Your search keyword '"Isabelle C. Samper"' showing total 9 results

1. Functional Electrochemistry: On-Nerve Assessment of Electrode Materials for Electrochemistry and Functional Neurostimulation

Author

Jason A. Miranda, Adrien Rapeaux, Isabelle C. Samper, Carolina Silveira, David R. Wille, Gerald E. Hunsberger, Wesley J. Dopson, Huanfen Yao, Annapurna Karicherla, and Daniel J. Chew

Subjects

Bioelectronics, electrochemistry, electrode materials, nerve stimulation, neural interface, Computer applications to medicine. Medical informatics, R858-859.7, Medical technology, R855-855.5

Abstract

Emerging therapies in bioelectronic medicine highlight the need for deeper understanding of electrode material performance in the context of tissue stimulation. Electrochemical properties are characterized on the benchtop, facilitating standardization across experiments. On-nerve electrochemistry differs from benchtop characterization and the relationship between electrochemical performance and nerve activation thresholds are not commonly established. This relationship is important in understanding differences between electrical stimulation requirements and electrode performance. We report functional electrochemistry as a follow-up to benchtop testing, describing a novel experimental approach for evaluating on-nerve electrochemical performance in the context of nerve activation. An ex-vivo rat sciatic nerve preparation was developed to quantify activation thresholds of fiber subtypes and electrode material charge injection limits for platinum iridium, iridium oxide, titanium nitride and PEDOT. Finally, we address experimental complexities arising in these studies, and demonstrate statistical solutions that support rigorous material performance comparisons for decision making in neural interface development.

Published

2024

2. Electrochemical Capillary Driven Immunoassay for Detection of SARS-CoV-2

Author

Kaylee M. Clark, Melissa S. Schenkel, Trey W. Pittman, Isabelle C. Samper, Loran B. R. Anderson, Wisarut Khamcharoen, Suad Elmegerhi, Rushika Perera, Weena Siangproh, Alan J. Kennan, Brian J. Geiss, David S. Dandy, and Charles S. Henry

Subjects

Environmental Engineering, Industrial and Manufacturing Engineering

Abstract

The COVID-19 pandemic focused attention on a pressing need for fast, accurate, and low-cost diagnostic tests. This work presents an electrochemical capillary driven immunoassay (eCaDI) developed to detect SARS-CoV-2 nucleocapsid (N) protein. The low-cost flow device is made of polyethylene terephthalate (PET) and adhesive films. Upon addition of a sample, reagents and washes are sequentially delivered to an integrated screen-printed carbon electrode for detection, thus automating a full sandwich immunoassay with a single end-user step. The modified electrodes are sensitive and selective for SARS-CoV-2 N protein and stable for over 7 weeks. The eCaDI was tested with influenza A and Sindbis virus and proved to be selective. The eCaDI was also successfully applied to detect nine different SARS-CoV-2 variants, including Omicron.

Published

2022

3. Electrochemical Immunoassay for the Detection of SARS-CoV-2 Nucleocapsid Protein in Nasopharyngeal Samples

Author

Isabelle C. Samper, Catherine J. McMahon, Melissa S. Schenkel, Kaylee M. Clark, Wisarut Khamcharoen, Loran B. R. Anderson, James S. Terry, Emily N. Gallichotte, Gregory D. Ebel, Brian J. Geiss, David S. Dandy, and Charles S. Henry

Subjects

Immunoassay, SARS-CoV-2, COVID-19, Humans, Nucleocapsid Proteins, Sensitivity and Specificity, Analytical Chemistry

Abstract

Point-of-care (POC) methods currently available for detecting SARS-CoV-2 infections still lack accuracy. Here, we report the development of a highly sensitive electrochemical immunoassay capable of quantitatively detecting the presence of the SARS-CoV-2 virus in patient nasopharyngeal samples using stencil-printed carbon electrodes (SPCEs) functionalized with capture antibodies targeting the SARS-CoV-2 nucleocapsid protein (N protein). Samples are added to the electrode surface, followed by horseradish peroxidase (HRP)-conjugated detection antibodies also targeting the SARS-CoV-2 N protein. The concentration of the virus in samples is quantified using chronoamperometry in the presence of 3,3'5,5'-tetramethylbenzidine. Limits of detection equivalent to less than 50 plaque forming units/mL (PFU/mL) were determined with virus sample volumes of 20 μL. No cross-reactivity was detected with the influenza virus and other coronavirus N proteins. Patient nasopharyngeal samples were tested as part of a proof-of-concept clinical study where samples were also tested using the gold-standard real-time quantitative polymerase chain reaction (RT-qPCR) method. Preliminary results from a data set of 22 samples demonstrated a clinical specificity of 100% (

