Graphene FET Sensors for Alzheimer’s Disease Protein Biomarker Clusterin Detection

Bungon, Theodore; Haslam, Carrie; Damiati, Samar; O’Driscoll, Benjamin; Whitley, Toby; Davey, Paul; Siligardi, Giuliano; Charmet, Jérôme; Awan, S.A.

doi:10.3389/fmolb.2021.651232

Cited by 28 publications

(12 citation statements)

References 75 publications

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“…Studying biomarkers related to AD greatly accelerates the understanding of the disease and can lead to new treatments against dementia. , Three biomarkers, T-tau, P-tau, and Aβ 42 , have been identified and confirmed in the cerebrospinal fluid that are strongly associated with AD and could be used as progression markers in developing drugs . To detect the AD-associated biomarkers in the brain, various imaging techniques have been developed, such as magnetic resonance imaging (MRI) and positron emission tomography (PET). − However, MRI and PET are costly and time-consuming while they still lack specific molecular information. , Other biosensing methods such as surface plasmon resonance biosensors and field-effect transistors offer specific information on the optical or electronic properties of the analyte − and, thus, are insufficient to gain comprehensive insights into the biomarkers of AD. Recently, spectroscopy based detection of AD biomarkers via immunoassay and fluorescence on blood and cerebrospinal fluid (CSF) has been intensively investigated in preclinical stages, − but they are not label-free, which prevents the discovery of novel biomarkers.…”

Section: Introductionmentioning

confidence: 99%

Rapid Biomarker Screening of Alzheimer’s Disease by Interpretable Machine Learning and Graphene-Assisted Raman Spectroscopy

Wang

Zhang

et al. 2022

ACS Nano

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The study of Alzheimer’s disease (AD), the most common cause of dementia, faces challenges in terms of understanding the cause, monitoring the pathogenesis, and developing early diagnoses and effective treatments. Rapid and accurate identification of AD biomarkers in the brain is critical to providing key insights into AD and facilitating the development of early diagnosis methods. In this work, we developed a platform that enables a rapid screening of AD biomarkers by employing graphene-assisted Raman spectroscopy and machine learning interpretation in AD transgenic animal brains. Specifically, we collected Raman spectra on slices of mouse brains with and without AD and used machine learning to classify AD and non-AD spectra. By contacting monolayer graphene with the brain slices, the accuracy was increased from 77% to 98% in machine learning classification. Further, using a linear support vector machine (SVM), we identified a spectral feature importance map that reveals the importance of each Raman wavenumber in classifying AD and non-AD spectra. Based on this spectral feature importance map, we identified AD biomarkers including Aβ and tau proteins and other potential biomarkers, such as triolein, phosphatidylcholine, and actin, which have been confirmed by other biochemical studies. Our Raman–machine learning integrated method with interpretability will facilitate the study of AD and can be extended to other tissues and biofluids and for various other diseases.

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Section: Introductionmentioning

confidence: 99%

Rapid Biomarker Screening of Alzheimer’s Disease by Interpretable Machine Learning and Graphene-Assisted Raman Spectroscopy

Wang

Zhang

et al. 2022

ACS Nano

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“…Furthermore, GFET biosensors consume very low amounts of power and have great potential for mass production. GFET biosensors have been utilized for ultralow detection of a variety of biological species including proteins, exosomes, DNAs, viruses, and other disease biomarkers. − However, so far, there is no report of the detection of GFAP in patient samples for neurological diseases using the GFET technology. Here, we recruited six patients with moderate–severe TBI (defined by the Mayo classification), and we demonstrated an on-chip GFET biosensing platform for ultrasensitive and ultrafast detection of GFAP with the LOD down to 20 fg/mL (400 aM) in clean phosphate-buffered saline (PBS) and 231 fg/mL (4 fM) in patient plasma.…”

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confidence: 99%

Detection of Glial Fibrillary Acidic Protein in Patient Plasma Using On-Chip Graphene Field-Effect Biosensors, in Comparison with ELISA and Single-Molecule Array

Ramadan

Akingbade

et al. 2021

ACS Sens.

