The present invention is related to a micro biosensor and sensing structure thereof. Particularly, the present invention is related to a micro biosensor and sensing structure thereof which can limit a diffusive distribution of a biofluid.
The basic configuration of the continuous glucose monitoring system includes a biosensor and a transmitter. The biosensor measures a physiological signal in response to a glucose concentration in the body, and the measurement thereof is mostly based on an electrochemical process. Specifically, glucose is subjected to a catalysis reaction with glucose oxidase (GOx) to produce gluconolactone and a reduced glucose oxidase, followed by an electron transfer reaction between the reduced glucose oxidase and oxygen in a biological fluid of the body to produce hydrogen peroxide (H2O2) as a byproduct. The glucose concentration is then derived from an oxidation reaction of the byproduct H2O2.
However, if interferants, such as ascorbic acid (a major component of vitamin C), acetaminophen (a common analgesic ingredient), uric acid, protein, glucose analogs, or the like, which oxidation potentials are proximate to the oxidation potential of H2O2, are present in the blood or the tissue fluid, the measurement of glucose concentration will be adversely affected. Therefore, it is difficult to ensure that the physiological parameters of a subject are truly reflected by the measurement values and to maintain a long-term stability of the measured signal when the continuous glucose monitoring system is in operation.
At present, the aforesaid shortcomings are solved, for example, by providing a polymer membrane to filter out the interferants. However, it remains difficult to filter out the interferants completely. Alternatively, a plurality of working electrodes optionally coated with an enzyme or different types of enzymes are respectively applied with potentials to read a plurality of signals from the working electrodes. The signals are then processed, such as subtraction, to accurately obtain the physiological parameter of the target analyte. However, such conventional processes involving the manufacturing and use of the working electrodes are very complicated. In addition, it is not easy to find out an appropriate ratio for the subtraction.
It is therefore the Applicant's attempt to deal with the above situations encountered in the prior art.
A micro biosensor of the present invention can be implanted under a skin to measure a physiological parameter of a target analyte of a biofluid, and includes a first working electrode for measuring the physiological parameter, a second working electrode for consuming interferants and an isolated layer. The isolated layer is configured to at least shield a part of the first working electrode to prevent the interferants in the biofluid from diffusing to the first working electrode directly, to ensure the biofluid passes through the second working electrode before reaching the first working electrode, so that the second working electrode consumes the interferants that affect the measurement in the biological fluid using an electrochemical reaction, and the first working electrode can obtain more accurate measurement results during measurement.
In accordance with another aspect of the present disclosure, a micro biosensor for implantation under a skin to measure a physiological parameter of a target analyte of a biofluid and reduce an interference of an interferant of the biofluid on the measurement by an electrochemical reaction is disclosed. The micro biosensor includes: a substrate being a sheet and having a first surface and a second surface which are oppositely configured; a first working electrode at least including a first sensing section configured on the first surface of the substrate, wherein the first sensing section of the first working electrode includes a first conductive material; at least one second working electrode configured on the first surface of the substrate, and including a second sensing section, wherein the second sensing section is configured adjacent to at least one side of the first sensing section, and the second sensing section of the second working electrode includes a second conductive material different from the first conductive material; a first functional membrane covering the first sensing section of the first working electrode and the second sensing section of the second working electrode, for regulating a diffusion amount of the biofluid to the first sensing section of the first working electrode and the second sensing section of the second working electrode, wherein the first functional membrane includes a chemical reagent at least covering a part of the first conductive material to define an active surface of the first sensing section, for reacting with the target analyte of the biofluid so as to obtain a resultant; and an isolated layer at least configured with respect to at least a part of the active surface of the first sensing section of the first working electrode to optimize a diffusive path of the interferant of the biofluid as one passing through the second sensing section of the second working electrode, wherein: the biofluid diffuses to the second sensing section over a time period, and then diffuses to the first sensing section after passing through the second sensing section; when the first working electrode is driven by a first working voltage, the first sensing section reacts with the resultant for outputting a physiological signal corresponding to the physiological parameter of the target analyte; and when the second working electrode is driven by a second working voltage, the second sensing section consumes the interferant of the biofluid by the electrochemical reaction during the time period, and a remaining part of the biofluid diffuses to the first sensing section of the first working electrode after passing through the second sensing section, for reducing the interference of the interferant to the physiological signal.
