Your search keyword '"BIOMAGNETISM"' showing total 2,840 results

101. Artificial neural network model for predicting changes in ion channel conductance based on cardiac action potential shapes generated via simulation.

Author

Jeong, Da Un and Lim, Ki Moo

Subjects

*ELECTROPHYSIOLOGY, *NEUROLOGY, *ION channels, *PROTEINS, *BIOMAGNETISM

Abstract

Many studies have revealed changes in specific protein channels due to physiological causes such as mutation and their effects on action potential duration changes. However, no studies have been conducted to predict the type of protein channel abnormalities that occur through an action potential (AP) shape. Therefore, in this study, we aim to predict the ion channel conductance that is altered from various AP shapes using a machine learning algorithm. We perform electrophysiological simulations using a single-cell model to obtain AP shapes based on variations in the ion channel conductance. In the AP simulation, we increase and decrease the conductance of each ion channel at a constant rate, resulting in 1,980 AP shapes and one standard AP shape without any changes in the ion channel conductance. Subsequently, we calculate the AP difference shapes between them and use them as the input of the machine learning model to predict the changed ion channel conductance. In this study, we demonstrate that the changed ion channel conductance can be predicted with high prediction accuracy, as reflected by an F1 score of 0.985, using only AP shapes and simple machine learning. [ABSTRACT FROM AUTHOR]

Published

2021

102. Effect of Thermal Radiation on Biomagnetic Fluid Flow and Heat Transfer over an Unsteady Stretching Sheet.

Author

ALAM, Md. Jahangir, MURTAZA, Md. Ghulam, TZIRTZILAKIS, Efstratios E., and FERDOWS, Mohammad

Subjects

BIOMAGNETISM, FLUID flow, HEAT radiation & absorption, HEAT transfer, MAGNETIC fluids, MAGNETOHYDRODYNAMICS

Abstract

This study examines the influence of thermal radiation on biomagnetic fluid, namely blood that passes through a two-dimensional stretching sheet in the presence of magnetic dipole. This analysis is conducted to observe the behavior of blood flow for an unsteady case, which will help in developing new solutions to treat diseases and disorders related to human body. Our model is namely biomagnetic fluid dynamics (BFD), which is consistent with two principles: ferrohydrodynamic (FHD) and magnetohydrodynamic (MHD), where blood is treated as electrically conductive. It is assumed that the implemented magnetic field is sufficiently strong to saturate the ferrofluid, and the variation of magnetization with temperature may be approximated with the aid of a function of temperature distinction. The governing partial differential equations (PDEs) converted into ordinary differential equations (ODEs) using similarity transformation and numerical results are thus obtained by using the bvp4c function technique in MATLAB software with considering applicable boundary conditions. With the help of graphs, we discuss the impact of various parameters, namely radiation parameter, unsteady parameter, permeability parameter, suction parameter, magnetic field parameter, ferromagnetic parameter, Prandtl number, velocity and thermal slip parameter on fluid (blood) flow and heat transfer in the boundary layer. The rate of heat transfer and skin friction coefficient is also computationally obtained for the requirement of this study. The fluid velocity decreases with increasing values of the magnetic parameter, ferromagnetic interaction parameter, radiation parameter whereas temperature profile increases for the unsteady parameter, Prandtl number, and perme ability parameter. From the analysis, it is also observed that the skin friction coefficient decreases and the rate of heat transfer increases respectively with increasing values of the ferromagnetic interaction parameter. The most important part of the present analysis is that we neither neglect the magnetization nor electrical conductivity of the blood throughout this study. To make the results more feasible, they are compared with the data previously published in the literature and found to be in good accuracy. [ABSTRACT FROM AUTHOR]

Published

2021

103. A soft ferromagnetic multiwire-based inductance coil sensor for sensing applications.

Author

Devkota, J., Luong, T., Liu, J. S., Shen, H., Qin, F. X., Sun, J. F., Mukherjee, P., Srikanth, H., and Phan, M. H.

Subjects

*ELECTRIC inductance, *SENSITIVITY analysis, *AMORPHOUS semiconductors, *INDUCTIVE effect, *BIOMAGNETISM

Abstract

We present an effective approach to improve the sensitivity of inductance coil sensors by designing a sensor core that consists of multiple soft ferromagnetic microwires. A systematic study of the longitudinally excited magneto-inductive (LEMI) effect has been performed in a non-magnetic copper wire coil with a filler composed of multiple Co-rich amorphous microwires. Melt-extracted microwires of Co68.2Fe4.3B15Si12.5 and glass-coated microwires of Co68B15Si10Mn7 with excellent soft magnetic properties were used for this study. We have shown that the LEMI ratio and field sensitivity of an inductive coil depend strongly upon the filler-to-air ratio inside the coil, the magnetic softness, and the anisotropy axis distribution of the microwire. Relative to a single-microwire based sensor, the LEMI ratio and field sensitivity of a multi-microwire based sensor are enhanced by three to four times, when varying the number of microwires inside the inductive coil. The sensitivity of the sensor using four glass-coated Co68B15Si10Mn7 microwires in the core reaches a maximum value of 1957%/Oe. Our study paves a pathway for the development of novel roomtemperature electric contact free magnetic sensors for use in industry, biomagnetism, space science, and geoscience. [ABSTRACT FROM AUTHOR]

Published

2014

104. Control of Alternating Magnetic Field Distribution Using Twin Coils and Dual-Voltage Source Inverters to Realize High-Performance Biological Evaluation.

Author

Matsubara, Kazuki, Wada, Keiji, and Suzuki, Yukihisa

Subjects

*BIOMAGNETISM, *MAGNETIC fields, *MAGNETIC control, *WIRELESS power transmission, *MAGNETIC flux leakage, *PULSE width modulation transformers

Abstract

Recently, wireless power transfer (WPT) systems for electrical vehicles in the 85 kHz band have gained significant attention. However, human exposure due to the leakage magnetic field is a growing concern because WPT systems are installed in proximity to the human body. Therefore, it is essential to evaluate the biological effects induced by magnetic fields through experimental verification. To address this issue, a magnetic field generator was proposed for evaluating biological effects. A magnetic field generator must generate a higher alternating magnetic field. In addition, the biological experiments for sham exposure are conducted simultaneously under zero magnetic field conditions to perform control experiments. Therefore, it is preferable to provide a zero magnetic field environment under the same environment with exposure experiment except the magnetic field. This article proposes a magnetic field generator that consists of twin air-core coils and dual-inverter circuits that can produce either a higher or lower magnetic field at 85 kHz on the same system configuration. The analysis of the inverter circuit operations for in-phase and opposite phase is presented. Moreover, the validity of operation analysis for the proposed circuit is confirmed through the experimental verification of 1/10 current scale. [ABSTRACT FROM AUTHOR]

Published

2021

105. A hybrid magnetometer towards femtotesla sensitivity under ambient conditions.

Author

Xie, Yijin, Yu, Huiyao, Zhu, Yunbin, Qin, Xi, Rong, Xing, Duan, Chang-Kui, and Du, Jiangfeng

Subjects

*SUPERCONDUCTING quantum interference devices, *MAGNETOENCEPHALOGRAPHY, *MAGNETOMETERS, *MAGNETIC fields, *BIOMAGNETISM

Abstract

Detecting magnetic field is of great importance for many applications, such as magnetoencephalography and underground prospecting. There have been many magnetometers being widely used since the age of Hall magnetometer. One of the magnetometers, the superconducting quantum interference device, is capable of measuring femtotesla magnetic fields at cryogenic temperature. However, a solid-state magnetometer with femtotesla sensitivity under ambient conditions remains elusive. Here we present a hybrid magnetometer based on the ensemble nitrogen-vacancy centers in diamond with the sensitivity of (195 ± 60) fT / Hz 1 / 2 under ambient conditions, which can be further advanced to 11 fT / Hz 1 / 2 at 100 Hz with cutting-edge fabrication technologies. Our method will find potential applications in biomagnetism and geomagnetism. [ABSTRACT FROM AUTHOR]

Published

2021

106. Action potentials induce biomagnetic fields in carnivorous Venus flytrap plants.

Author

Fabricant, Anne, Iwata, Geoffrey Z., Scherzer, Sönke, Bougas, Lykourgos, Rolfs, Katharina, Jodko-Władzińska, Anna, Voigt, Jens, Hedrich, Rainer, and Budker, Dmitry

Subjects

*ACTION potentials, *BIOMAGNETISM, *CARNIVOROUS plants, *ELECTROENCEPHALOGRAPHY, *VENUS'S flytrap

