Abstract: A motorized joint filler scraper or shaver that rapidly and smoothly shaves joint filler flush to a floor. Aspects may include a blade attachment component that allows the blade to rotate relative to the frame of the shaver, allowing the blade to maintain contact with uneven surfaces and to be rotated to avoid dulling the blade through use of a single side. Further aspects may include an operator platform that allows the operator to ride along with the scraper.

Abstract: A microneedle injection apparatus (100) comprising an inverted actuator. The apparatus can include a housing (102) having a base and a cavity, and a microneedle array holder (106) configured to hold a microneedle array (107) within the cavity of the housing. The microneedle array holder can be movable between a retracted position, and an extended position. The apparatus can further include an actuator (104) movable with respect to the housing and the microneedle array holder between a first position and a second position to cause the microneedle array holder to move from the retracted position to the extended position. At least a portion of the actuator can be located on a skin-facing side of the apparatus (e.g., adjacent the base of the housing) and can be configured to be moved from the first position to the second position in response to the apparatus being pressed toward the skin surface.

Abstract: An electrostatic discharge robust semiconductor transistor (transistor) includes a semiconductor substrate of a first conductivity type, a substrate contact region of the first conductivity type coupled with the semiconductor substrate, a source region of a second conductivity type, a channel region of the second conductivity type, a gate region of the first conductivity type, a drain region having a first drain region of the first conductivity type and a second drain region of the second conductivity type, and an electrical conductor coupled over the second drain region and a portion of the first drain region. A portion of the first drain region not covered by the electrical conductor forms a resistive electrical ballast region configured to protect the transistor from electrostatic discharge (ESD) induced voltage pulses. In implementations the transistor includes a silicon controlled rectifier (SCR) junction field effect transistor (SCR JFET) or a laterally diffused metal-oxide semiconductor (SCR LDMOS).

Abstract: An adhesive hydrogel dressing as well as methods of applying the dressing to a patient. The dressing generally comprises an adhesive hydrogel pad, a backing layer, and an adhesive layer on the backing layer facing the hydrogel pad. The adhesive layer and backing layer form a perimeter around the hydrogel pad and hold the hydrogel pad in place on an application surface. A release element is in contact with at least a portion of the edge of the hydrogel pad proximate the area that the hydrogel pad and release liner separate during liner removal.

Abstract: A decoupling underlayment membrane is described. The decoupling underlayment membrane includes: a set of mortar cavities; a set of through holes; and an adhesive layer coupled to an exterior surface of each mortar cavity in the set of cavities. A method of manufacturing a decoupling underlayment membrane includes: retrieving a membrane sheet; thermoforming a set of cavities into a top surface of the membrane sheet; pressing a set of through holes into the membrane sheet. A decoupling underlayment membrane includes: a set of starfish-shaped cavities arranged in a first repeating pattern and formed into a top surface of the membrane; a set of through holes arranged in a second repeating pattern; and a peel and stick adhesive layer coupled to a bottom surface of the membrane.

Abstract: A microneedle injection apparatus comprising a dual cover. The apparatus can include a housing having a base and a cavity; a microneedle array comprising a first side comprising a plurality of microneedles; and a microneedle array holder configured to hold a microneedle array and located in the housing. The microneedle array holder can be movable between a retracted position, and an extended position. The apparatus can further include a cover (113) configured to be positioned to cover the opening (115) in the base (112) of the housing. The cover can include (i) a first portion (140) configured to cover at least a portion of the base of the housing adjacent the opening, and (ii) a second portion (142) configured to be received in the cavity of the housing and further configured to cover the plurality of microneedles on the microneedle array when the microneedle array holder is in the retracted position.

Abstract: A microneedle injection and infusion apparatus, and a method of using same. The apparatus (100) can include a housing (102), a microneedle array holder (106) for holding a microneedle array (107), and a shuttle (125) that holds a cartridge (e.g., that contains an active agent). The microneedle array holder can be movable between a retracted position and an extended position. The shuttle can be movable between a first position in which the cartridge is not in fluid communication with a fluid path and a second position in which the cartridge is in fluid communication with the fluid path. The apparatus can further include an actuator (104) movable between a first position and a second position. The method can include moving the actuator to its second position to allow the shuttle to move toward its second position, wherein movement of the shuttle toward its second position allows the microneedle array holder to move to its extended position.

Abstract: A microneedle injection apparatus (100) comprising an inverted actuator. The apparatus can include a housing (102) having a base and a cavity, and a microneedle array holder (106) configured to hold a microneedle array (107) within the cavity of the housing. The microneedle array holder can be movable between a retracted position, and an extended position. The apparatus can further include an actuator (104) movable with respect to the housing and the microneedle array holder between a first position and a second position to cause the microneedle array holder to move from the retracted position to the extended position. At least a portion of the actuator can be located on a skin-facing side of the apparatus (e.g., adjacent the base of the housing) and can be configured to be moved from the first position to the second position in response to the apparatus being pressed toward the skin surface.

Abstract: A silver composition comprising silver sulfate, methods of making antimicrobial articles, particularly packaged antimicrobial articles, methods of whitening antimicrobial articles, and packaged antimicrobial articles.