Published

2022

4. Electrochemical Capillary-Flow Immunoassay for Detecting Anti-SARS-CoV-2 Nucleocapsid Protein Antibodies at the Point of Care

Author

Charles S. Henry, Ana Sánchez-Cano, Brian J. Geiss, Eva Baldrich, Ilhoon Jang, Weena Siangproh, David S. Dandy, Wisarut Khamcharoen, and Isabelle C Samper

Subjects

Point-of-Care Systems, Microfluidics, serology, Bioengineering, Antibodies, Viral, Article, chemistry.chemical_compound, Seroepidemiologic Studies, medicine, Humans, Sample preparation, Instrumentation, Point of care, Fluid Flow and Transfer Processes, Immunoassay, Chromatography, point-of-care (POC) diagnostics, medicine.diagnostic_test, biology, capillary-flow device, SARS-CoV-2, Process Chemistry and Technology, COVID-19, Reproducibility of Results, Chronoamperometry, Nucleocapsid Proteins, Potentiostat, chemistry, electrochemistry, biology.protein, Antibody, Nitrocellulose

Abstract

Rapid and inexpensive serological tests for SARS-CoV-2 antibodies are needed to conduct population-level seroprevalence surveillance studies and can improve diagnostic reliability when used in combination with viral tests. Here, we report a novel low-cost electrochemical capillary-flow device to quantify IgG antibodies targeting SARS-CoV-2 nucleocapsid proteins (anti-N antibody) down to 5 ng/mL in low-volume (10 μL) human whole blood samples in under 20 min. No sample preparation is needed as the device integrates a blood-filtration membrane for on-board plasma extraction. The device is made of stacked layers of a hydrophilic polyester and double-sided adhesive films, which create a passive microfluidic circuit that automates the steps of an enzyme-linked immunosorbent assay (ELISA). The sample and reagents are sequentially delivered to a nitrocellulose membrane that is modified with a recombinant SARS-CoV-2 nucleocapsid protein. When present in the sample, anti-N antibodies are captured on the nitrocellulose membrane and detected via chronoamperometry performed on a screen-printed carbon electrode. As a result of this quantitative electrochemical readout, no result interpretation is required, making the device ideal for point-of-care (POC) use by non-trained users. Moreover, we show that the device can be coupled to a near-field communication potentiostat operated from a smartphone, confirming its true POC potential. The novelty of this work resides in the integration of sensitive electrochemical detection with capillary-flow immunoassay, providing accuracy at the point of care. This novel electrochemical capillary-flow device has the potential to aid the diagnosis of infectious diseases at the point of care.

Published

2021

5. Fiber-based electrochemical biosensors for monitoring pH and transient neurometabolic lactate

Author

Melinda Hersey, Molly M. Stevens, Isabelle C. Samper, Sally A. N. Gowers, Martyn G. Boutelle, Parastoo Hashemi, Marsilea A. Booth, Polina Anikeeva, Seongjun Park, Medical Research Council (MRC), and Engineering & Physical Science Research Council (EPSRC)

Subjects

Chemistry, 010401 analytical chemistry, Potentiometric titration, Context (language use), Biosensing Techniques, Hydrogen-Ion Concentration, 010402 general chemistry, 01 natural sciences, Article, Amperometry, 0104 chemical sciences, Analytical Chemistry, Mice, Platinum black, Electrode, 0399 Other Chemical Sciences, Biophysics, Animals, Graphite, Lactic Acid, Transient (oscillation), Fiber, Electrodes, Biosensor, 0301 Analytical Chemistry