Abstract

Upon stimulation, plants elicit electrical signals that can travel within a cellular network analogous to the animal nervous system. It is well-known that in the human brain, voltage changes in certain regions result from concerted electrical activity which, in the form of action potentials (APs), travels within nerve-cell arrays. Electro- and magnetophysiological techniques like electroencephalography, magnetoencephalography, and magnetic resonance imaging are used to record this activity and to diagnose disorders. Here we demonstrate that APs in a multicellular plant system produce measurable magnetic fields. Using atomic optically pumped magnetometers, biomagnetism associated with electrical activity in the carnivorous Venus flytrap, Dionaea muscipula, was recorded. Action potentials were induced by heat stimulation and detected both electrically and magnetically. Furthermore, the thermal properties of ion channels underlying the AP were studied. Beyond proof of principle, our findings pave the way to understanding the molecular basis of biomagnetism in living plants. In the future, magnetometry may be used to study long-distance electrical signaling in a variety of plant species, and to develop noninvasive diagnostics of plant stress and disease. [ABSTRACT FROM AUTHOR]

Published

2021

107. SELECTED ABSTRACTS.

Subjects

*BIOMAGNETISM, *SCIENTIFIC literature, *ANIMAL diversity, *WILDLIFE conservation, *RUBELLA, *AEROBIC bacteria, *URBAN animals, *CAMPYLOBACTER jejuni

Published

2021

108. Different narcotic gases and concentrations for immobilization of ostrich embryos for in-ovo imaging.

Author

Perkas O, Schmidt A, Kuehnel C, Greiser J, Hermeyer H, Klingner C, Freesmeyer M, and Winkens T

Subjects

Animals, Anesthetics, Inhalation, Sevoflurane adverse effects, Sevoflurane pharmacology, Narcotics toxicity, Immobilization, Isoflurane, Desflurane, Struthioniformes embryology, Embryo, Nonmammalian drug effects

Abstract

In-ovo imaging using avian eggs has been described as a potential alternative to animal testing using rodents. However, imaging studies are hampered by embryonal motion producing artifacts. This study aims at systematically comparing isoflurane, desflurane and sevoflurane in three different concentrations in ostrich embryos. Biomagnetic signals of ostrich embryos were recorded analyzing cardiac action and motion. Ten groups comprising eight ostrich embryos each were investigated: Control, isoflurane (2%, 4%, and 6%), desflurane (6%, 12%, and 18%) and sevoflurane (3%, 5%, and 8%). Each ostrich egg was exposed to the same narcotic gas and concentration on development day (DD) 31 and 34. Narcotic gas exposure was upheld for 90 min and embryos were monitored for additional 75 min. Toxicity was evaluated by verifying embryo viability 24 h after the experiments. Initial heart rate of mean 148 beats/min (DD 31) and 136 beats/min (DD 34) decreased over time by 44-48 beats/minute. No significant differences were observed between groups. All narcotic gases led to distinct movement reduction after mean 8 min. Embryos exposed to desflurane 6% showed residual movements. Isoflurane 6% and sevoflurane 8% produced motion-free time intervals of mean 70 min after discontinuation of narcotic gas exposure. Only one embryo death occurred after narcotic gas exposure with desflurane 6%. This study shows that isoflurane, desflurane and sevoflurane are suitable for ostrich embryo immobilization, which is a prerequisite for motion-artifact free imaging. Application of isoflurane 6% and sevoflurane 8% is a) safe as no embryonal deaths occurred after exposure and b) effective as immobilization was observed for approx. 70 min after the end of narcotic gas exposure. These results should be interpreted with caution regarding transferability to other avian species as differences in embryo size and incubation duration exist., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Perkas, Schmidt, Kuehnel, Greiser, Hermeyer, Klingner, Freesmeyer and Winkens.)

Published

2024

109. SQUID magnetoneurography: an old-fashioned yet new tool for noninvasive functional imaging of spinal cords and peripheral nerves.

Author

Adachi Y and Kawabata S

Abstract

We are engaged in the development and clinical application of a neural magnetic field measurement system that utilizes biomagnetic measurements to observe the activity of the spinal cord and peripheral nerves. Unlike conventional surface potential measurements, biomagnetic measurements are not affected by the conductivity distribution within the body, making them less influenced by the anatomical structure of body tissues. Consequently, functional testing using biomagnetic measurements can achieve higher spatial resolution compared to surface potential measurements. The neural magnetic field measurement, referred to as magnetoneurography, takes advantage of these benefits to enable functional testing of the spinal cord and peripheral nerves, while maintaining high spatial resolution and noninvasiveness. Our magnetoneurograph system is based on superconducting quantum interference devices (SQUIDs) similar to the conventional biomagnetic measurement systems. Various design considerations have been incorporated into the SQUID sensor array structure and signal processing software to make it suitable for detecting neural signal propagation along spinal cord and peripheral nerve. The technical validation of this system began in 1999 with a 3-channel SQUID system. Over the course of more than 20 years, we have continued technological development through medical-engineering collaboration, and in the latest prototype released in 2020, neural function imaging of the spinal cord and peripheral nerves, which could also be applied for the diagnosis of neurological disorders, has become possible. This paper provides an overview of the technical aspects of the magnetoneurograph system, covering the measurement hardware and software perspectives for providing diagnostic information, and its applications. Additionally, we discuss the integration with a helium recondensing system, which is a key factor in reducing running costs and achieving practicality in hospitals., Competing Interests: The authors had a financial relationship with Ricoh Company Ltd, which was involved in some part of research and development of the magnetoneurograph system., (© 2024 Adachi and Kawabata.)

Published

2024

110. Biomagnetics : Principles and Applications of Biomagnetic Stimulation and Imaging

Author

Shoogo Ueno, Masaki Sekino, Shoogo Ueno, and Masaki Sekino

Subjects

Magnetic resonance imaging, Imaging systems in medicine, Biomagnetism, Magnetic brain stimulation

Abstract

Discover the Most Advanced Technologies in BiomagneticsCo-edited by Professor Ueno, a leader in the biomagnetics field for over 40 years, Biomagnetics: Principles and Applications of Biomagnetic Stimulation and Imaging explains the physical principles of biomagnetic stimulation and imaging and explores applications of the latest techniques in neuroscience, clinical medicine, and healthcare. The book shows you how the techniques are used in hospitals and why they are so promising. A brief overview of recent research trends in biomagnetics provides you with an up-to-date, informative guide to explore further in this field.The book focuses on three important areas: Magnetic nerve stimulation and transcranial magnetic stimulation Biomagnetic measurements and imaging of the human brain by advanced technologies of magnetoencephalography and MRI Biomagnetic approaches to potential treatments of cancers, pains, and other neurological and psychiatric diseases, such as Alzheimer's disease and depression These core areas of the book were developed from the editors'prestigious graduate-level courses in biomedical engineering. The text also discusses biomagnetic approaches to advanced medicine, including regenerative and rehabilitation medicine.

Published

2015

111. Biomagnetism Leaders & Upstarts Converge in Sydney.

Subjects

MAGNETIC measurements, MAGNETIC control, BIOMAGNETISM, MAGNETIC fields, MAGNETIC shielding, TRANSCRANIAL magnetic stimulation

Published

2024

112. International Journal of Bioelectromagnetism

Subjects

bioelectricity, biomagnetism, physiology, diagnosis, therapy, Medical technology, R855-855.5, Physiology, QP1-981

Published

2020

113. Reports Summarize Central Nervous System Research from Heidelberg University Hospital (The auditory P2 is influenced by pitch changes but not pitch strength and consists of two separate subcomponents).

Subjects

CENTRAL nervous system, UNIVERSITY hospitals, AUDITORY cortex, BIOMAGNETISM, AUDITORY evoked response

Abstract

A recent report from Heidelberg University Hospital in Germany discusses research on the auditory P2 component of the central nervous system. The study found that the P2 component is influenced by changes in voice pitch, but not by pitch strength or harmonicity. The researchers also discovered that the P2 component consists of two separate subcomponents, which likely reflect processing at different stages of the auditory pathway. This information provides valuable insights into how the brain processes auditory stimuli. [Extracted from the article]

Published

2024

114. Extremely low-frequency electric field suppresses not only induced stress response but also stress-related tissue damage in mice.

Author

Harakawa, Shinji, Nedachi, Takaki, and Suzuki, Hiroshi

Subjects

*ELECTRIC fields, *THERAPEUTICS, *BIOMAGNETISM, *GLUCOCORTICOIDS, *DEHYDROGENASES

Abstract

Although extremely low-frequency electric fields (ELF-EF) have been utilised for therapeutic purposes, the biological effect and the underlying mechanism of ELF-EF have not been elucidated. Here, we developed a mouse model of immobilisation-induced increase in glucocorticoid (GC) to evaluate the effect of ELF-EF. Mice were exposed to 50-Hz 10 kV/m EF via a parallel plate electrode and immobilised as needed. The ELF-EF suppressed the immobilisation-induced increase in blood GC level. Here, the results of 32 tests using the model were pooled and analysed. The suppressive effect of ELF-EF on immobilisation-induced increase in GC was reproduced, and the GC level was slightly higher in the ELF-EF-treated mice than in the sham-controlled mice, a novel observation. The immobilisation-induced increase in lactate dehydrogenase, glutamic oxaloacetic transaminase, and glutamic pyruvic transaminase, markers of tissue damage, was suppressed by co-treatment with EF in the biochemical tests using the same plasma sample. In the metabolome analysis, the changes in corticosterones, leukotrienes, and hydroxyeicosatetraenoic acids, markers of inflammation, showed a pattern similar to that of the plasma GC level. Thus, ELF-EF suppresses the stress response that causes an increase in the GC level and slightly promotes GC production in the absence of stress. Moreover, the suppressive effect of ELF-EF on induced stress response might be involved in stress-induced tissue damage or inflammation in immobilised mice. Overall, the model and the data help explore the biological effect of ELF-EF and explain the stress-relieving effect of EF. They would be useful in determining the medical applications of EF in humans and animals. [ABSTRACT FROM AUTHOR]

Published

2020

115. Improved solutions to a TEAM problem for multi‐objective optimisation in magnetics.

Author

Di Barba, Paolo, Mognaschi, Maria Evelina, Lowther, David A., and Sykulski, Jan K.