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Glial fibrillary acidic protein (GFAP) is a discriminative blood biomarker for many neurological diseases, such as traumatic brain injury. Detection of GFAP in buffer solutions using biosensors has been demonstrated, but accurate quantification of GFAP in patient samples has not been reported, yet in urgent need. Herein, we demonstrate a robust on-chip graphene field-effect transistor (GFET) biosensing method for sensitive and ultrafast detection of GFAP in patient plasma. Patients with moderate–severe traumatic brain injuries, defined by the Mayo classification, are recruited to provide plasma samples. The binding of target GFAP with the specific antibodies that are conjugated on a monolayer GFET device triggers the shift of its Dirac point, and this signal change is correlated with the GFAP concentration in the patient plasma. The limit of detection (LOD) values of 20 fg/mL (400 aM) in buffer solution and 231 fg/mL (4 fM) in patient plasma have been achieved using this approach. In parallel, for the first time, we compare our results to the state-of-the-art single-molecule array (Simoa) technology and the classic enzyme-linked immunosorbent assay (ELISA) for reference. The GFET biosensor shows competitive LOD to Simoa (1.18 pg/mL) and faster sample-to-result time (<15 min), and also it is cheaper and more user-friendly. In comparison to ELISA, GFET offers advantages of total detection time, detection sensitivity, and simplicity. This GFET biosensing platform holds high promise for the point-of-care diagnosis and monitoring of traumatic brain injury in GP surgeries and patient homes.

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“…For the detection of clusterin, quantitative immunoprecipitation liquid chromatography/mass spectrometry (IP-LC/MS) for urine samples of cynomolgus and enzyme-linked immunosorbent assay (ELISA) analysis for nasal secretion samples of humans have been reported. , The biggest challenge these classical methods face is that the sensitivity is not high enough and the operation is not simple and fast enough. With the development of nanotechnology and sensing technology, the emergence of biosensors makes it possible to make up for the defects of traditional methods. − Label-free immunosensors that depend on electrochemistry and graphene field-effect transistor biosensors for clusterin have been developed. , The essence of these sensors is the signal amplification system based on the antigen–antibody recognition reaction, so the sensitivity of detection is significantly improved. In addition to the signal amplification system, improving the recognition response elements of target molecules is another way to build clusterin biosensors that meet the needs of clinical testing.…”

Section: Introductionmentioning

confidence: 99%

Colorimetric Aptasensor for the Visual and Microplate Determination of Clusterin in Human Urine Based on Aggregation Characteristics of Gold Nanoparticles

Wen

Liu

et al. 2023

ACS Omega

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Clusterin has the potential to become the biomarker of multiple diseases, but its clinical quantitative detection methods are limited, which restricts its research progress as a biomarker. A rapid and visible colorimetric sensor for clusterin detection based on sodium chloride-induced aggregation characteristic of gold nanoparticles (AuNPs) was successfully constructed. Unlike the existing methods based on antigen−antibody recognition reactions, the aptamer of clusterin was used as the sensing recognition element. The aptamer could protect AuNPs from aggregation caused by sodium chloride, but clusterin bound with aptamer detached it from AuNPs, thereby inducing aggregation again. Simultaneously, the color change from red in the dispersed state to purple gray in the aggregated state made it possible to preliminarily judge the concentration of clusterin by observation. This biosensor showed a linear range of 0.02−2 ng/mL and good sensitivity with a detection limit of 5.37 pg/mL. The test results of clusterin in spiked human urine confirmed that the recovery rate was satisfactory. The proposed strategy is helpful for the development of label-free point-of-care testing equipment for clinical testing of clusterin, which is cost-effective and feasible.

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Graphene FET Sensors for Alzheimer’s Disease Protein Biomarker Clusterin Detection

Cited by 28 publications

References 75 publications

Rapid Biomarker Screening of Alzheimer’s Disease by Interpretable Machine Learning and Graphene-Assisted Raman Spectroscopy

Rapid Biomarker Screening of Alzheimer’s Disease by Interpretable Machine Learning and Graphene-Assisted Raman Spectroscopy

Detection of Glial Fibrillary Acidic Protein in Patient Plasma Using On-Chip Graphene Field-Effect Biosensors, in Comparison with ELISA and Single-Molecule Array

Colorimetric Aptasensor for the Visual and Microplate Determination of Clusterin in Human Urine Based on Aggregation Characteristics of Gold Nanoparticles

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