Abstract: A sensor module assembly for a respiratory therapy apparatus may be configured for a seal-based securement within a respiratory therapy device that includes a separable pneumatic block to make assembly or replacement more efficient. The sensor module assembly may include a flow manifold. The flow manifold may have an inlet and an outlet and a main pneumatic path between the inlet and the outlet. The assembly may have a sensor module with sensor(s) on a printed circuit board. The sensor module may be pneumatically and fixedly coupled to the flow manifold. The inlet of the flow manifold may be configured for removable coupling with an outlet of the pneumatic block assembly. Moreover, the outlet of the flow manifold may be configured for removable coupling with a pneumatic path of a housing panel of the respiratory therapy apparatus. The pneumatic path is adapted for supplying breathable gas to a patient interface.

Abstract: Using a computer system, an instruction is received to define or modify a permission constraint corresponding to one or more files. A permission-instruction data set representing the permission constraint is stored in a data store. Subsequent to storing the permission-instruction data, a user request to access a particular file is intercepted. The data store is queried to determine whether any pending permission-instruction data set corresponds to the particular file. In response to the query, it is determined that the permission-instruction data set corresponds to the particular file. A permission constraint of the particular file is added or modified based on the permission-instruction data set. Based on the modified or added permission constraint, it is determined whether and/or an extent to which the user request is authorized. A response to the user request based on the determination as to whether and/or an extent to which the user request is authorized.

Abstract: Using a computer system, an instruction is received to define or modify a permission constraint corresponding to one or more files. A permission-instruction data set representing the permission constraint is stored in a data store. Subsequent to storing the permission-instruction data, a user request to access a particular file is intercepted. The data store is queried to determine whether any pending permission-instruction data set corresponds to the particular file. In response to the query, it is determined that the permission-instruction data set corresponds to the particular file. A permission constraint of the particular file is added or modified based on the permission-instruction data set. Based on the modified or added permission constraint, it is determined whether and/or an extent to which the user request is authorized. A response to the user request based on the determination as to whether and/or an extent to which the user request is authorized.

Abstract: An instruction is received to define or modify a permission constraint corresponding to one or more file. A period of time is determined, where the period is one during which the defined or modified permission constraint is to apply to the one or more files. It is determined that the one or more files are to be deleted following completion of the period of time. A permission-instruction data set representing the permission constraint and a flag indicating that the one or more files are to be deleted following completion of the period of time are stored in a data store. It is detected that the period of time has ended. The one or more files are deleted in response to the detection.

Abstract: Various examples described herein are directed to systems and methods for securing data. A security system may receive a first record comprising a plurality of record fields, where the plurality of record fields includes a first record field and the first record field includes a first record field data. The security system may access a source setup record corresponding to the first record from a source setup table and determine that the source setup record comprises data referencing the first record field. The security system may access first token data corresponding to the first record field data and replace the first record field data at the first record field with the first token data. The security system may store the first token data at a token table and writing the first token data to the first record field to replace the first record field data.

Abstract: Systems and methods for case management systems provide the ability to automatically create cases when issues are identified with shipments, to assign ownership to the created cases, and to communicate directly with internal or external teams. Embodiments include a system and method that uses machine learning (ML) models to determine shipment exception causes and dispositions. The case management system applies this, and other information to case rules to trigger the automatic creation of cases.

Abstract: Various examples described herein are directed to systems and methods for securing data. A security system may receive a first record comprising a plurality of record fields, where the plurality of record fields includes a first record field and the first record field includes a first record field data. The security system may access a source setup record corresponding to the first record from a source setup table and determine that the source setup record comprises data referencing the first record field. The security system may access first token data corresponding to the first record field data and replace the first record field data at the first record field with the first token data. The security system may store the first token data at a token table and writing the first token data to the first record field to replace the first record field data.

Abstract: Various examples described herein are directed to systems and methods for securing data. A security system may receive a first record comprising a plurality of record fields, where the plurality of record fields includes a first record field and the first record field includes a first record field data. The security system may access a source setup record corresponding to the first record from a source setup table and determine that the source setup record comprises data referencing the first record field. The security system may access first token data corresponding to the first record field data and replace the first record field data at the first record field with the first token data. The security system may store the first token data at a token table and writing the first token data to the first record field to replace the first record field data.

Abstract: An electrochemical test device for detecting a first analyte and a second analyte in a fluid sample is provided. The device comprises a first conductor layer arranged to receive a fluid sample, wherein the first conductor layer comprises a first working electrode for receiving sensing chemistry for the first analyte and a second working electrode for receiving sensing chemistry for the second analyte; and wherein a layer of the electrochemical test device is arranged to provide error correction information for correcting a measurement of a response of the fluid sample with at least one sensing chemistry received on the first conductor layer.