Abstract

Developing tools that are able to monitor transient neurochemical dynamics is important to decipher brain chemistry and function. Multifunctional polymer-based fibers have been recently applied to monitor and modulate neural activity. Here, we explore the potential of polymer fibers comprising six graphite-doped electrodes and two microfluidic channels within a flexible polycarbonate body as a platform for sensing pH and neurometabolic lactate. Electrodes were made into potentiometric sensors (responsive to pH) or amperometric sensors (lactate biosensors). The growth of an iridium oxide layer made the fiber electrodes responsive to pH in a physiologically relevant range. Lactate biosensors were fabricated via platinum black growth on the fiber electrode, followed by an enzyme layer, making them responsive to lactate concentration. Lactate fiber biosensors detected transient neurometabolic lactate changes in an in vivo mouse model. Lactate concentration changes were associated with spreading depolarizations, known to be detrimental to the injured brain. Induced waves were identified by a signature lactate concentration change profile and measured as having a speed of ∼2.7 mm/min (n = 4 waves). Our work highlights the potential applications of fiber-based biosensors for direct monitoring of brain metabolites in the context of injury.

Published

2021

6. Real-time neurochemical measurement of dynamic metabolic events during cardiac arrest and resuscitation in a porcine model

Author

Georgia K Smith, Kirsten Møller, De-Shaine R. K. Murray, Martyn G. Boutelle, Sarah Jeyaprakash, Michelle L. Rogers, Markus Harboe Olsen, Isabelle C. Samper, Michael Karlsson, Sally A. N. Gowers, Engineering & Physical Science Research Council (EPSRC), Imperial College Healthcare NHS Trust- BRC Funding, and Engineering & Physical Science Research Council (E

Subjects

Resuscitation, Swine, Microdialysis, medicine.medical_treatment, Biosensing Techniques, BRAIN-INJURY, Biochemistry, LACTATE, Brain Ischemia, Mixed Function Oxygenases, GLUCOSE, Analytical Chemistry, Electrochemistry, ONLINE MICRODIALYSIS, Spectroscopy, RAPID SAMPLING MICRODIALYSIS, Brain, Microfluidic Analytical Techniques, Chemistry, Physical Sciences, Cardiology, Female, Aspergillus niger, 0301 Analytical Chemistry, Aerococcus, medicine.medical_specialty, Defibrillation, Return of spontaneous circulation, Proof of Concept Study, Microfluidic Analysis, Glucose Oxidase, Neurochemical, Internal medicine, 0399 Other Chemical Sciences, medicine, Animals, Environmental Chemistry, Lactic Acid, Cardiopulmonary resuscitation, Science & Technology, Chemistry, Analytical, Neurophysiological Monitoring, Cardiopulmonary Resuscitation, Heart Arrest, Challenging environment, IMMOBILIZATION, BIOSENSORS, Biomarkers, SYSTEM

Abstract

This work describes a fully-integrated portable microfluidic analysis system for real-time monitoring of dynamic changes in glucose and lactate occurring in the brain as a result of cardiac arrest and resuscitation. Brain metabolites are sampled using FDA-approved microdialysis probes and coupled to a high-temporal resolution 3D printed microfluidic chip housing glucose and lactate biosensors. The microfluidic biosensors are integrated with a wireless 2-channel potentiostat forming a compact analysis system that is ideal for use in a crowded operating theatre. Data are transmitted to a custom-written app running on a tablet for real-time visualisation of metabolic trends. In a proof-of-concept porcine model of cardiac arrest, the integrated analysis system proved reliable in a challenging environment resembling a clinical setting; noise levels were found to be comparable with those seen in the lab and were not affected by major clinical interventions such as defibrillation of the heart. Using this system, we were able, for the first time, to measure changes in brain glucose and lactate levels caused by cardiac arrest and resuscitation; the system was sensitive to clinical interventions such as infusion of adrenaline. Trends suggest that cardiopulmonary resuscitation alone does not meet the high energy demands of the brain as metabolite levels only return to their values preceding cardiac arrest upon return of spontaneous circulation.

