Multichannel power electronics and magnetic nanoparticles for selective thermal magnetogenetics

Wang, Boshuo; Li, Zhongxi; Sebesta, Charles; Hinojosa, Daniel Torres; Zhang, Qingbo; Robinson, Jacob T.; Bao, Gang; Peterchev, Angel V.; Goetz, Stefan M.

doi:10.1088/1741-2552/ac5b94

Cited by 18 publications

(7 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The small size, large surface, and more active area account for the extensive use of NPs in various applications, such as in drug delivery [ 88 ], diagnostics [ 89 ], food science [ 90 ], electronics [ 91 ], and several other biological and nonbiological areas. With the increased interest in nanotechnology in the last decade, the safety of NPs in the environment has also been considered.…”

Section: Application Of Nps In Vector-insectsmentioning

confidence: 99%

Nanoparticles: A Potential and Effective Method to Control Insect-Borne Diseases

Nie,

Li,

Xie

et al. 2023

Bioinorganic Chemistry and Applications

View full text Add to dashboard Cite

Insects act as vectors to carry a wide range of bacteria and viruses that can cause multiple vector-borne diseases in humans. Diseases such as dengue fever, epidemic encephalitis B, and epidemic typhus, which pose serious risks to humans, can be transmitted by insects. Due to the absence of effective vaccines for most arbovirus, insect control was the main strategy for vector-borne diseases control. However, the rise of drug resistance in the vectors brings a great challenge to the prevention and control of vector-borne diseases. Therefore, finding an eco-friendly method for vector control is essential to combat vector-borne diseases. Nanomaterials with the ability to resist insects and deliver drugs offer new opportunities to increase agent efficacy compared with traditional agents, and the application of nanoagents has expanded the field of vector-borne disease control. Up to now, the reviews of nanomaterials mainly focus on biomedicines, and the control of insect-borne diseases has always been a neglected field. In this study, we analyzed 425 works of the literature about different nanoparticles applied on vectors in PubMed around keywords, such as“nanoparticles against insect,” “NPs against insect,” and “metal nanoparticles against insect.” Through these articles, we focus on the application and development of nanoparticles (NPs) for vector control, discussing the lethal mechanism of NPs to vectors, which can explore the prospect of applying nanotechnology in the prevention and control of vectors.

show abstract

Section: Application Of Nps In Vector-insectsmentioning

confidence: 99%

Nanoparticles: A Potential and Effective Method to Control Insect-Borne Diseases

Nie,

Li,

Xie

et al. 2023

Bioinorganic Chemistry and Applications

View full text Add to dashboard Cite

show abstract

“…The force (torque) exhibited by MNPs in a uniform magnetic field can be harnessed to remotely change protein conformation, control organelles, and cells (Cho et al, 2012; Etoc et al, 2015; Hu et al, 2013; Jin et al, 2019; J. W. Kim et al, 2017). For example, superparamagnetic nanoparticles subjected to a rotating magnetic field can generate mechanical forces with a low piconewton (pN) range that can promote a conformational change of mechanosensitive ion channels and induce Ca 2+ influx into neurons for neuromodulation (Collier et al, 2022; Seo et al, 2016; Su et al, 2022; B. Wang et al, 2022; X. Wang et al, 2022). Others have also showed that magnetic nanorings can generate a mechanical force under a low‐frequency magnetic field, which can overcome the frictional force and provide the expected diffusion effect in tumor tissue.…”

Section: Mnms and Their Magneto‐responsive Propertiesmentioning

confidence: 99%

“…Using freely moving flies, the researchers showed that remote magneto‐thermal activation of TRPA1‐A channel caused a sub‐second wing‐opening response (Figure 3e,f). The introduction of novel heat‐sensitive ion channel such as TRPA1‐A was demonstrated as a good strategy to bring magneto‐thermal neuromodulation closer to the temporal precision of optogenetic methods (B. Wang et al, 2022; X. Wang et al, 2022).…”

Section: Mnms‐mediated Neuromodulationmentioning

confidence: 99%

Magnetic nanomaterials‐mediated neuromodulation

Wei

et al. 2023

WIREs Nanomed Nanobiotechnol

View full text Add to dashboard Cite

Researchers have leveraged magnetic nanomaterials (MNMs) to explore neural circuits and treat neurological diseases via an approach known as MNMsmediated neuromodulation. Here, the magneto-responsive effects of MNMs to an external magnetic field are manipulated to activate or inhibit neuronal cell activity. In this way, MNMs can serve as a nano-mediator, by converting electromagnetic energy into heat, mechanical force/torque, and an electrical field at nanoscale. These physicochemical effects can stimulate ion channels and activate precise signaling pathways involved in neuromodulation. In this review, we outline the various ion channels and MNMs that have been applied to MNMs-mediated neuromodulation. We highlight the recent advances made in this technique and its potential applications, and then discuss the current challenges and future directions of MNMs-mediated neuromodulation. Our aim is to reveal the potential of MNMs to treat neurological diseases in the clinical setting.

show abstract

“…A driver system was built high-electron-mobility gallium-nitride transistors (GS61008T,GaN Systems) as the H-bridge stage with an optimized magnetic board layout for high frequency and power switching operations 47 . This magnetic field driver was controlled using a custom script through Waveforms where control signals were sent through an Analog Discovery Pro (ADP3450/ADP3250).…”

Section: Magnetic Field Transmittermentioning

confidence: 99%

Endocisternal interfaces for minimally invasive neural stimulation and recording of the brain and spinal cord

Chen,

Dhuliyawalla,

Garcia

et al. 2023

Preprint

View full text Add to dashboard Cite

Minimally invasive neural interfaces can be used to diagnose, manage, and treat many disorders with substantially reduced risks of surgical complications. Endovascular neural interfaces implanted in the veins or arteries is one approach, but it requires prescriptions of anti-thrombotic medication and are likely not explantable after endothelialization. More critically, the approach is limited by the small size and location of blood vessels, such that many important cortical, subcortical, spinal targets cannot be reached. Here, we demonstrate a chronic endocisternal neural interface that approaches brain and spinal cord targets through inner and outer cerebral spinal fluid (CSF) spaces. These spaces surround the nervous system and lack the tortuosity of the circulatory system, giving us access to the entire brain convexity, deep brain structures within the ventricles, and the spinal cord from the spinal subarachnoid space. Combined with miniature magnetoelectric-powered bioelectronics, the entire wireless system is deployable through a percutaneous procedure. The flexible catheter electrodes can be freely navigated throughout the body from the spinal to cranial subarachnoid space, and from the cranial subarachnoid space to the ventricles. We show in a large animal model that we can also reposition the recording and stimulation electrodes or explant the neural interface after chronic implantation. This enables applications in therapies that require transient or permanent brain/machine interface such as stroke rehabilitation and epilepsy monitoring and opens a new class of minimally invasive endocisternal bioelectronics.

show abstract

Multichannel power electronics and magnetic nanoparticles for selective thermal magnetogenetics

Cited by 18 publications

References 38 publications

Nanoparticles: A Potential and Effective Method to Control Insect-Borne Diseases

Nanoparticles: A Potential and Effective Method to Control Insect-Borne Diseases

Magnetic nanomaterials‐mediated neuromodulation

Endocisternal interfaces for minimally invasive neural stimulation and recording of the brain and spinal cord

Contact Info

Product

Resources

About