Abstract

New solutions to a recently proposed benchmark TEAM problem for Pareto optimisation are presented. In the benchmark, an air‐cored solenoid of small size, which can be used, for example, for magnetic fluid hyperthermia, is considered. Two shape optimisations of the solenoid are proposed in the benchmark: synthesising a uniform magnetic field in a control region, considering also a sensitivity function (Problem 1) or synthesising a uniform magnetic field, simultaneously minimising the power losses (Problem 2). The benchmark is solved by means of three different nature‐inspired algorithms and a genetic one, namely micro biogeography‐inspired algorithm, wind‐driven optimisation, and the cuckoo search, taking the genetic algorithm NSGA‐II as a reference, because all these methods have proven to be effective in solving multi‐objective optimisation problems. [ABSTRACT FROM AUTHOR]

Published

2020

116. Optically pumped magnetometers enable a new level of biomagnetic measurements.

Author

Sander, Tilmann, Jodko-Władzińska, Anna, Hartwig, Stefan, Brühl, Rüdiger, and Middelmann, Thomas

Subjects

MAGNETOMETERS, MAGNETIC shielding, MAGNETIC fields, MAGNETOENCEPHALOGRAPHY, HUMAN body, BIOMAGNETISM

Abstract

The electrophysiological activities in the human body generate electric and magnetic fields that can be measured noninvasively by electrodes on the skin, or even, not requiring any contact, by magnetometers. This includes the measurement of electrical activity of brain, heart, muscles and nerves that can be measured in vivo and allows to analyze functional processes with high temporal resolution. To measure these extremely small magnetic biosignals, traditionally highly sensitive superconducting quantum-interference devices have been used, together with advanced magnetic shields. Recently, they have been complemented in usability by a new class of sensors, optically pumped magnetometers (OPMs). These quantum sensors offer a high sensitivity without requiring cryogenic temperatures, allowing the design of small and flexible sensors for clinical applications. In this letter, we describe the advantages of these upcoming OPMs in two exemplary applications that were recently carried out at Physikalisch-Technische Bundesanstalt (PTB): (1) magnetocardiography (MCG) recorded during exercise and (2) auditory-evoked fields registered by magnetoencephalography. [ABSTRACT FROM AUTHOR]

Published

2020

117. Recording brain activities in unshielded Earth's field with optically pumped atomic magnetometers.

Author

Rui Zhang, Wei Xiao, Yudong Ding, Yulong Feng, Xiang Peng, Liang Shen, Chenxi Sun, Teng Wu, Yulong Wu, Yucheng Yang, Zhaoyu Zheng, Xiangzhi Zhang, Jingbiao Chen, and Hong Guo

Subjects

*DRUG infusion pumps, *ALPHA rhythm, *MAGNETOMETERS, *MAGNETIC field measurements, *SUPERCONDUCTING quantum interference devices, *BIOMAGNETISM, *BRAIN

Abstract

The article explores the understanding the relationship between brain activity and specific mental function as important for medical diagnosis of brain symptoms, such as epilepsy. It discusses about the Magnetoencephalography, which uses an array of highsensitivity magnetometers to record magnetic field signals generated from neural currents occurring naturally in the brain, as a noninvasive method for locating the brain activities.

Published

2020

118. Metal concentrations and biological effects from one of the largest mining disasters in the world (Brumadinho, Minas Gerais, Brazil).

Author

Vergilio, Cristiane dos Santos, Lacerda, Diego, Oliveira, Braulio Cherene Vaz de, Sartori, Echily, Campos, Gabriela Munis, Pereira, Anna Luiza de Souza, Aguiar, Diego Borges de, Souza, Tatiana da Silva, Almeida, Marcelo Gomes de, Thompson, Fabiano, and Rezende, Carlos Eduardo de

Subjects

*MINERAL industries, *BIOMAGNETISM, *HEAVY metals, *RARE earth metals, *MARINE sediments

Abstract

The rupture of the Brumadinho mining tailings dam in Brazil is considered one of the largest mining disasters in the world, resulting in 244 deaths and 26 missing people, in addition to the environmental consequences. The present study aims to evaluate the concentrations of multiple elements and the biological effects on water and sediments of the Paraopeba River after the Brumadinho Dam rupture. The tailings are formed by fine particulate material with large amounts of Fe, Al, Mn, Ti, rare earth metals and toxic metals. In the water, the levels of Fe, Al, Mn, Zn, Cu, Pb, Cd and U were higher than those allowed by Brazilian legislation. In the sediments, Cr, Ni, Cu and Cd levels were higher than the established sediment quality guidelines (TEL-NOAA). The differences in metal concentrations in the water and sediments between the upstream and downstream sides of the dam illustrate the effect of the tailings in the Paraopeba River. Toxicological tests demonstrated that the water and sediments were toxic to different trophic levels, from algae to microcrustaceans and fish. The fish exposed to water and sediments containing mine ore also accumulated metals in muscle tissue. This evaluation emphasizes the necessity of long-term monitoring in the affected area. [ABSTRACT FROM AUTHOR]

Published

2020

119. Magnetic Measurement of Electrically Evoked Muscle Responses With Optically Pumped Magnetometers.

Author

Elzenheimer, Eric, Laufs, Helmut, Schulte-Mattler, Wilhelm, and Schmidt, Gerhard

Subjects

MAGNETIC measurements, MAGNETOMETERS, MAGNETIC shielding, MUSCLES, MAGNETIC fields

Abstract

Objective: Electroneurography has been an essential method for assessing peripheral nerve disorders for decades. During this procedure, a nerve is briefly electrically excited, and nerve conduction properties are identified by indirect means from the behavior of the innervated muscle. The magnetic field of the resulting muscle response can also be recorded by novel, uncooled magnetometers, which have become very attractive for different medical applications over recent years. These highly sensitive magnetometers are called optically pumped magnetometers. Methods: We performed unaveraged and averaged magnetic signal detection of electrically evoked muscle responses using optically pumped magnetometers. We then discussed the suitability of this procedure for clinical applications in the context of diagnostic value and in direct comparison with the current electrical gold standard. Results: The magnetic detection of muscle responses is possible using optically pumped magnetometers. Our magnetic results (averaged and unaveraged) closely match those from electrical measurements. Conclusion: Optically pumped magnetometers provide an alternative, contactless technology for electrode-based motor studies, but they are currently not ready for routine clinical use. This costly technology requires additional earth magnetic shielding because this is a prerequisite for proper operation. Currently, there are no diagnostic advantages over electrical measurements. Additionally, the required measurement setup and procedure are much more complicated. Significance: In contrast to already published proof-of-principle studies for magnetomyography, we report in detail the results of the magnetic measurements of electrically evoked muscle responses in a shielded environment by applying supramaximal stimulation and finally validate our findings with electroneurography data as a reference. [ABSTRACT FROM AUTHOR]

Published

2020

120. AC biosusceptometry and magnetic nanoparticles to assess doxorubicin-induced kidney injury in rats.

Author

Prospero, Andre G, Fidelis-de-Oliveira, Patrícia, Soares, Guilherme A, Miranda, Milena F, Pinto, Leonardo A, dos Santos, Daniela C, Silva, Vanessa dos S, Zufelato, Nicholas, Bakuzis, Andris F, and Miranda, José RA

Abstract

Aim: This paper aims to investigate a doxorubicin (DOX) chronic kidney disease rat model using magnetic nanoparticles (MNPs) associated with the alternate current biosusceptometry (ACB) to analyze its different perfusion profiles in both healthy and DOX-injured kidneys. Materials & methods: We used the ACB to detect the MNP kidney perfusion in vivo. Furthermore, we performed biochemical and histological analyses, which sustained results obtained from the ACB system. We also studied the MNP biodistribution. Results: We found that DOX kidney injury alters the MNPs' kidney perfusion. These changes became more intense as the disease progressed. Moreover, DOX has an important effect on MNP biodistribution as the disease evolved. Conclusion: This study provides new applications of MNPs in nephrology, instrumentation, pharmacology, physiology and nanomedicine. [ABSTRACT FROM AUTHOR]