In accordance with one more aspect of the present disclosure, a micro biosensor for implantation under a skin to measure a physiological parameter of a target analyte of a biofluid and reduce an interference of an interferant of the biofluid on the measurement by an electrochemical reaction is disclosed. The micro biosensor includes: a substrate having a first surface and a second surface which are oppositely configured; a first working electrode at least including a first sensing section configured on the first surface of the substrate, for measuring the physiological parameter of the target analyte; at least one second working electrode configured on the first surface of the substrate, and including a second sensing section, wherein the second sensing section is configured adjacent to at least one side of the first sensing section for consuming the interferant by the electrochemical reaction; a first functional membrane covering the first sensing section of the first working electrode and the second sensing section of the second working electrode, for regulating a diffusion amount of the biofluid to the first sensing section of the first working electrode and the second sensing section of the second working electrode, wherein the first functional membrane includes a chemical reagent at least covering a part of the first sensing section to define an active surface, for reacting with the target analyte of the biofluid so as to obtain a resultant; and an isolated layer at least configured with respect to at least a part of the active surface to delineate a diffusive path of the interferant as one causing the biofluid to gain an increased opportunity to interact with the second sensing section of the second working electrode, wherein: when the first working electrode is driven by a first working voltage, the first sensing section reacts with the resultant for outputting a physiological signal corresponding to the physiological parameter of the target analyte; and when the second working electrode is driven by a second working voltage, the second sensing section consumes the interferant of the biofluid by the electrochemical reaction, and a remaining part of the biofluid diffuses to the first sensing section after passing through the second sensing section, for reducing the interference of the interferant to the physiological signal.
In accordance with one more aspect of the present disclosure, a sensing structure of a micro biosensor for implantation under a skin to measure a physiological parameter of a target analyte of a biofluid and reduce an interference of an interferant of the biofluid on the measurement by an electrochemical reaction is provided. The sensing structure includes: a substrate having a surface; a first working electrode configured on the surface of the substrate, and having an active surface; at least one second working electrode configured on the surface of the substrate and adjacent to at least one side of the first working electrode, for consuming the interferant by the electrochemical reaction; and an isolated layer at least configured with respect to at least a part of the active surface to program a diffusive distribution of the interferant when the biofluid flows through the second working electrode, wherein at least the interferant of the biofluid passes through the second working electrode over a time period and is consumed by the second working electrode by the electrochemical reaction.
Other objectives, advantages and efficacies of the present invention will be described in detail below taken from the preferred embodiments with reference to the accompanying drawings.
The present invention will now be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for purpose of illustration and description only; they are not intended to be exhaustive or to be limited to the precise form disclosed. In the preferred embodiments, the same reference numeral represents the same element in each embodiment.
The micro biosensor of the present invention can be a sensor of a continuous glucose monitoring system, which is implanted under a skin of a living body to continuously measure physiological parameters of a target analyte in a biofluid. In addition, the term “target analyte” mentioned herein generally refers to any substance to be tested that exists in the living body, such as but not limited to glucose, lactose, uric acid, etc. The term “biofluid” may be but not limited to blood or interstitial fluid (ISF), and the term “physiological parameter” may be but not limited to concentration.
Please refer to
The substrate 110 is a sheet, and has a first surface 111, a second surface 112 oppositely configured to the first surface 111, a first end 113 and a second end 114. Preferably, both the first surface 111 and the second surface 112 are flat planes for disposing the following electrodes. A signal output area 115, a sensing area 116 and an insulating area 117 are further defined on the substrate 110. The signal output area 115 is located at an area close to the first end 113, the sensing area 116 is located at an area close to the second end 114, and the insulating area 117 is covered by a first insulating layer I1 and located at an area between the signal output area 115 and the sensing area 116. The substrate 110 can be made of any material that can be used to manufacture electrode substrates and has flexibility and insulation, such as but not limited to, polyester, polyimide and other polymer materials. The polymer materials may be used alone or used as a mixture. The sensing structure of the present invention includes at least the first working electrode 120, the second working electrode 130, the first functional membrane 140 and the isolated layer 150 formed in the sensing area 116 and on the substrate 110.
The first working electrode 120 and the second working electrode 130 are configured on the first surface 111 of the substrate 110, and extended from the first end 113 to the second end 114, wherein a portion of the first working electrode 120 in the sensing area 116 is a first sensing section 121, and a portion of the second working electrode 120 in the sensing area 116 is a second sensing section 131. The first sensing section 121 at least has a first conductive material 1C, and the second sensing section 131 at least has a second conductive material 2C. The first conductive material 1C can be one of carbon, platinum, aluminum, gallium, gold, indium, iridium, iron, lead, magnesium, nickel, molybdenum, osmium, palladium, rhodium, silver, tin, titanium, zinc, silicon and zirconium, a derivative thereof (such as alloy, oxide or metal compound), or a combination thereof, and the second conductive material 2C can be the element or the derivative thereof exemplified for the first conductive material 1C.
