Abstract: The present disclosure relates to mapping catheters, and in particular to mapping catheters having thin film electrodes used in sensing electrical activity within a patient. Particularly, aspects of the present disclosure are directed to a medical device having a hollow core, a balloon disposed over at least a portion of the hollow core, and a flexible framework having one or more thin film elements formed on at least a portion of the balloon. The one or more thin film elements comprise a plurality of mapping electrodes.

Abstract: Disclosed is a floating island construction method for overall transplantation of sandy soil plants, the method comprising the following steps: separation from a surrounding soil body; construction of a buoyancy tank device (13); and waterproof construction, so as to construct a plant floating island from plants to be transplanted in a reservoir area. The floating island protects all the root systems of the plants and most of the undisturbed soil, improves the survival rate, preserves the unique landscape of an original habitat, and can be constructed at the same time as water conservancy project construction, which saves on the construction period, saves costs, and is convenient for on-site overall scheduling.

Abstract: The present disclosure relates to branched proximal connectors for high density neural interfaces and methods of microfabricating the branched proximal connectors. Particularly, aspects of the present disclosure are directed to a branched connector that includes a main body having a base portion of a supporting structure and a plurality of conductive traces formed on the base portion, and a plurality of plugs extending from the main body. Each plug of the plurality of plugs include an end portion of the supporting structure comprised of the one or more layers of dielectric material, and a subset of conductive traces from the plurality of conductive traces. Each trace from the subset of conductive traces terminates at a bond pad exposed on a surface of the end portion of the supporting structure.

Abstract: A device may be configured to be located underneath an eyelid for treating ophthalmic conditions. The device may include an annular body and a flex circuit mounted on and conforming to at least a portion of an outer surface of the annular body. The flex circuit may include a substrate comprising an electronic circuitry portion and one or more electrode portions, and electronic circuitry attached to the electronic circuitry portion of the substrate. The flex circuit may further include one or more electrodes bonded to the substrate at the one or more electrode portions and electrically coupled to the electronic circuitry. An orientation around the annular body of each of the one or more electrodes may be based on a position on the substrate of a respective electrode portion of the one or more electrode portions.

Abstract: The technology disclosed attenuates spatial crosstalk from sequencing images for base calling. The technology disclosed accesses a section of an image output by a biosensor, where the section of the image includes a plurality of pixels depicting intensity emission values from a plurality of clusters within the biosensor and from locations within the biosensor that are adjacent to the plurality of clusters. The plurality of clusters includes a target cluster. The section of the image is convolved with a convolution kernel, to generate a feature map comprising a plurality of features having a corresponding plurality of feature values. A weighted feature value is assigned to the target cluster, where the weighted feature value is based on one or more features values of the plurality of feature values of the feature map. The weighted feature value assigned to the target cluster is processed, to base call the target cluster.

Abstract: The technology disclosed present systems and methods to produce an enhanced resolution image from images of a target using structured illumination microscopy (SIM). The method includes transforming at least three images of the target captured by a sensor in a spatial domain into a Fourier domain to produce at least three frequency domain matrices that each include first blocks of complex coefficients and redundant second blocks of complex coefficients that are conjugates to the first blocks. The method includes reducing computing resources required to produce the enhanced resolution image by using first blocks of complex coefficients to produce at least three phase-separated half-matrices in the Fourier domain. The method includes performing one or more intermediate transformation on the phase-separated half-matrices to produce realigned shifted half-matrices. The method includes calculating complex coefficients of second blocks in the Fourier domain to produce full matrices from half-matrices.

Abstract: The present disclosure relates to connectors for high density neural interfaces and methods of microfabricating the connectors. Particularly, aspects of the present disclosure are directed to a connector having a main body, a first plug extending from the main body, a flexible bridge extending from the main body or the first plug, and a second plug extending from the flexible bridge. This structure allows for the main body, the first plug, and the second plug to be arranged in tandem on a longitudinal axis of the main body, which enables the connector to be passed through a narrow diameter cannula. This structure also allows for the first plug and the second plug to be arranged in a spread out orientation, which enables the connector to be electrically connected with a neurostimulator.

Abstract: The present disclosure relates to branched proximal connectors for high density neural interfaces and methods of microfabricating the branched proximal connectors. Particularly, aspects of the present disclosure are directed to a branched connector that includes a main body having a base portion of a supporting structure and a plurality of conductive traces formed on the base portion, and a plurality of plugs extending from the main body. Each plug of the plurality of plugs include an end portion of the supporting structure comprised of the one or more layers of dielectric material, and a subset of conductive traces from the plurality of conductive traces. Each trace from the subset of conductive traces terminates at a bond pad exposed on a surface of the end portion of the supporting structure.

Abstract: Thin film connectors are described for connecting a lead assembly and a data acquisition system. Particularly, a connector includes a button having a housing and conductive pins extending from a proximal end of the housing through a base plate into a cavity on a distal end of the housing. The connector further includes a thin-film adapter having: (i) a supporting structure, (ii) bond pads formed on the supporting structure, (iii) a cable having conductive traces electrically connected to the bond pads, and (iv) feedthroughs that pass through the supporting structure and are electrically connected with the bond pads. Each conductive pin extends through a feedthrough, and each conductive pin is in electrical connection with one or more conductive traces via each bond pad.