Published

2020

121. A multi-channel parameters adjustable magnetic field generator.

Author

Chen, Yimei, Gao, Guohui, Xiong, Hui, Liu, Jinzhen, and Wang, Yuling

Subjects

*MAGNETIC fields, *MAGNETIC flux density, *BIOMAGNETISM, *BIOTHERAPY

Abstract

In order to increase the security and flexibility of the magnetic field generator, a multi-channel parameters adjustable (MCPA) magnetic field generator is designed and implemented in this paper. The circuit topology of the MCPA magnetic field generator is presented. The working principle of MCPA is analyzed. The pulse current is measured and verified by experiments. The results show that the pulsed current amplitude is adjustable under 1000 A, the adjustment range of the effective pulse width is 0–160 µs, and the adjustment range of the frequency is 1–10 Hz. The magnetic field intensity at 2.5 cm below the scalp of the brain was measured when the three channels were working at the same time. It can be seen that the intensity of the magnetic field in the central area is apparently higher than that in the surrounding. The channels of MCPA can also be chosen flexibly as needed. Therefore, it has a very high application and research value in the field of biological magnetism therapy. [ABSTRACT FROM AUTHOR]

Published

2020

122. El Biomagnetismo como regulador del Ciclo Menstrual en Ameno-rrea, A propósito de casos clínicos de Amenorrea Hipotalámica que fueron tratadas con el Biomagnetismo

Author

Ortiz Dueñas, Silvio Eleuterio, Ochoa Bustamante, Jessenia Paola, Toapanta González, Adriana Steffanie, Briones Nieto, Norma Stephanie, Medina Montoya, William Josue, Ortiz Dueñas, Silvio Eleuterio, Ochoa Bustamante, Jessenia Paola, Toapanta González, Adriana Steffanie, Briones Nieto, Norma Stephanie, and Medina Montoya, William Josue

Abstract

Amenorrhea is one of the main reasons for consultation in reproductive medicine, endocrinology and gyne-cology. Science has proven that bioelectrical imbalances in the body manifest themselves before biochemical changes. The change in the bioelectric signal influences the metabolism, previously, and some time later the disorder that we call disease begins. While the pathology can manifest as biochemical imbalances, the under-lying problem is electromagnetic. The purpose of this research is to report the clinical cases of patients with amenorrhea who were treated by biomagnetism in the medical consultation by the specialist in Gynecology and Obstetrics Dr. Silvio Ortiz Dueñas and to evidence bibliographic information available in scientific aca-demic digital repositories that apply the usefulness of Biomagnetism in the control of amenorrhea, as well as exposing, if found, the differences in the theory of the therapeutic Magnetic Field in diagnosed amenorrhea. It is assumed as a premise that it is an alternative for the treatment of amenorrhea, therefore, using the selection of works by their descriptors, the summary and analysis, a structure of organized findings is presented that build a contribution to knowledge in the proposed area., La amenorrea constituye uno de los principales motivos de consulta en medicina de la reproducción, en endo-crinología y en ginecología. La ciencia ha comprobado que los desequilibrios bioeléctricos en el organismo se manifiestan antes que los cambios bioquímicos. El cambio en la señal bioeléctrica influye sobre el metabolis-mo, previamente, y tiempo después comienza el desorden que denominamos enfermedad. Si bien la patología puede manifestarse como esequilibrios bioquímicos, el problema subyacente es electromagnético. El propó-sito de la presente investigación consiste en reportar los casos clínicos de pacientes con amenorrea que fueron tratados mediante el biomagnetismo en la consulta médica por el especialista en Ginecología y Obstetricia Dr. Silvio Ortiz Dueñas y evidenciar información bibliográfica disponible en repositorios digitales académicos cien-tíficos que aplique la utilidad del Biomagnetismo en el control de la amenorrea, así como exponer, de encon-trarse, las diferencias de la teoría del Campo Magnético terapéutico en amenorreas diagnosticadas. Se asume como premisa que es una alternativa para el tratamiento de amenorreas, por lo tanto, utilizando la selección de trabajos por sus descriptores, el resumen y análisis se presenta una estructura de los hallazgos organizados que construyan un aporte al conocimiento en el área propuesta.

Published

2023

123. On the mechanism of painful burn sensation in tattoos on magnetic resonance imaging (MRI). Magnetic substances in tattoo inks used for permanent makeup (PMU) identified:Magnetite, goethite, and hematite

Author

Serup, Jørgen, Alsing, Kasper Køhler, Olsen, Ole, Koch, Christian Bender, Hansen, Rasmus Hvass, Serup, Jørgen, Alsing, Kasper Køhler, Olsen, Ole, Koch, Christian Bender, and Hansen, Rasmus Hvass

Abstract

Background: Persons with cosmetic tattoos occasionally experience severe pain and burning sensation on magnetic resonance imaging (MRI). Objective: To explore the culprit magnetic substances in commonly used permanent makeup inks. Material and methods: 20 inks used for cosmetic tattooing of eyebrows, eyeliners, and lips were selected. Ink bottles were tested for magnetic behavior with a neodymium magnet. Eight iron oxide inks qualified for the final study. Metals were analyzed by Inductively Coupled Plasma Mass Spectrometry (ICP-MS). The magnetic fraction of inks was isolated and analyzed by X-ray fluorescence (XRF). Magnetic iron compounds were characterized by Mössbauer spectroscopy and powder X-ray diffraction (XRD). Results: ICP-MS showed iron in all magnetic samples, and some nickel and chromium. Mössbauer spectroscopy and XRD detected ferromagnetic minerals, particularly magnetite, followed by goethite and hematite. Conclusion: This original study of cosmetic ink stock products made with iron oxide pigments reports magnetic impurities in inks for cosmetic tattooing, e.g., magnetite, goethite, and hematite. These may be the main cause of MRI burn sensation in cosmetic tattoos. The mechanism behind sensations is hypothesized to be induction of electrical stimuli of axons from periaxonal pigment/impurity activated by magnetic force. Magnetite is considered the lead culprit.

Published

2023

124. Performances of compact integrated superconducting magnetometers for biomagnetic imaging.

Author

Granata, C., Vettoliere, A., Rombetto, S., Nappi, C., and Russo, M.

Subjects

*SUPERCONDUCTORS, *MAGNETOMETERS, *BIOMAGNETISM, *MAGNETIC flux, *SUPERCONDUCTING quantum interference devices, *MAGNETIC dipoles, *MAGNETOENCEPHALOGRAPHY

Abstract

In the present paper, performances of compact fully integrated superconducting quantum interference device (SQUID) magnetometers, recently developed, have been investigated in view of their employment in large multichannel systems for biomagnetic imaging. The analysis has been focused on SQUID sensors having a pickup loop side length of 3 and 4 mm based on a design aimed to maximize the magnetic flux transferred from the detection coil to the SQUID in comparison with a magnetometer with 9 mm side length having a suitable sensitivity for biomagnetic applications. The performance study has been consisted in the computation of the magnetic responses to a current dipole which is the most fundamental approach used in biomagnetism. The results have shown that the dipole current sensitivity of 4 mm long side compact magnetometers is suitable for application in multichannel systems for magnetoencephalography and magnetocardiography. [ABSTRACT FROM AUTHOR]

Published

2008

125. Improving microbial production of value-added products through the intervention of magnetic fields.

Author

Chen, Sirui, Jin, Yamei, Yang, Na, Wei, Liwen, Xu, Dan, and Xu, Xueming

Subjects

*BIOMAGNETISM, *MAGNETIC fields, *MAGNETICS

Abstract

[Display omitted] • Microbial fermentation is a mainstream method for producing high-value compounds. • Applications of magnetic fields in microbial fermentation were summarized. • Magnetic field assisted microbial fermentation devices were illustrated. • Underlying mechanisms behind biological effects of magnetic fields were elaborated. The magnetic field application is emerging as an auxiliary physical strategy to facilitate rapid biomass accumulation and intracellular production of compounds. However, the underlying mechanisms and principles governing the application of magnetic fields for microbial growth and biotransformation are not yet fully understood. Therefore, a better understanding of interdisciplinary technologies integration, expanded magnetic field application, and scaled-up industrial implementation is crucial. In this review, the magnetic field characteristics, magnetic field-assisted fermentation devices, and the working mechanism of magnetic field have been reviewed comprehensively from both physical and microbiological perspectives. The review suggests that magnetic fields affect the biochemical processes in microorganisms by mediating nutrient transport across membranes, electron transfer during photosynthesis and respiration, enzyme activity and gene expression. Moreover, the recent advances in magnetic field application for microbial fermentation and conversion in biochemical, food and agricultural fields have been summarized. [ABSTRACT FROM AUTHOR]

Published

2024

126. Tracking Airborne Pollution with Environmental Magnetism in A Medium-Sized African City

Author

Daouda Dawaï, Mélina Macouin, Sonia Rousse, Jean-François Léon, Merlin Gountié Dedzo, and Loïc Drigo

