonance imaging as a screening platform in biopharmaceutical development

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