Published

2019

7. Portable Microfluidic Biosensing System for Real-Time Analysis of Microdialysate in Transplant Kidneys

Author

Tonghathai Phairatana, Isabelle C. Samper, Martyn G. Boutelle, Thomas Watts, Vassilios Papalois, Chu Wang, Sally A. N. Gowers, Natalie Vallant, Marsilea A. Booth, and Bynvant Sandhu

Subjects

Aerococcus, Swine, Microdialysis, Microfluidics, Biosensing Techniques, 010402 general chemistry, Kidney, 01 natural sciences, Proof of Concept Study, Article, Analytical Chemistry, law.invention, Mixed Function Oxygenases, Bluetooth, Fungal Proteins, Glucose Oxidase, Bacterial Proteins, law, Dialysis Solutions, Lab-On-A-Chip Devices, Animals, Lactic Acid, Monitoring, Physiologic, business.industry, Chemistry, 010401 analytical chemistry, Continuous monitoring, Kidney metabolism, Microfluidic Analytical Techniques, Potentiostat, 0104 chemical sciences, Transplantation, Glucose, Proof of concept, Embedded system, Aspergillus niger, business, Biosensor

Abstract

Currently, there is a severe shortage of donor kidneys that are fit for transplantation, due in part to a lack of adequate viability assessment tools for transplant organs. This work presents the integration of a novel wireless two-channel amperometric potentiostat with microneedle-based glucose and lactate biosensors housed in a 3D printed chip to create a microfluidic biosensing system that is genuinely portable. The wireless potentiostat transmits data via Bluetooth to an Android app running on a tablet. The whole miniaturized system is fully enclosed and can be integrated with microdialysis to allow continuous monitoring of tissue metabolite levels in real time. We have also developed a wireless portable automated calibration platform so that biosensors can be calibrated away from the laboratory and in transit. As a proof of concept, we have demonstrated the use of this portable analysis system to monitor porcine kidneys for the first time from organ retrieval, through warm ischemia, transportation on ice, right through to cold preservation and reperfusion. The portable system is robust and reliable in the challenging conditions of the abattoir and during kidney transportation and can detect clear physiological changes in the organ associated with clinical interventions.

Published

2019

8. 3D printed microfluidic device for online detection of neurochemical changes with high temporal resolution in human brain microdialysate

Author

Isabelle C, Samper, Sally A N, Gowers, Michelle L, Rogers, De-Shaine R K, Murray, Sharon L, Jewell, Clemens, Pahl, Anthony J, Strong, and Martyn G, Boutelle

Subjects

Lab-On-A-Chip Devices, Microdialysis, Printing, Three-Dimensional, Brain, Humans, Neurochemistry, Biosensing Techniques, Equipment Design, Signal-To-Noise Ratio, Online Systems

Abstract

This paper presents the design, optimisation and fabrication of a mechanically robust 3D printed microfluidic device for the high time resolution online analysis of biomarkers in a microdialysate stream at microlitre per minute flow rates. The device consists of a microfluidic channel with secure low volume connections that easily integrates electrochemical biosensors for biomarkers such as glutamate, glucose and lactate. The optimisation process of the microfluidic channel fabrication, including for different types of 3D printer, is explained and the resulting improvement in sensor response time is quantified. The time resolution of the device is characterised by recording short lactate concentration pulses. The device is employed to record simultaneous glutamate, glucose and lactate concentration changes simulating the physiological response to spreading depolarisation events in cerebrospinal fluid dialysate. As a proof-of-concept study, the device is then used in the intensive care unit for online monitoring of a brain injury patient, demonstrating its capabilities for clinical monitoring.

Published

2019

9. Chemical Monitoring in Clinical Settings: Recent Developments toward Real-Time Chemical Monitoring of Patients

Author

Marsilea A. Booth, Isabelle C. Samper, Michelle L. Rogers, Chi Leng Leong, Aidan Wickham, Sally A. N. Gowers, Martyn G. Boutelle, Engineering & Physical Science Research Council (EPSRC), Engineering & Physical Science Research Council (E, The Royal Society of New Zealand - Rutherford Foundation, National Institutes of Health, and Imperial College Healthcare NHS Trust- BRC Funding

Subjects

Time Factors, Chemistry, Extramural, 010401 analytical chemistry, MEDLINE, 0904 Chemical Engineering, Analytical Chemistry (journal), Clinical settings, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Data science, Neurophysiological Monitoring, 0104 chemical sciences, Analytical Chemistry, 0399 Other Chemical Sciences, Humans, 0210 nano-technology, 0301 Analytical Chemistry

Abstract

This review covers references found in the recent literature (from 2015) describing clinically relevant chemical monitoring that either gives continuous chemical information in real time or has the near prospect of doing so.

Published

2017