Abstract: Systems and methods are provided for determining levels of an analyte in a biological fluid sample. A transdermal sampling and analysis device may include a substrate, at least one disruptor mounted on the substrate, a reservoir configured to collect and contain a biological fluid sample; a sensing element comprising at least two sensing electrodes, and at least one layer of a cofactor covering the sensing element in which the cofactor catalyzes a reaction to determine levels of an analyte in the biological fluid sample. The at least one disruptor of the transdermal sampling and analysis device may generate a localized heat capable of altering permeability characteristics of a stratum corneum layer of skin of an organism. The surface of at least one of the sensing electrodes of the transdermal sampling and analysis device may be coated with a sensing layer in which an enzyme immobilized within a hydrogel.

Abstract: Systems and methods are provided for determining levels of an analyte in a biological fluid sample. A transdermal sampling and analysis device may include a substrate, at least one disruptor mounted on the substrate, a reservoir configured to collect and contain a biological fluid sample; a sensing element comprising at least two sensing electrodes, and at least one layer of a cofactor covering the sensing element in which the cofactor catalyzes a reaction to determine levels of an analyte in the biological fluid sample. The at least one disruptor of the transdermal sampling and analysis device may generate a localized heat capable of altering permeability characteristics of a stratum corneum layer of skin of an organism. The surface of at least one of the sensing electrodes of the transdermal sampling and analysis device may be coated with a sensing layer in which an enzyme immobilized within a hydrogel.

Abstract: Provided are methods for treating a disease, disorder, or condition associated with an acid ceramidase (AC) biological activity. The methods include administering to a subject in need thereof a composition including an AC inhibitor and at least one additional active agent, such as a C6-ceramide nanoliposome (CNL); an inhibitor of a Bcl-2 family protein; a hypomethylating agent; an intensive chemotherapeutic agent such as cytarabine (AraC) and/or daunorubicin; a Hedgehog pathway inhibitor; a targeted agent, such as a FLT2 inhibitor or a EDH1/2 inhibitor; and/or an antibody drug conjugate that targets, for example, CD-33. The composition can include N-[(2S,3R)-1,3-dihydroxyoctadecan-2-yl]2-chloroacetamide (SACLAC) or a pharmaceutically acceptable salt thereof and at least one additional active agent. The disease, disorder, or condition associated with the AC biological activity can be a cancer, such as acute myeloid leukemia (AML).

Abstract: Systems and methods are provided for determining levels of a target analyte in a biological sample. A transdermal sampling and analysis device may include a substrate, at least one disruptor mounted on the substrate, a reservoir configured to collect and contain a biological sample, at least two electrodes, and an electrochemical bioassay configured to determine levels of a target analyte in the biological sample. The at least one disruptor of the transdermal sampling and analysis device may be configured to generate a localized heat capable of altering permeability characteristics of a stratum corneum layer of skin of an organism.

Abstract: Methods and systems for manufacturing a transdermal sampling and analysis device for non-invasively and transdermally obtaining biological samples from a subject and determining levels of analytes of the obtained biological samples are provided. A method of manufacturing the device may improve performance and includes forming channel structures on the lid of the device, thereby making the spacer/channel support structures physically independent and separable from the sensing electrode. Other methods of manufacturing the device may improve performance and include forming at least one of the electrodes on each of the base and the lid, and forming a recessed second spacer layer over the channel support structures, thereby separating the channel support structures and the electrode on the lid to allow a larger area of the electrode to be exposed to the biological sample.

Abstract: Systems and methods are provided for determining levels of a target analyte in a biological sample. A transdermal sampling and analysis device may include a substrate, at least one disruptor mounted on the substrate, a reservoir configured to collect and contain a biological sample, at least two electrodes, and an electrochemical bioassay configured to determine levels of a target analyte in the biological sample. The at least one disruptor of the transdermal sampling and analysis device may be configured to generate a localized heat capable of altering permeability characteristics of a stratum corneum layer of skin of an organism.

Abstract: Methods and systems for manufacturing a transdermal sampling and analysis device for non-invasively and transdermally obtaining biological samples from a subject and determining levels of analytes of the obtained biological samples are provided. A method of manufacturing the device may improve performance and includes forming channel structures on the lid of the device, thereby making the spacer/channel support structures physically independent and separable from the sensing electrode. Other methods of manufacturing the device may improve performance and include forming at least one of the electrodes on each of the base and the lid, and forming a recessed second spacer layer over the channel support structures, thereby separating the channel support structures and the electrode on the lid to allow a larger area of the electrode to be exposed to the biological sample.

Abstract: Systems and methods are provided for determining levels of an analyte in a biological fluid sample. A transdermal sampling and analysis device may include a substrate, at least one disruptor mounted on the substrate, a reservoir configured to collect and contain a biological fluid sample; a sensing element comprising at least two sensing electrodes, and at least one layer of a cofactor covering the sensing element in which the cofactor catalyzes a reaction to determine levels of an analyte in the biological fluid sample. The at least one disruptor of the transdermal sampling and analysis device may generate a localized heat capable of altering permeability characteristics of a stratum corneum layer of skin of an organism. The surface of at least one of the sensing electrodes of the transdermal sampling and analysis device may be coated with a sensing layer in which an enzyme immobilized within a hydrogel.

Abstract: A system and methods are provided for reducing electrochemical interference in a transdermal sampling and analysis device. A one-step transdermal glucose biosensor may calculate glucose concentrations that are artificially high compared to traditional home blood glucose sensors due to interference, which may be mitigated by forming an anti-interferent barrier layer over a sensing element. The anti-interferent barrier layer may be formed over a sensing layer and may possess a charge type which repels interferent molecules having the same charge type from interacting with the sensing layer disposed below the anti-interferent barrier layer.

Abstract: Methods and systems for manufacturing a transdermal sampling and analysis device for non-invasively and transdermally obtaining biological samples from a subject and determining levels of analytes of the obtained biological samples are provided. A method of manufacturing the device may improve performance and includes forming channel structures on the lid of the device, thereby making the spacer/channel support structures physically independent and separable from the sensing electrode. Other methods of manufacturing the device may improve performance and include forming at least one of the electrodes on each of the base and the lid, and forming a recessed second spacer layer over the channel support structures, thereby separating the channel support structures and the electrode on the lid to allow a larger area of the electrode to be exposed to the biological sample.