Abstract: The present disclosure relates to connectors for high density neural interfaces and methods of microfabricating the connectors. Particularly, aspects of the present disclosure are directed to a connector having a core and a supporting structure wrapped around at least a portion of the core. The supporting structure may have a first layer of a high temperature liquid crystal polymer, and the second layer of a low temperature liquid crystal polymer that is reflowed to attach the supporting structure to the core. Conductive traces are buried between the first layer and the second layer, and the conductive traces terminate at conductive contacts formed on a surface of the first layer. The connector may have a predetermined shape or profile, which facilitates alignment and insertion of the connector into a header of a neurostimulator.

Abstract: The technology disclosed relates to structured illumination microscopy (SIM). In particular, the technology disclosed relates to capturing and processing, in real time, numerous image tiles across a large image plane, dividing them into subtiles, efficiently processing the subtiles, and producing enhanced resolution images from the subtiles. The enhanced resolution images can be combined into enhanced images and can be used in subsequent analysis steps. The technology disclosed includes logic to reduce computing resources required to produce an enhanced resolution image from structured illumination of a target. A method is described for producing an enhanced resolution image from images of a target captured under structured illumination. This method applies one or more transformations to non-redundant data and then recovers redundant data from the non-redundant data after the transformations.

Abstract: Thin parylene C membranes having smooth front sides and ultrathin regions (e.g., 0.01 ?m to 5 ?m thick) interspersed with thicker regions are disclosed. The back sides of the membranes can be rough compared with the smooth front sides. The membranes can be used in vitro to grow monolayers of cells in a laboratory or in vivo as surgically implantable growth layers, such as to replace the Bruch's membrane in the eye. The thin regions of parylene are semipermeable to allow for proteins in serum to pass through, and the thick regions give mechanical support for handling by a surgeon. The smooth front side allows for monolayer cell growth, and the rough back side helps prevents cells from attaching there.

Abstract: A stimulation system can include one or more stimulating components, each of which can include one or more electrodes and one or more leads. Each lead can be connected at a first end of the lead to an electrode of the one or more electrodes and can be connected at a second end of the lead to a bonding pad of the one or more bonding pads. The stimulation system can also include a cylindrical substrate. Each stimulating component can be secured to a surface of the cylindrical substrate. The stimulation system can further include a skull-mount package that includes electronics that identify stimulation parameters. The bonding pads can be electrically connected to the electronics. The skull-mount package can further include one or more bonding pads. Each lead can be directly electrically and physically connected to a bonding pad of the one or more bonding pads.

Abstract: A method is used to generate a report presenting parameter values corresponding to a structured illumination microscopy (SIM) optical system. The parameter values are based at least in part on the performed modulation calculation corresponding to an image set captured with the SIM optical system. A minimum FWHM slice is identified, based at least in part on an average FWHM value across the images in the first image set. Parameter estimation is performed on the identified minimum FWHM slice. Best in-focus parameters are identified based at least in part on the performed estimation. A phase estimate is performed for each image in the set. A modulation calculation is performed based at least in part on the identified best in-focus parameters. The report is based at least in part on the performed modulation calculation.

Abstract: The present disclosure relates to implantable neuromodulation devices and methods of fabrication, and in particular to a thin-film electrode assemblies and methods of fabricating the thin-film electrode assembly to include a soft overmold. Particularly, aspects of the present invention are directed to a thin-film electrode assembly that includes an overmold and a supporting structure formed within a portion of the overmold. The overmold includes a first polymer and the supporting structure includes a second polymer, different from the first polymer. The thin-film electrode assembly also includes a wire formed within a portion of the supporting structure, and an electrode formed on a top surface of the supporting structure and in electrical contact with the wire.

Abstract: A method is used to generate a report presenting parameter values corresponding to a structured illumination microscopy (SIM) optical system. The parameter values are based at least in part on the performed modulation calculation corresponding to an image set captured with the SIM optical system. A minimum FWHM slice is identified, based at least in part on an average FWHM value across the images in the first image set. Parameter estimation is performed on the identified minimum FWHM slice. Best in-focus parameters are identified based at least in part on the performed estimation. A phase estimate is performed for each image in the set. A modulation calculation is performed based at least in part on the identified best in-focus parameters. The report is based at least in part on the performed modulation calculation.

Abstract: Embodiments relate to an implantable device. Specifically, a device includes a flexible connection component that includes a set of conductive filaments that connect a set of electrodes (or traces connected to the electrodes) and circuitry that receives and/or transmits electronic signals from and/or to the electrodes.

Abstract: The present disclosure relates to a monolithic thin-film lead assembly and methods of microfabricating a monolithic thin-film lead assembly. Particularly, aspects of the present disclosure are directed to a monolithic thin-film lead assembly that includes a cable having a proximal end, a distal end, a supporting structure that extends from the proximal end to the distal end, and a plurality of conductive traces formed on a portion of the supporting structure. The supporting structure includes one or more layers of dielectric material. The monolithic thin-film lead assembly may further include an electrode assembly formed on the supporting structure at the distal end of the cable. The electrode assembly includes one or more electrodes in electrical connection with one or more conductive traces of the plurality of conductive traces.

Abstract: Embodiments of this application disclose an iOAM packet transmission method and related apparatus. In the method, a tail node device in a measurement domain receives a first iOAM packet, and determines whether the first iOAM packet includes an important data identifier. If the first iOAM packet includes the important data identifier, the tail node device generates, based on the first iOAM packet, a notification message that includes first node information, and sends the notification message to a management device in an iOAM network. According to the solution in the embodiments of this application, only when the received first iOAM packet includes the important data identifier, the tail node device generates the notification message based on the first iOAM packet and reports the notification message.