Nondestructive in-line sub-picomolar detection of magnetic nanoparticles in flowing complex fluids

Bougas, Lykourgos; Langenegger, Lukas D.; Mora, Carlos A.; Zeltner, Martin; Stark, Wendelin J.; Wickenbrock, Arne; Blanchard, John W.; Budker, Dmitry

doi:10.1038/s41598-018-21802-2

Cited by 27 publications

(23 citation statements)

References 42 publications

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“…et al developed a microfluidic device where they can rapidly assess magnetic particle concentrations in a range of 0.01 mg/mL to 5 mg/mL by measuring the diamagnetic repelling velocity of polystyrene microspheres. 54 Also, Bougas, L. et al reported a method of detecting sub-picomolar magnetic nanoparticles in flowing complex fluids 55 , which would be useful when integrated with the extracorporeal device to monitor low amounts of the magnetic particles returning to the patients. While most extracorporeal blood treatment methods have targeted lowering endotoxin or cytokine levels in blood of the septic patients, extracorporeal removal of viral particles has rarely been explored 56 .…”

Section: Technical and Experimental Challengesmentioning

confidence: 99%

Multiscale Biofluidic and Nanobiotechnology Approaches for Treating Sepsis in Extracorporeal Circuits

Kang

2020

BioChip J

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Infectious diseases and their pandemics periodically attract public interests due to difficulty in treating the patients and the consequent high mortality. Sepsis caused by an imbalanced systemic inflammatory response to infection often leads to organ failure and death. The current therapeutic intervention mainly includes "the sepsis bundles," antibiotics (antibacterial, antiviral, and antifungal), intravenous fluids for resuscitation, and surgery, which have significantly improved the clinical outcomes in past decades; however, the patients with fulminant sepsis are still in desperate need of alternative therapeutic approaches. One of the potential supportive therapies, extracorporeal blood treatment, has emerged and been developed for improving the current therapeutic efficacy. Here, I overview how the treatment of infectious diseases has been assisted with the extracorporeal adjuvant therapy and the potential utility of various nanobiotechnology and microfluidic approaches for developing new auxiliary therapeutic methods.

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Section: Technical and Experimental Challengesmentioning

confidence: 99%

Multiscale Biofluidic and Nanobiotechnology Approaches for Treating Sepsis in Extracorporeal Circuits

Kang

2020

BioChip J

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“…Moreover, there are many technologies available for magnetic particle detection, such as superconducting quantum interference devices, atomic magnetometers, and diamond-based magnetometers. Of these, atomic magnetometers are the most sensitive to magnetic fields, and allow for various non-invasive sensing modalities operated in ambient conditions [58]. The advances in the field of biosensors could revolutionize the fast and sensitive quantification of biomarkers for diagnosing Alzheimer’s disease, chronic kidney disease, diabetes, liver diseases, tuberculosis, atherosclerosis, sepsis, and cancer [59].…”

Section: Magnetic Particles In Diagnosismentioning

confidence: 99%

Magnetic Particles for Advanced Molecular Diagnosis

2019

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Molecular diagnosis is the field that aims to develop nucleic-acid-based analytical methods for biological markers and gene expression assessments by combining laboratory medicine and molecular genetics. As it gradually becomes a clinical reality, molecular diagnosis could benefit from improvements resulting from thorough studies that could enhance the accuracy of these methods. The application of magnetic particles in molecular diagnosis tools has led to tremendous breakthroughs in terms of specificity, sensitivity, and discrimination in bioassays. Therefore, the aim of this review is to highlight the principles involved in the implementation of magnetic particles for sample preparation and targeted analyte isolation, purification, and extraction. Furthermore, the most recent advancements in the area of cancer and infectious disease diagnosis are presented, with an emphasis on screening and early stage detection.

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“…Recently, a method for detection of trace amounts of MNPs in complex fluids was published [89]. The authors used a magnetometric sensor, which detects low magnetic fluctuations to determine the presence of iron and cobalt MNPs under flowing conditions.…”

Section: Risk Assessment Of Mnps For Clinical Applicationsmentioning

confidence: 99%

Biochemical functionality of magnetic particles as nanosensors: how far away are we to implement them into clinical practice?

2019

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Magnetic nanosensors have become attractive instruments for the diagnosis and treatment of different diseases. They represent an efficient carrier system in drug delivery or in transporting contrast agents. For such purposes, magnetic nanosensors are used in vivo (intracorporeal application). To remove specific compounds from blood, magnetic nanosensors act as elimination system, which represents an extracorporeal approach. This review discusses principles, advantages and risks on recent advances in the field of magnetic nanosensors. First, synthesis methods for magnetic nanosensors and possibilities for enhancement of biocompatibility with different coating materials are addressed. Then, attention is devoted to clinical applications, in which nanosensors are or may be used as carrier- and elimination systems in the near future. Finally, risk considerations and possible effects of nanomaterials are discussed when working towards clinical applications with magnetic nanosensors.

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Nondestructive in-line sub-picomolar detection of magnetic nanoparticles in flowing complex fluids

Cited by 27 publications

References 42 publications

Multiscale Biofluidic and Nanobiotechnology Approaches for Treating Sepsis in Extracorporeal Circuits

Multiscale Biofluidic and Nanobiotechnology Approaches for Treating Sepsis in Extracorporeal Circuits

Magnetic Particles for Advanced Molecular Diagnosis

Biochemical functionality of magnetic particles as nanosensors: how far away are we to implement them into clinical practice?

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