Opsin-free optical neuromodulation and electrophysiology enabled by a soft monolithic infrared multifunctional neural interface

Gudmundsen

Jessen³

et al. 2022

Preprint

Self Cite

The combination of neuroimaging and targeted neuromodulation is a crucial tool to gain a deeper understanding of neural networks at a circuit level. Infrared neurostimulation (INS) is a promising optical modality that allows to evoke neuronal activity with high spatial resolution without need for the introduction of exogenous substances in the brain. Here, we report the use of whole-brain functional [18F]fluorodeoxyglucose positron emission tomography (FDG-PET) imaging during INS in the dorsal striatum, performed using a multifunctional soft neural probe. We demonstrate the possibility to identify multi-circuit connection patterns in both cortical and subcortical brain regions within a single scan. By using a bolus plus infusion FDG-PET scanning protocol, we were able to observe the metabolic rate evolution in these regions during the experiments and correlate its variation with the onset of the INS stimulus. Due to the focality of INS and the large amount of viable molecular targets for PET, this novel approach to simultaneous imaging and stimulation is highly versatile. This pilot study can pave the way to further understand the brain connectivity on a global scale.

Section: Discussionmentioning

confidence: 59%

“…In this study, we used soft infrared neural implants developed by our group for chronic INS applications described in [32] (Fig. 2A).…”

Section: Neural Implantsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Mapping whole brain effects of infrared neural stimulation with positron emission tomography

Gudmundsen

Jessen³

et al. 2022

Preprint

Self Cite

“…Commercially available rods of fluorinated ethylene-propylene (FEP) copolymer and polysulfone (PSU) were used as starting materials for the preform, [17][18][19] which was heated and pulled at a speed of 2 meters/minute to obtain a final fiber diameter of ∼ 400 μm (Figure 1a). Prior to the fiber fabrication, the viscosity-temperature profiles and refractive indices of both materials had been measured using a rotational rheometer (TA, Discovery Hybrid HR2) and ellipsometer (J.…”

Section: Fabrication and Characterization Of The Neural Interfacesmentioning

confidence: 99%

“…All the procedures concerning the housing of rats, habituation in the animal facility, surgery and post-surgery care were approved by the national veterinary and food administration (permission number for the animal research: 2019-15-0201-00018) and in compliance with the European Union Directive 2010/63/EU. All details of the surgical procedures are described in Meneghetti et al 18…”

Section: In Vivo Experimentsmentioning

confidence: 99%

Infrared neural stimulation and electrophysiology in a soft fiber-based neural interface

Optogenetics and Optical Manipulation 2023

Sui²,

Kaur³

et al. 2023

Infrared neurostimulation has emerged in recent years as a promising technique for controlling neuronal activity without genetic manipulation. Having high absorption of the employed wavelengths as its fundamental mechanism, it requires implantable platforms to deliver light in brain regions deeper than the first cortical layers. Due to the spatial confinement of the stimulation, electrodes integrated in close proximity to the illumination spot are desirable to verify the effects of the stimulation by extracellular electrophysiology. Here we developed and validated in vivo a multifunctional neural interface based on a soft, biocompatible polymer optical fiber that allows simultaneous infrared neurostimulation and electrophysiology.

Drug delivery and optical neuromodulation using a structured polymer optical fiber with ultra-high NA

Sui

Optogenetics and Optical Manipulation 2023

Kaur

et al. 2023

Implantable optical fibers have been widely used for optical neuromodulation in deep brain regions. Polymer fiber-based neural devices have natural advantages over silica fibers since their high flexibility would lead to a less inflammatory response in chronic in vivo experiments. Using three kinds of polymer materials: polycarbonate (PC), polysulfone (PSU), and fluorinated ethylene propylene (FEP), we present multifunctional soft polymer fiber (POF)-based brain implants with an Ultra-High Numerical Aperture (UHNA) and integrated Microfluidic Channels (MCs) for wide illumination and drug delivery, respectively. The flexibility of the proposed fiber devices has been found to be 100-fold reduced compared to their commercially available counterparts. Biofluids delivery can be controllably achieved over a wide range of injection rates spanning from 10 nL/min to 1000 nL/min by the structured MCs in the fiber cladding. The illumination area of the UHNA POFs in brain phantom has been increased significantly compared with the commercially available silica fibers. A fluorescent light recording experiment has been conducted to demonstrate the proposed UHNA POFs can be used as optical waveguides in fiber photometry. The limited illumination angle of the optical fiber imposed by current technology has been enlarged by the proposed UHNA POFs and we anticipate our work to pave the way toward more efficient multifunctional neural probes for neuroscience.