Abstract: Described and illustrated herein are one exemplary method and a measurement system having a meter and a test strip. The test strip has a first working electrode, reference electrode and second working electrode. In this method, acceptable fill data from known first current and known second current are used to predict an estimated second current at proximate the second time period (for a given batch of test strips) during the test sequence. The estimated second current at proximate the second time interval is then compared with a measured actual second current at proximate the second time interval during an actual test to determine if the measured actual second current is substantially equal to or within an acceptable percent deviation from the estimated second current so as to determine sufficient volume of a physiological fluid sample in the test strip.

Abstract: Information in a data set of a copy-on-write file system may be made inaccessible. A first key for encrypting a data set of a copy-on-write file system is generated and wrapped with a second key. An encrypted data set is created with the first key. The wrapped first key is stored with the encrypted data set. A command to delete the encrypted data set is received and the second key is altered or changed to make information in the encrypted data set of the copy-on-write file system inaccessible.

Abstract: Described and illustrated herein are one exemplary method and a measurement system having a meter and a test strip. The test strip has a first working electrode, reference electrode and second working electrode. In this method, acceptable fill data from known first current and known second current are used to predict an estimated second current at proximate the second time period (for a given batch of test strips) during the test sequence. The estimated second current at proximate the second time interval is then compared with a measured actual second current at proximate the second time interval during an actual test to determine if the measured actual second current is substantially equal to or within an acceptable percent deviation from the estimated second current so as to determine sufficient volume of a physiological fluid sample in the test strip.

Abstract: Described and illustrated herein are one exemplary method and a measurement system having a meter and a test strip. The test strip has a first working electrode, reference electrode and second working electrode. In this method, acceptable fill data from known first current and known second current are used to predict an estimated second current at proximate the second time period (for a given batch of test strips) during the test sequence. The estimated second current at proximate the second time interval is then compared with a measured actual second current at proximate the second time interval during an actual test to determine if the measured actual second current is substantially equal to or within an acceptable percent deviation from the estimated second current so as to determine sufficient volume of a physiological fluid sample in the test strip.

Abstract: Devices for determining the concentration of an analyte in a fluid are provided. Also provided are systems and kits for use in practicing the subject methods.

Abstract: An analytical test strip and test meter combination for use in the determination of an analyte in a bodily fluid sample includes an analytical test strip and a test meter, and a method for determination thereof. The analytical test strip has an electrode, a first electrical contact pad in electrical communication with the electrode and configured to communicate an electrical response of the electrode to the test meter; and a second electrical contact pad in electrical communication with the electrode and configured to communicate an electrical response of the electrode to the test meter should the test meter be in electrical communication with the second electrical contact pad. In addition, the second electrical contact pad has electrical continuity with the first electrical contact pad and the first and second electrical contact pads are disposed in either of first and second predetermined spatial relationships to one another.

Abstract: A method for encrypting data includes receiving a block of plaintext for a data set at one or more computers, acquiring a cryptographic key for the data set, generating an initialization vector for the block of plaintext based on the block of plaintext, and encrypting the block of plaintext using the cryptographic key and the initialization vector.

Abstract: An electrochemical-based analytical test strip for the determination of an analyte (such as glucose) in a bodily fluid sample (for example, whole blood) includes an electrically insulating base layer, a patterned conductor layer disposed over the electrically-insulating layer, and a patterned insulation layer, with an electrode exposure window therethrough, disposed over the patterned conductor layer. The patterned conductive layer of the electrochemical-based analytical test strip includes at least one working electrode and a counter/reference electrode. In addition, at least a portion of the electrode exposure window is configured to expose a working electrode exposed portion and a counter/reference electrode exposed portion, with the working electrode exposed portion being rectangular in shape and the counter/reference electrode exposed portion being one of a crossroads shape and an at least six-sided portion of a crossroads shape.

Abstract: Described and illustrated herein are one exemplary method and a measurement system having a meter and a test strip. The test strip has a first working electrode, reference electrode and second working electrode. In this method, acceptable fill data from known first current and known second current are used to predict an estimated second current at proximate the second time period (for a given batch of test strips) during the test sequence. The estimated second current at proximate the second time interval is then compared with a measured actual second current at proximate the second time interval during an actual test to determine if the measured actual second current is substantially equal to or within an acceptable percent deviation from the estimated second current so as to determine sufficient volume of a physiological fluid sample in the test strip.

Abstract: A multi-analyte test strip includes a first insulating layer and an electrically conductive layer disposed on the first insulating layer. The electrically conductive layer has a first working electrode with a first analyte contact pad, a shared counter/reference electrode with a counter/reference electrode contact pad, and a second working electrode with a second analyte contact pad. The multi-analyte test strip also includes a second insulating layer disposed above the first insulating layer and a patterned spacer layer positioned between the first insulating layer and the first electrically conductive layer with the patterned spacer layer defining a bodily fluid sample-receiving chamber that overlies the first working electrode, the shared counter/reference electrode and the second working electrode.