Subjects

magnetic susceptibility, biomagnetism, neem trees, Central Africa, deposited atmospheric dust, urban pollution, Meteorology. Climatology, QC851-999

Abstract

As in other parts of the world, air pollution over West and Central Africa has major health and meteorological impacts. Air quality assessment and its possible sanitary impact have become essential even in medium-sized towns, therefore amplifying the need for easy-to-implement monitoring methods with low environmental impact. We present here the potential of magnetic methods to monitor air quality at street level in the medium-sized city of Maroua (northern Cameroon) affected by dust-laden desert winds. More than five hundred (544) samples of bark and leaves taken from Neem trees in Maroua were analyzed. Magnetic susceptibility, saturation remanence, and S-ratio were found to determine the concentration and nature of magnetic particles. They are dominated by magnetite-like particle signals as a part of particulate emissions due to urban activities, including both traffic, composed of a substantial proportion of motorcycles, and wood burning for food preparation. We show that both bark and leaves from Neem trees are adequate passive bio-recorders. The use of both enables different times and heights to be sampled, allowing for the high-resolution monitoring, in terms of spatialization, of various urban environments. Particle emissions require assessment and screening that could be carried out rapidly and efficiently by magnetic methods on bio-recorders, even in cities impacted by dust-laden wind.

Published

2021

127. Modified beamformers for coherent source region suppression

Author

Dalal, Sarang S, Sekihara, Kensuke, and Nagarajan, Srikantan S

Subjects

beamformer, biomagnetism, functional neuroimaging, magnetoencephalography, MEG inverse problems, neuromagnetic signal processing

Abstract

Many tomographic source localization algorithms used in biomagnetic imaging assume, explicitly or sometimes implicitly, that the source activity at different brain locations are either independent or that the correlation structure between sources is known. Among these algorithms is a class of adaptive spatial filters known as beamformers, which have superior spatiotemporal resolution abilities. The performance of beamformers is robust to weakly coherent sources. However, these algorithms are extremely sensitive to the presence of strongly coherent sources. A frequent mode of failure in bearnformers occurs with reconstruction of auditory evoked fields (AEFs), in which bilateral auditory cortices are highly coherent in their activation. Here, we present a novel beamformer that suppresses activation from regions with interfering coherent sources. First, a volume containing the interfering sources is defined. The lead field matrix for this volume is computed and reduced into a few significant columns using singular value decomposition (SVD). A vector beamformer is then constructed by rejecting the contribution of sources in the suppression region while allowing for source reconstruction at other specified regions. Performance of this algorithm was first validated with simulated data. Subsequent tests of this modified beamformer were performed on bilateral AEF data. An unmodified vector beamformer using whole head coverage misplaces the source medially. After defining a suppression region containing the temporal cortex on one side, the described method consistently results in clear focal activations at expected regions of the contralateral superior temporal plane.

Published

2006

128. Time of Permanence in the Bloodstream and Biodistribution of MnFe2O4 in Rats: Preliminary Results

Author

Próspero, A. G., Fidelis-de-Oliveira, P., Quini, C. C., De Gobbi, J. I. F., Matos, J. F., Zufelato, N., Bakuzis, A. F., Miranda, J. R. A., MAGJAREVIC, Ratko, Editor-in-chief, Ładyzynsk, Piotr, Series editor, Ibrahim, Fatimah, Series editor, Lacković, Igor, Series editor, Rock, Emilio Sacristan, Series editor, Braidot, Ariel, editor, and Hadad, Alejandro, editor

Published

2015

129. Magnetite Biomineralization and Magnetoreception in Organisms : A New Biomagnetism

Author

Joseph L. Kirschvink, Douglas S. Jones, Bruce J. MacFadden, Joseph L. Kirschvink, Douglas S. Jones, and Bruce J. MacFadden

Subjects

Biomagnetism, Biomineralization, Magnetite, Magnetoreception

Abstract

The mystery of how migrating animals find their way over unfamiliar terrain has intrigued people for centuries, and has been the focus of productive research in the biological sci­ ences for several decades. Whether or not the earth's magnetic field had anything to do with their navigational abilities has sufaced and been dismissed several times, beginning at least in the mid to late 1800s. This topic generally remained out of the mainstream of scientific research for two reasons: (1) The apparent irreproducibility of many of the be­ havioral experiments which were supposed to demonstrate the existence of the magnetic sense; and (2) Perceived theoretical difficulties which were encountered when biophysi­ cists tried to understand how such a sensory system might operate. However, during the mid to late 1960s as the science of ethology (animal behavior) grew, it became clear from studies on bees and birds that the geomagnetic field is used under a variety of conditions. As more and more organisms were found to have similar abilities, the problem shifted back to the question as to the basis of this perception. Of the various schemes for trans­ ducing the geomagnetic field to the nervous system which have been proposed, the hy­ pothesis of magnetite-based magnetoreception discussed at length in this volume has per­ haps the best potential for explaining a wide range of these effects, even though this link is as yet clear only in the case of magnetotactic bacteria.

Published

2013

130. Magnetocardiogram measured by fundamental mode orthogonal fluxgate array.

Author

Hikaru Karo and Ichiro Sasada

Subjects

*FLUXGATE magnetometers, *RECEIVER operating characteristic curves, *BIOMAGNETISM, *MAGNETOCARDIOGRAPHY, *MAGNETOMETERS

Abstract

Magnetocardiography (MCG) of healthy volunteers has been measured by using a fundamental mode orthogonal fluxgate magnetometer array of 32 channels in a magnetic shielded room (MSR). Sensor heads, which are employed, consist of a 45mm long U-shaped amorphous wire core and a 1000-turn solenoid pick-up coil of 30mm in length and 3mm in outer diameter. The excitation current of 100 kHz with large dc bias current is fed directly into wire cores, which are connected in series, whereas the signal detection circuit is provided to each of the sensor heads. A special technique to avoid mutual interaction between sensor heads is implemented, where all the sensor heads are excited synchronously by using a single ac source. A 2-D array having 32 sensors with 4 cm grid spacing was used to measure MCG signals inside an MSR. Measured data from each channel were first filtered (0.16-100Hz pass band), then averaged for 2min synchronously with electrocardiogram's peaks taken from both hands. Noise remaining after the average is about 1.8 pTrms for the band-width of 0.16-100 Hz. The QRS complex and the T-wave are clearly detected. [ABSTRACT FROM AUTHOR]

Published

2015

131. Selective stimulation of rat sciatic nerve using an array of mm-size magnetic coils: a simulation study

Author

Pragya Kosta, David J. Warren, and Gianluca Lazzi

Subjects

biological tissues, physiological models, neurophysiology, neuromuscular stimulation, bioelectric potentials, muscle, biomagnetism, bioelectric phenomena, biomedical electrodes, targeted region, nontargeted regions, selectivity index, array configuration, traditional extraneural electrode arrays, selective neurostimulation, selective stimulation, rat sciatic nerve, mm-size magnetic coils, magnetic neural stimulation, electrical stimulation, selective activation, selective neural stimulation, single coil, three-dimensional heterogeneous multiresolution nerve model, magnetic fields, electric fields, performance metric, Medical technology, R855-855.5

Abstract

This work proposes and computationally investigate the use of magnetic neural stimulation as an alternative to electrical stimulation to achieve selective activation of rat sciatic nerve. In particular, they assess the effectiveness of an array of small coils to obtain selective neural stimulation, as compared to a single coil. Specifically, an array of four mm-sized coils is used to stimulate rat sciatic nerve, targeting the regions of fascicles that are associated with different muscles of the leg. To evaluate the selectivity of activation, a three-dimensional heterogeneous multi-resolution nerve model is implemented using the impedance method for the computation of the magnetic and electric fields in the nerve. The performance metric ‘selectivity index’ is defined that measures the recruitment of the targeted region compared to other non-targeted regions of the nerve. The selectivity index takes values between −1 (least selective) and 1 (most selective). For each targeted region, a selectivity index of 0.75 or better is predicted for the proposed array configuration. The results suggest that an array of coils can provide superior spatial control of the electric field induced in the neural tissue compared to traditional extraneural electrode arrays, thus opening the possibility to applications where selective neurostimulation is of interest.

Published

2019

132. Spin-dependent charge transport through 2D chiral hybrid lead-iodide perovskites.

Author

Haipeng Lu, Jingying Wang, Chuanxiao Xiao, Xin Pan, Xihan Chen, Brunecky, Roman, Berry, Joseph J., Kai Zhu, Beard, Matthew C., and Vardeny, Zeev Valy

Subjects

*NANOSCIENCE, *ELECTRON spin states, *ELECTRON beam deposition, *BIOMAGNETISM, *OXIDE minerals, *SPINTRONICS, *PEROVSKITE

Abstract

The article explores how spin-dependent charge transport through two dimension (2D) chiral hybrid lead-iodide perovskites. Topics discussed include inorganic framework with a chiral organic sublattice inducing chirality to the hybrid system; oriented chiral 2D-layered Pb-iodide organic/inorganic hybrid perovskite systems; and ferromagnet electrode confirm the occurrence of spin-dependent charge transport through the organic/inorganic layers.

