Abstract: A method for compensating an analyte measurement in the event of a low sample volume of a deposited fluid sample onto a test strip having first and second working electrodes and a reference electrode. At least one test voltage is applied between the first and second working electrodes and the reference electrode and current is measured at each of the working electrodes at a predetermined time point. The difference in measured current is compared to a stored threshold. If the difference in measured currents is within the stored threshold, the current measurements are used in determining an analyte of interest at a final test time. If the difference in measured currents is not within the stored threshold, then only the measured current of the first working electrode with a suitable correction applied is used in determining the analyte of interest at the final test time.

Abstract: A test strip port connector of a test meter receives an analytical test strip comprising a sample chamber for receiving a fluid sample. The fluid sample is prevented from contaminating an interior region of the test strip port connector by a sealing mechanism having a seal configured to be moved into a sealing position across the test strip.

Abstract: A test strip having conductive surfaces separated by a spacer layer, wherein the spacer layer is comprised of sections forming a plurality of sample chambers that enable the test strip to be inserted into a test meter in a number of possible orientations. The test strip also includes electrical contact pads on opposing sides thereof such that the test meter may separately engage the contact pads depending on the insertion orientation.

Abstract: An electrochemical-based analytical test strip for the determination of an analyte (such as glucose) in a bodily fluid sample includes an electrically insulating base layer, a first electrically conductive layer disposed on the electrically insulating base layer and including at least one electrode, an enzymatic reagent layer disposed on the at least one electrode, a patterned spacer layer and a top layer. The electrochemical-based analytical test strip also includes an ultra-thin discontinuous metal layer with a nominal thickness of less than 10 nanometers disposed between the first electrically conductive layer and the top layer. Moreover, at least the patterned spacer layer defines a sample-receiving chamber containing the at least one electrode, and the ultra-thin discontinuous metal layer is disposed at least within the sample-receiving chamber.

Abstract: An analytical test strip can include a patterned definition layer defining two fluidically-separated sample cells having respective ports, a common electrode arranged over the definition layer and in electrical communication with each of the cells, and respective cell electrodes. Surface portions of each electrode can be exposed. A method for testing a fluid sample using such a strip includes receiving a first fluid sample in the first sample cell and detecting a first electrical property thereof. It is then determined whether a second fluid sample should be added to the other sample cell. An analyte measurement system can include such a strip and test meter to receive the strip. The test meter can detect respective electrical properties of fluid samples in the cells.

Abstract: An analyte meter having a test strip port includes a detector proximate the port for detecting a test strip being inserted therein. A drive mechanism connected to the detector is configured to engage and pull a detected test strip into the test meter and into electrical and mechanical engagement therewith to enable analyte tests to be conducted.

Abstract: A test strip having conductive surfaces separated by a spacer layer, wherein the spacer layer is comprised of sections forming a plurality of sample chambers that enable the test strip to be inserted into a test meter in a number of possible orientations. The test strip also includes electrical contact pads on opposing sides thereof such that the test meter may separately engage the contact pads depending on the insertion orientation.

Abstract: A test strip port connector of a test meter receives an analytical test strip comprising a sample chamber for receiving a fluid sample. The fluid sample is prevented from contaminating an interior region of the test strip port connector by a sealing mechanism having a seal configured to be moved into a sealing position across the test strip.

Abstract: An analyte meter having a test strip port includes a camera which is configured to transmit digital images of a test strip in the test strip port for display to facilitate simultaneous application of a sample to the test strip.

Abstract: An analytical test strip can include a patterned definition layer defining two fluidically-separated sample cells having respective ports, a common electrode arranged over the definition layer and in electrical communication with each of the cells, and respective cell electrodes. Surface portions of each electrode can be exposed. A method for testing a fluid sample using such a strip includes receiving a first fluid sample in the first sample cell and detecting a first electrical property thereof. It is then determined whether a second fluid sample should be added to the other sample cell. An analyte measurement system can include such a strip and test meter to receive the strip. The test meter can detect respective electrical properties of fluid samples in the cells.