Abstract: A pill counting tray for counting pills. The pill counting tray includes a digital counter with a sensor that can digitally count the pills as they are being moved by a wand on the tray. The pill counting tray also includes a number of small evenly spaced terrain domes on one part of the tray to prevent the pills from clumping or clustering. The pill counting tray also includes a hinged return funnel that inclines upward when the pill counting tray is placed on a counter during counting, such that the hinged funnel creates a backstop to prevent pills from rolling off of the tray. The hinged funnel will rotate downward when the pill counting tray is lifted to ease the return of excess pills to the stock bottle. A portion of the surface of the hinged funnel also includes a number of spaced terrain domes.

Abstract: Systems and methods for reducing operational latency of data storage systems are disclosed. More particularly, a data storage device can perform conditioning operations on inactive zones while the data storage device is idle. When an active zone is the target of a write command, the data storage device can exchange a conditioned inactive zone for the unconditioned target zone. The write operation can be performed immediately on the previously-inactive already-conditioned zone. At a later time, the target zone can be conditioned.

Abstract: An applicator and method for applying a microneedle device to skin. The applicator can include a housing and a reciprocating support structure slidably engaged with the housing. The reciprocating support structure can have a plurality of alignment feet. The applicator can have a lockout mechanism that prevents actuation if the alignment feet are not evenly aligned. The applicator can include a device life indicator that is capable of counting the number of use cycles that the applicator has undergone and providing feedback to the user. The applicator can include a dose timer capable of determining the time that has elapsed after actuation of the device and providing feedback to the user.

Abstract: A decoupling underlayment membrane is described. The decoupling underlayment membrane includes: a set of mortar cavities; a set of through holes; and an adhesive layer coupled to an exterior surface of each mortar cavity in the set of cavities. A method of manufacturing a decoupling underlayment membrane includes: retrieving a membrane sheet; thermoforming a set of cavities into a top surface of the membrane sheet; pressing a set of through holes into the membrane sheet. A decoupling underlayment membrane includes: a set of starfish-shaped cavities arranged in a first repeating pattern and formed into a top surface of the membrane; a set of through holes arranged in a second repeating pattern; and a peel and stick adhesive layer coupled to a bottom surface of the membrane.

Abstract: Adhesive assemblies and microneedle injection apparatuses comprising same. The apparatus (100) can include a housing (102) having a base and an opening (115) formed in the base; and an applicator comprising a microneedle array (104), the microneedle array comprising a first major surface (111) and microneedles (105). The applicator can be movable between a first position, and a second position in which at least a portion of the microneedle array extends through the opening in the base. The apparatus can further include an adhesive assembly (118), which can be adhered to the base of the housing. The adhesive assembly can include an extension (125) that extends at least partially into the area defined by the opening, such that when the applicator is in the second position, at least a portion of the first major surface of the microneedle array is in contact with the extension of the adhesive assembly.

Abstract: In accordance with an embodiment, an electrical element includes a first portion of a first dielectric material between a first portion of a first electrical conductor and a first portion of a second electrical conductor and a second portion of the first dielectric material between a second portion of the first electrical conductor and a first portion of a third electrical conductor. In accordance with another embodiment, a method includes forming a first electrically conductive structure over a first portion of the first layer of dielectric material and forming a second electrically conductive structure over a second portion of the first layer of dielectric material. A second layer of dielectric material is formed over the first electrically conductive structure and a third electrically conductive structure over the second layer of dielectric material, wherein the third electrically conductive structure is over portions of the first and second electrically conductive structures.

Abstract: The present disclosure relates to systems and methods for delivering microneedles to a patient's skin. In one aspect, the present disclosure provides a system for delivering a microneedle array to a patient's skin surface, the system comprising: a delivery apparatus including a housing; and an infusion device detachably received in the housing.

Abstract: A decoupling underlayment membrane is described. The decoupling underlayment membrane includes: a set of mortar cavities; a set of through holes; and an adhesive layer coupled to an exterior surface of each mortar cavity in the set of cavities. A method of manufacturing a decoupling underlayment membrane includes: retrieving a membrane sheet; thermoforming a set of cavities into a top surface of the membrane sheet; pressing a set of through holes into the membrane sheet. A decoupling underlayment membrane includes: a set of starfish-shaped cavities arranged in a first repeating pattern and formed into a top surface of the membrane; a set of through holes arranged in a second repeating pattern; and a peel and stick adhesive layer coupled to a bottom surface of the membrane.

Abstract: A pill counting tray for counting pills. The pill counting tray includes a digital counter with a sensor that can digitally count the pills as they are being moved by a wand on the tray. The pill counting tray also includes a number of small evenly spaced terrain domes on one part of the tray to prevent the pills from clumping or clustering. The pill counting tray also includes a hinged return funnel that inclines upward when the pill counting tray is placed on a counter during counting, such that the hinged funnel creates a backstop to prevent pills from rolling off of the tray. The hinged funnel will rotate downward when the pill counting tray is lifted to ease the return of excess pills to the stock bottle. A portion of the surface of the hinged funnel also includes a number of spaced terrain domes.