Published

2019

133. Computational imaging of the cardiac activities using magnetocardiography.

Author

Bhat, Vikas R. and Anitha, H.

Subjects

*MAGNETOCARDIOGRAPHY, *BIOMAGNETISM, *MYOCARDIUM, *ENDOCARDIUM, *MAGNETIC fields, *INVERSE problems, *HEART physiology, *CHEST physiology, *BIOLOGICAL models, *FINITE element method, *MYOCARDIAL infarction, *HEART function tests

Abstract

The electrical impulses of the heart will generate a tiny magnetic field outside the thorax that is measured as Magnetocardiographic signals. The challenging study is to estimate the cardiac activities in terms of depolarisation and repolarization maps from the measured signals called as inverse problem. This is computed only if one has solved generic or subject- specific prior models using the anatomical structures of the myocardium, the torso and the detectors called as forward problem. In this study, the Discretised heart is priorily assumed as the dipolar sources forming a double layer. The thorax structure modelled with finite element meshes is considered in the forward study. The magnetocardiographic data are simulated using uniform double layer model representing transmembrane distribution on the epicardium and endocardium. Using this data, the activation maps are non-invasively imaged on the heart surface using Tikhonov's regularisation technique. The inverse study is extended to reconstruct the depolarisation sequences of the abnormal cases. [ABSTRACT FROM AUTHOR]

Published

2019

134. Effects of silver nanoparticles coated with anti‐HER2 on irradiation efficiency of SKBR3 breast cancer cells.

Author

Aghamiri, Shahin, Jafarpour, Ali, and Shoja, Mohsen

Abstract

Breast cancer is the second cause of death in the world. Ionising radiation is a potent mutagen that can cause DNA damage, chromosomes breakage, and cell death. In the present study, radiotherapy and nanoparticle‐antibodies (ABs) have been combined to enhance the efficacy of cancer cell treatment. Silver nanoparticles (SNP) were synthesised, coated with anti‐HER2, and then characterised with different techniques such as X‐ray diffraction, dynamic light scattering, transmission electron microscopy, Fourier transform infrared, and UV–Vis spectroscopy. SKBR3 cells were irradiated with cobalt‐60 in the presence of nanoparticle‐AB as the drug. Cell viability was measured using the diphenyltetrazolium bromide assay, and the cellular status was assessed by Raman spectroscopy. Irradiation considerably decreased cell viability proportionate to the dose increase and post‐irradiation time. The surface‐enhanced Raman spectroscopy increased the signal in the presence of SNP. Increasing the dose to 2 Gy increased the irradiation resistance, and higher dose increases (4 and 6 Gy) enhanced the irradiation sensitivity. Moreover, the cellular changes induced by irradiation in the presence of the drug were stable after 48 h. The authors results introduced the combination of the drug with radiation as an effective treatment for cancer and Raman spectroscopy as a suitable tool to diagnose effective irradiation doses. [ABSTRACT FROM AUTHOR]

Published

2019

135. Influence of a perpendicular magnetic field on biological effectiveness of carbon-ion beams.

Author

Inaniwa, Taku, Suzuki, Masao, Sato, Shinji, Noda, Akira, Muramatsu, Masayuki, Iwata, Yoshiyuki, Kanematsu, Nobuyuki, Shirai, Toshiyuki, and Noda, Koji

Subjects

*BIOMAGNETISM, *MAGNETIC fields, *LINEAR energy transfer, *MAGNETIC flux density, *MAGNETICS

Abstract

Purpose: Our previous study revealed that the application of a magnetic field longitudinal to a carbon-ion beam of 0.1 ≤ B//≤ 0.6 T enhances the biological effectiveness of the radiation. The purpose of this study is to experimentally verify whether the application of a magnetic field perpendicular to the beam also alters the biological effectiveness. Methods and materials: Most experimental conditions other than the magnetic field direction were the same as those used in the previous study to allow comparison of their results. Human cancer and normal cells were exposed to low (12 keV/μm) and high (50 keV/μm) linear energy transfer (LET) carbon-ion beams under the perpendicular magnetic fields of = 0, 0.15, 0.3, or 0.6 T generated by a dipole magnet. The effects of the magnetic fields on the biological effectiveness were evaluated by clonogenic cell survival. Doses that would result in the survival of 10%, D10s, were determined for the exposures and analyzed using Student's t-tests. Results: For both cancer and normal cells treated by low- and high-LET carbon-ion beams, the D10s measured in the presence of the perpendicular magnetic fields of ≥ 0.15 T were not statistically different (p ≫.05) from the D10s measured in the absence of the magnetic fields, = 0 T. Conclusions: Exposure of human cancer and normal cells to the perpendicular magnetic fields of ≤ 0.6 T did not alter significantly the biological effectiveness of the carbon-ion beams, unlike the exposure to longitudinal magnetic fields of the same strength. Although the mechanisms underlying the observed results still require further exploration, these findings indicate that the influence of the magnetic field on biological effectiveness of the carbon-ion beam depends on the applied field direction with respect to the beam. [ABSTRACT FROM AUTHOR]

Published

2019

136. Carbon ion and proton beam irradiation of a normal human TK6 lymphoblastoid cell line within a magnetic field of 1.0 tesla.

Author

Yudhistiara, B, Weber, KJ, Huber, PE, Ruehle, A, Brons, S, Haering, P, Debus, J, and Hauswald, H

Subjects

BIOMAGNETISM, LYMPHOBLASTOID cell lines, PROTON beams, ION beams, MAGNETIC fields

Abstract

Background: Considering the increasing simultaneous application of magnetic resonance imaging (MRI) for more precise photon radiotherapy, it will be likely for particle radiotherapy to adopt MRI for future image guiding. It will then be imperative to evaluate the potential biological effects of a magnetic field (MF) on particle irradiation. This study explores such effects on the highly radiosensitive TK6 lymphoblastoid human cell line. Methods: The following three parameters were measured after irradiation with either carbon ion or proton beams using spread out Bragg peaks and applying different doses within a perpendicular 1.0 T MF: (1) cell survival fraction (14 days postirradiation), (2) treatment-specific apoptosis, which was determined through the measurement of population in the sub-G1 phase, and (3) cell cycle progression by means of flow cytometry. These were compared to the same parameters measured without an MF. Results: The clonogenic assay in both treatment groups showed almost identical survival curves with overlapping error bars. The calculated α values with and without an MF were 2.18 (σ=0.245) and 2.17 (σ=0.234) for carbon ions and 1.08 (σ=0.138) and 1.13 (σ=0.0679) for protons, respectively. Similarly, the treatment-specific apoptosis and cell cycle progression showed almost identical curves with overlapping error bars. A two-sample, unpooled t-test analysis was implemented for comparison of all mean values and showed p-values >0.05. Conclusion: No statistically significant difference in biological response of the TK6 cells was observed when they were irradiated using spreadout Bragg peaks within a perpendicular 1.0 T MF as compared to those, which received the same dose without the MF. This should serve as another supporting piece of evidence toward the implementation of MRI in particle radiotherapy, though further research is necessary. [ABSTRACT FROM AUTHOR]

Published

2019

137. Non-Invasive Measurement of Glaucoma Disease at Earlier Stage Through GMR Sensor AH Biomagnetic Signal From Eye and RADWT Algorithm.

Author

Ganesh, E., Shanker, N. R., and Priya, M.