Abstract: A biosensor for use as an analytical test strip is formed as a main body having a first electrode facing in a first direction, a second electrode facing in a second direction, a pair of spacers disposed between the first and second electrodes, wherein the first electrode extends from the main body of the biosensor at a first angle and the second electrode extends from the main body at a second angle transverse to the first angle.

Abstract: A test meter for use with a dual-chamber, multi-analyte test strip includes a test strip receiving module and a signal processing module. The test strip receiving module has a first electrical connector configured for contacting a first analyte contact pad of a first working electrode of the test strip; a second electrical connector configured for contacting a second analyte contact pad of a second working electrode of the test strip, a third electrical connector configured for contacting a first counter/reference contact pad of a first counter/reference electrode layer of the test strip, and a fourth electrical connector configured for contacting a second counter/reference contact pad of a second counter/reference electrode layer of the test strip.

Abstract: A nicotinamide adenine dinucleotide (NAD) polymeric coenzyme for use in enzymatic electrochemical-based sensors includes NAD moieties covalently bound as pendent groups to a polymer backbone. An enzymatic electrochemical-based biosensor includes nicotinamide adenine dinucleotide (NAD) polymeric coenzyme, a polymeric electron transfer agent (e.g., polymeric ferrocene) at least one working electrode, and at least one reference electrode.

Abstract: A dual chamber, multi-analyte test strip has a first insulating layer, a first electrically conductive layer, with a first working electrode, disposed on the first insulating layer and a first patterned spacer layer positioned above the first electrically conductive layer. The first patterned spacer layer has a first sample-receiving chamber, with first and second end openings, defined therein that overlies the first working electrode. The test strip also includes a first counter/reference electrode layer that is exposed to the first sample receiving chamber and is in an opposing relationship to the first working electrode. The test strip further includes a counter/reference insulating layer disposed over the first counter/reference electrode layer and a second counter/reference electrode layer disposed on the counter/reference substrate. Also included in the test strip is a second patterned spacer layer that is positioned above the second counter/reference electrode layer.

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: A test meter for use with a dual-chamber, multi-analyte test strip includes a test strip receiving module and a signal processing module. The test strip receiving module has a first electrical connector configured for contacting a first analyte contact pad of a first working electrode of the test strip; a second electrical connector configured for contacting a second analyte contact pad of a second working electrode of the test strip, a third electrical connector configured for contacting a first counter/reference contact pad of a first counter/reference electrode layer of the test strip, and a fourth electrical connector configured for contacting a second counter/reference contact pad of a second counter/reference electrode layer of the test strip.

Abstract: A dual chamber, multi-analyte test strip has a first insulating layer, a first electrically conductive layer, with a first working electrode, disposed on the first insulating layer and a first patterned spacer layer positioned above the first electrically conductive layer. The first patterned spacer layer has a first sample-receiving chamber, with first and second end openings, defined therein that overlies the first working electrode. The test strip also includes a first counter/reference electrode layer that is exposed to the first sample receiving chamber and is in an opposing relationship to the first working electrode. The test strip further includes a counter/reference insulating layer disposed over the first counter/reference electrode layer and a second counter/reference electrode layer disposed on the counter/reference substrate. Also included in the test strip is a second patterned spacer layer that is positioned above the second counter/reference electrode layer.

Abstract: Immunoassay of methyl tert-butyl ether (MTBE) and related fuel oxygenates and their breakdown products is performed using a monoclonal antibody produced using a hapten with a CH3—O—C(CH3)2—CH2-moiety, preferably CH3—O—C(CH3)2—(CH2)3—CH(CH3)—CH2—CHO conjugated to a carrier protein.

Abstract: A backing sheet (101) is provided with a pattern of pathways (131,132,133) of (e.g.) silica or cellulose by a printing process (e.g., screen printing). There may be multiple pathways leading from an eluant application region (117) to a detection zone (116) and thence to a waste reservoir (118). Different pathways may have different fluid traversal times because they differ in length and/or material (e.g., nitrocellulose for slow traversal and fibrous cellulose for rapid traversal by an aqueous liquid). Thus analyte and reagents deposited at depots (112,113) on different pathways are sequentially delivered to the detection zone. Reagents may be applied by printing. The detection zone may have an electrode assembly (105), also applied by printing, for detecting the effects of analyte.