Abstract

In this paper, we propose a non-invasive method to detect glaucoma eye disease at the earlier stage from aqueous humor (AH) fluid’s biomagnetic signal in anterior chamber of eye. The AH fluid has biomagnetic emission because of magnetic material, such as sodium, potassium, chloride, bicarbonate, and protein. At present, the diagnosis of glaucoma was done at the later stage because of undetectable microvariation in the fundus image cup to disc size ratio measurement and because of similar symptoms in glaucoma eye and vision problem. In the proposed method, glaucoma can be detected through the acquisition of AH fluid biomagnetic signal from eye through giant magnetoresistance magnetometers (GMRs) sensor. The biomagnetic signal of AH fluid’s dynamic and static variation in eye is analyzed with the rational dilation wavelet transform (RADWT) algorithm. The variations of AH fluid is obtained through beta-blocker eye drops. From experiment, The AH fluid’s biomagnetic signal shows variations for the rate of dissipation of fluid in eye, such as normal and glaucoma eye, with and without eye drops. The AH biomagnetic signal correlates glaucoma disease with signal variance and RADWT subband energy for 50 glaucoma and 10 normal eye. The proposed method detect glaucoma eye in the early stage with 90% accuracy. The experimental result is validated with glaucoma measuring tonometer instrument. The earlier detection of glaucoma eye is measured through regression modeling. [ABSTRACT FROM AUTHOR]

Published

2019

138. Magnetically tunable iron oxide nanotubes for multifunctional biomedical applications.

Author

Das, Raja, Cardarelli, Jason A., Phan, Manh-Huong, and Srikanth, Hariharan

Subjects

*IRON oxides, *NANOTUBES, *FERRIC oxide, *IRON oxide nanoparticles, *METAL-insulator transitions, *THERMOTHERAPY, *MAGNETIC measurements, *HYDROTHERMAL synthesis

Abstract

Design of a multifunctional magnetic bionanosystem has become increasingly important towards advancing the future of clinical medicine. While hollow iron oxide nanoparticles with enhanced surface areas allow for more drug molecules to be attached to the particles, their relatively low saturation magnetization (M S) hinders their practicality in medicinal applications such as drug delivery and hyperthermia therapy. We demonstrate that this limitation can be overcome by utilizing 1D magnetic nanotubes that possess both enhanced surface areas and high M S. In this study, highly crystalline, tunable aspect ratio Fe 3 O 4 nanotubes have been successfully synthesized using a hydrothermal method. Magnetic measurements showed a clear Verwey transition (∼120 K) and high M S (∼75 emu/g) at 300 K, confirming the high quality of the synthesized Fe 3 O 4 nanotubes. Calorimetric experiments on randomly dispersed Fe 3 O 4 nanotubes in water with concentration of 1 mg/mL showed a large Specific Absorption Rate (SAR) value of 400 W/g for an AC magnetic field of 800 Oe, which increased to 500 W/g when the nanotubes were aligned parallel to the DC magnetic field and suspended in a 2% agar solution. Our study shows the possibility of using the Fe 3 O 4 nanotubes as a highly effective multifunctional nanoscale tool for targeted hyperthermia and on-demand drug delivery. • Hydrothermal synthesis of highly crystalline, tunable aspect ratio Fe 3 O 4 nanotubes. • Systematic study of the growth mechanism of the nanotubes. • The presence of Verwey transition and high M S (75 emu/g) at 300 K. • Nanotubes exhibited large SAR value compared to their hollow counterparts. • Dual-purpose applications in hyperthermia and on-demand drug delivery. [ABSTRACT FROM AUTHOR]

Published

2019

139. Enhancement of biological effectiveness of carbon-ion beams by applying a longitudinal magnetic field.

Author

Inaniwa, Taku, Suzuki, Masao, Sato, Shinji, Noda, Akira, Iwata, Yoshiyuki, Kanematsu, Nobuyuki, Shirai, Toshiyuki, and Noda, Koji

Subjects

*BIOMAGNETISM, *MAGNETIC fields, *LINEAR energy transfer

Abstract

Purpose: A magnetic field longitudinal to an ion beam will potentially affect the biological effectiveness of the radiation. The purpose of this study is to experimentally verify the significance of such effects. Methods and materials: Human cancer and normal cell lines were exposed to low (12 keV/μm) and high (50 keV/μm) linear energy transfer (LET) carbon-ion beams under the longitudinal magnetic fields of B// = 0, 0.1, 0.2, 0.3, or 0.6 T generated by a solenoid magnet. The effects of the magnetic fields on the biological effectiveness were evaluated by clonogenic cell survival. Doses that would result in a survival fraction of 10% (D10s) were determined for each cell line and magnetic field. Results: For cancer cells exposed to the low (high)-LET beams, D10 decreased from 5.2 (3.1) Gy at 0 T to 4.3 (2.4) Gy at 0.1 T, while no further decrease in D10 was observed for higher magnetic fields. For normal cells, decreases in D10 of comparable magnitudes were observed by applying the magnetic fields. Conclusions: Significant decreases in D10, i.e. significant enhancements of the biological effectiveness, were observed in both cancer and normal cells by applying longitudinal magnetic fields of B// ≥ 0.1 T. These effects were enhanced with LET. Further studies are required to figure out the mechanism underlying the observed results. [ABSTRACT FROM AUTHOR]

Published

2019

140. Systematic review on the biological effects of electric, magnetic and electromagnetic fields in the intermediate frequency range (300 Hz to 1 MHz).

Author

Bodewein, Lambert, Schmiedchen, Kristina, Dechent, Dagmar, Stunder, Dominik, Graefrath, David, Winter, Lukas, Kraus, Thomas, and Driessen, Sarah

Subjects

*ELECTROMAGNETIC fields, *INTERMEDIATE frequency amplifiers, *BIOLOGICAL systems, *BIOMAGNETISM, *META-analysis

Abstract

Abstract Background Many novel technologies, including induction cookers or wireless power transfer, produce electric fields (EF), magnetic fields (MF) or electromagnetic fields (EMF) in the intermediate frequency (IF) range. The effects of such fields on biological systems, however, have been poorly investigated. The aim of this systematic review was to provide an update of the state of research and to evaluate the potential for adverse effects of EF, MF and EMF in the IF range (300 Hz to 1 MHz) on biological systems. Methods The review was prepared in accordance with PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines. Methodical limitations in individual studies were assessed using the Office of Health Assessment and Translation (OHAT) Risk of Bias Rating Tool for Human and Animal Studies. Results Fifty-six studies exposing humans, animals or in vitro systems were eligible for this review. In these studies, many different endpoints were examined and most of the findings were obtained in studies with exposure to MF. For most endpoints, however, the reviewed studies yielded inconsistent results, with some studies indicating no effect and some linking IF exposure with adverse effects. In the majority of the included studies, the applied field strengths were above the International Commission on Non-Ionizing Radiation Protection (ICNIRP) reference levels for the general public and the applied frequencies were mainly below 100 kHz. Furthermore, many of the reviewed studies suffered from methodical limitations which lowered the credibility of the reported results. Conclusion Due to the large heterogeneity in study designs, endpoints and exposed systems, as well as the inconsistent results and methodical limitations in many studies, the quality of evidence for adverse effects remains inadequate for drawing a conclusion on investigated biological effects of IF fields for most endpoints. We recommend that in future studies, effects of EF, MF and EMF in the IF range should be investigated more systematically, i.e., studies should consider various frequencies to identify potential frequency-dependent effects and apply different field strengths, especially if threshold-dependent effects are expected. Priority should be given to the investigation of acute effects, like induction of phosphenes, perception, excitation of nerves or muscles and thermal effects. This would be an important step towards the validation of the reference levels recommended by ICNIRP. Furthermore, we recommend that any new studies aim at implementing high quality dosimetry and minimizing sources of risk of bias. Highlights • Biological effects of intermediate frequency fields were systematically analyzed. • Fifty-six experimental studies were eligible. • Weak field strengths and frequencies > 100 kHz have been hardly investigated. • Low quality of evidence for adverse effects for most examined endpoints. • Methodical limitations lowered credibility of the results. [ABSTRACT FROM AUTHOR]

Published

2019

141. Superconducting magnetic shield for MEG coupled with permalloy PC.

Author

Irisawa, Daiichi, Imai, Kumiko, Shintomi, Koichi, Yahara, Akihito, and Matsubara, Hironori

Subjects

*MAGNETIC shielding, *BIOMAGNETISM, *MAGNETIC noise, *COMPOSITE columns, *SQUIDS, *MAGNETOMETERS

Abstract

The Biomagnetism measurement is required shielding effect 1/S≦1/10−7 for using SQUID magnetometer. The superconducting shield is possible to realize ideal low magnetic noise space. But it is required to attenuate every external field inside the superconducting hollow cylinder equally. Especially, radial external field decreases gently comparison to axial field. At this time the length of cylinder needs 4.4 m for diameter 1 m to realize shielding effect 1/S≦1/10−7. On the other hand, it is only 2.1 m for axial field. For that reason, we devised two methods to attenuate radial field rapidly coupled with permalloy. [ABSTRACT FROM AUTHOR]

Published

2019

142. Numerical study of biomagnetic fluid flow in a duct with a constriction affected by a magnetic field.

Author

Mousavi, S. Morteza, Darzi, A. Ali Rabienataj, Akbari, Omid ali, Toghraie, Davood, and Marzban, Ali

Subjects

*BIOMAGNETISM, *FLUID flow, *MAGNETIC fields, *ELECTRIC currents, *SHEARING force

Abstract

Highlights • The influence of a non-uniform magnetic field on biomagnetic fluid flow. • Duct with constriction. • The magnetic field is generated by a wire carrying electric current. • Applying the magnetic field has significant effects on the walls shear stress. Abstract In this paper, the influence of a non-uniform magnetic field on biomagnetic fluid flow in a duct with a constriction is investigated numerically. The magnetic field is generated by a wire carrying electric current located outside the duct. The biomagnetic fluid dynamics model, which is based on the ferrohydrodynamics and magnetohydrodynamics, is used to study the fluid flow, and a computational grid properly covering the magnetic field is used for the simulation. In this investigation, the influence of magnetic field on biomagnetic fluid flow in various percentages of the duct constriction, and the effect of the magnetic field on the biomagnetic fluid flow in various strengths of magnetic force are studied. The magnetic field is spatially varying, and the magnetic field strength decreases by increasing the distance from the wire carrying electric current which is the magnetic source. The results show that, the influence of the magnetic field on biomagnetic fluid flow is considerable near the magnetic source. Applying the magnetic field with enough strength causes the recirculation areas downstream of constriction to become smaller. In addition, applying the magnetic field has significant effects on the wall shear stress, so that it can decrease the shear stress on the wall away from the magnetic source. [ABSTRACT FROM AUTHOR]

Published

2019

143. The effects of electric, magnetic and electromagnetic fields on microorganisms in the perspective of bioremediation.

Author

Beretta, Gabriele, Mastorgio, Andrea Filippo, Pedrali, Lisa, Saponaro, Sabrina, and Sezenna, Elena

Subjects

BIOREMEDIATION, MICROORGANISMS, ELECTRIC fields, MAGNETIC fields, ELECTROMAGNETIC fields, BIOMAGNETISM

Abstract

Some studies show how exposure to fields can enhance or reduce cell activity, with possible applicative consequences in the field of biotechnology, including biological techniques for depollution. In order to identify full-scale conditions that are suitable and potentially applicable for use in electromagnetic fields to stimulate and accelerate bioremediation processes, this paper offers an examination of the scientific literature that is available on the effects of fields on microorganisms, and a critical analysis of it. The biological effects at times contrast with each other. [ABSTRACT FROM AUTHOR]

Published

2019

144. Size effects of magnetic beads in circulating tumour cells magnetic capture based on streptavidin–biotin complexation.

Author

Li, Fulai, Xu, Hengyi, Sun, Pingfeng, Hu, Zhibin, and Aguilar, Zoraida P.

Abstract

Circulating tumour cells (CTCs) draw significant attention as a promising biomarker for cancer prognosis, status monitoring, and metastasis diagnosis. However, the concentration of CTCs in peripheral blood is usually extremely low, thereby requiring enrichment followed by isolation of CTCs prior to detection. An immunomagnetic separation is a promising tool for CTCs enrichment. In this study, a cost‐effective magnetic separation method, based on streptavidin–biotin complexation, was developed and the effects of magnetic beads' size in CTCs capture were compared. Magnetic nanobeads which were 25 nm in diameter lead to highest capture efficiency (82.2%) compared with 150 nm magnetic beads and 1 µm microbeads. Based on the streptavidin–biotin system, 25 nm magnetic nanobeads could capture model CTCs over 80% efficiency even at concentrations as low as ∼25 cells/mL that may represent the actual level of CTCs in peripheral blood of cancer patients. Furthermore, the isolated cells remained robust and healthy showing insignificant changes in morphology and behaviour when cultured for 24 h immediately after capture and isolation. The magnetic nanobeads based on streptavidin–biotin complexation showed promise for the easy and efficient capture and isolation of healthy CTCs for further diagnosis and analysis. [ABSTRACT FROM AUTHOR]

Published

2019

145. Antidepressant Effects of Repetitive Transcranial Magnetic Stimulation Over Prefrontal Cortex of Parkinson's Disease Patients With Depression: A Meta-Analysis.

Author

Zhou, Liang, Guo, Zhiwei, Xing, Guoqiang, Peng, Haitao, Cai, Mengjie, Chen, Huaping, McClure, Morgan A., He, Lin, Xiong, Liangwen, He, Bin, Du, Fei, and Mu, Qiwen

Subjects

ANTIDEPRESSANTS, PSYCHIATRIC drugs, TRANSCRANIAL magnetic stimulation, BRAIN stimulation, BIOMAGNETISM

Abstract

Objective: The purpose of this meta-analysis was to investigate the antidepressant effects of repetitive transcranial magnetic stimulation (rTMS) over the prefrontal cortex (PFC) of patients with Parkinson's disease (PD) and to determine the optimal rTMS parameters, such as the intensity, frequency and the delivered pattern of rTMS stimulation. Methods: EMBASE, PubMed, Web of Science, MEDLINE, and Cochrane data bases were researched for papers published before March 12, 2018. Studies investigating the anti-depression effects of rTMS over PFC in patients with PD were considered. The main outcomes of pre- and post-rTMS treatment as well as score changes were all extracted. The mean effect size was estimated by calculating the standardized mean difference (SMD) with 95% confidence interval (CI) by using fixed or random effect models as appropriate. Results: Nine studies containing 137 PD patients with depression were included. The pooled results showed significant pre-post anti-depressive effects of rTMS over PFC in PD patients with depression (SMD = −0.80, P < 0.00001). The subgroup analyses of stimulation intensity, frequencies, and models also revealed significant effects (Intensities: 90% RMT: SMD = −1.16, P = 0.0006; >100% RMT: SMD = −0.82, P < 0.0001. Frequencies: < 1.0 Hz: SMD = −0.83, P = 0.03; 5.0 Hz: SMD = −1.10, P < 0.0001; ≥10.0 Hz: SMD = −0.55, P = 0.02. Models: Continuous: SMD = −0.79, P < 0.0001; Discontinuous: SMD = −0.84, P = 0.02). But the results of the studies with place-controlled designs were not significant (Overall: SMD = −0.27, P = 0.54. Intensities: 90% RMT: SMD = 0.27, P = 0.68; 100% RMT: SMD = −0.32, P = 0.33. Frequencies: 5.0 Hz: SMD = −0.87, P = 0.10; ≥10.0 Hz: SMD = 0.27, P = 0.66. Models: Continuous: SMD = −0.28, P = 0.68; Discontinuous: SMD = −0.32, P = 0.33). The greater effect sizes of rTMS with 90% RMT, 5.0 Hz in discontinuous days can be observed rather than the other parameters in both kinds of analyses across study design. Conclusions: rTMS may have a significant positive pre-post anti-depressive effect over PFC on patients with depression, especially by using 5.0 Hz frequency with 90% RMT intensity in discontinuous days, which may produce better effects than other parameters. The real effect, though, was not different from that of the placebo. Future studies with larger sample sizes and high-quality studies are needed to further corroborate our results and to identify the optimal rTMS protocols. [ABSTRACT FROM AUTHOR]

Published

2019

146. Discrete spatial filtering with SQUID gradiometers in biomagnetism.

Author

Bruno, A. C., Costa Ribeiro, P., von der Weid, J. P., and Symko, O. G.

Subjects

*BIOMAGNETISM, *BIOPHYSICS

Abstract

Presents a study which analyzed first-, second-, and third-order gradiometers in detecting biomagnetic signals as spatial filters. Taylor series approach of the gradiometer sensor; Nonrecursive spatial filter approach of the sensor; Phase characteristics.

Published

1986

147. ANIMAL MAGNETISM.

Author

Nicholls, Henry

Subjects

*ANIMAL magnetism, *MAGNETORECEPTION, *BIOMAGNETISM, *ANIMAL behavior, *MAGNETIC fields, *ZOOLOGY

Abstract

The article cites evidences that animals have the ability to sense magnetism and align themselves in a particular direction. Topics discussed include studies on animal magnetism conducted by entomologist Purushottam Deoras, zoologist Hynek Burda and ornithologist Roswitha Wiltschko, the possible reasons why animals sense the magnetic field, and human magnetoreception.

Published

2016

148. Your body the powerplant.

Author

Holmes, Bob

Subjects

*ELECTRIC battery design & construction, *MEDICAL innovations, *BIOTECHNOLOGY experiments, *BIOTECHNOLOGY, *SCIENTIFIC apparatus & instruments, *BIOMAGNETISM

Abstract

The article reports that medical researchers are working on pacemakers and other medical apparatus that would run off the energy produced by the human body as opposed to batteries. Most of the experimental implantable biofuel cells built so far use enzymes to catalyse the reactions. An alternative solution being explored is using a disposable battery attached to a renewable patch.

Published

2007

149. Medical Applications of Magnetism.

Author

Frei, E. H.

Subjects

MAGNETISM, MAGNETIC fields, ELECTRIC currents, MAGNETOTHERAPY, BIOMAGNETISM, PHYSIOLOGICAL effects of magnetic fields, MAGNETISM -- Experiments, FERROMAGNETISM

Abstract

The article discusses the use of magnetism in medicine. Magnetism has been used in various diagnostic and therapeutic process in medicine and physiology. Some of the advanced research at the Wiezmann Institute and other institutions regarding the magnetic fields is discussed and evaluated including the electric potentials or magnetic phosphenes, muscle stimulation, and magnetic controls. The development of magnetic tools are also discussed including magnetic catheters, and the improvement of contrast materials for X-ray.

Published

1972

150. The influence of plant species, leaf morphology, height and season on PM capture efficiency in living wall systems.

Author

Koch, Kyra, Wuyts, Karen, Denys, Siegfried, and Samson, Roeland

Published

2023