It must be noted that, in the first embodiment, the first conductive material 1C is different from the second conductive material 2C. In order to obtain these structures, in the manufacturing process, the first conductive material 1C and the second conductive material 2C can be respectively formed on the first surface 111 of the substrate 110 at first and patterned into a pattern as shown in
However, the structures of the first working electrode 120 and the second working electrode 130 of the present invention are not limited to those shown in
The second sensing section 131 of the present invention is adjacent to at least one side of the first sensing section 121, and a side of the second sensing section 131 extends along the at least one side of the first sensing section 121. In this embodiment, the second sensing section 131 extends along three sides of the first sensing section 121 to form a U-shape sensing section. In addition, the first sensing section 121 and the second sensing section 131 of the present invention maintain a positional relationship therebetween only via the first surface 111. Because the first sensing section 121 and the second sensing section 131 of the present invention are directly adjacent to each other, there are no intermediates, such as electrodes or connecting wires therebetween.
The first functional membrane 140 at least covers the first sensing section 121 of the first working electrode 120 and the second sensing section 131 of the second working electrode 130 for regulating a diffusion amount of the biofluid to the first sensing section 121 of the first working electrode 120 and the second sensing section 131 of the second working electrode 130, and thereby a detection sensitivity is adjusted. Specifically, the first functional membrane 140 of the first embodiment surrounds the substrate 110, the first working electrode 120, the second working electrode 130 and the counter electrode 210. The first functional membrane 140 includes a chemical reagent at least covers a part of the first conductive material 1C of the first sensing section 121, so that a surface of the first sensing section 121 covered by the chemical reagent is defined as an active surface. In another embodiment, the chemical reagent can also cover the second conductive material 2C of the second sensing section 131 of the second working electrode 130, or even cover the second surface 112 of the substrate 110. That is to say, the chemical reagent can surround the sensing area 116. Basically, the chemical reagent includes at least one enzyme that reacts with the target analyte or catalyzes a reaction of the target analyte, such as, but not limited to, glucose oxidase, glucose dehydrogenase, etc.
The first working electrode 120 of the micro biosensor 10 of the present invention is driven for measuring the physiological parameter of the target analyte of the biofluid. When the first working electrode 120 of the micro biosensor 10 is driven by the first working voltage, the first sensing section 121 has a first sensitivity to the resultant, so that the first conductive material 1C reacts with the resultant to generate a current signal. When the value of the current signal has a proportional relationship with the concentration of the resultant, the physiological signal corresponding to the physiological parameter is obtained. Therefore, in a range of the active surface of the first sensing section 121, the chemical reagent reacts with the target analyte of the biofluid so as to obtain the resultant, followed by the resultant reacting with the first conductive material 1C of the first sensing section 121 to produce the current signal, which corresponds to the physiological signal of the physiological parameter of the target analyte in the biofluid, and the physiological signal is transmitted to the signal output area 115 to be output.
Because the biofluid includes the target analyte and the interferant, the first conductive material 1C not only reacts with the resultant to produce the above-mentioned current signal, but also reacts with the interferant in the biofluid to produce an interfering current signal. The interfering current signal will be mixed with the current signal and output to interfere in the user's determination on the physiological signal. Similarly, when the second working electrode 130 is driven by the second working voltage, the second conductive material 2C of the second sensing section 131 has a second sensitivity to the resultant, so that the second conductive material 2C has an opportunity to react with the resultant to generate another current signal. That is to say, the second conductive material 2C consumes the resultant that should be measured by the first sensing section 121 of the first working electrode 120 to obtain the physiological parameter of the target analyte, so that the actual measured physiological parameter is affected. Therefore, in an embodiment, when the target analyte is glucose, the resultant is hydrogen peroxide and the physiological parameter is the glucose concentration, the first conductive material 1C should preferably be a material having the first sensitivity to hydrogen peroxide after being driven by the first working voltage.
More preferably, the first conductive material 1C is selected from the group consisting of gold, platinum, palladium, iridium, and a combination thereof. The second conductive material 2C should preferably be a material having the second sensitivity to hydrogen peroxide that is less than the first sensitivity after being driven by the second working voltage. In particular, the second conductive material 2C is a material that almost has no sensitivity to hydrogen peroxide after being driven by the second working voltage, that is, the second sensitivity is close to 0 or equal to 0. In addition, the second sensing section 131 of the second working electrode 130 of the present invention provides an active surface for consuming the interferant. Therefore, the second conductive material 2C needs to be a material that almost has no sensitivity to hydrogen peroxide, but performs an oxidation reaction with the interferant to directly and continuously consume the interferant. In particular, the second conductive material 2C has a sensitivity to the interferant similar to the first conductive material 1C.
More specifically, in an embodiment of the present invention, the first conductive material 1C is platinum, the first working voltage ranges from 0.2 volts (V) to 0.8 volts (V) and preferably ranges from 0.4 V to 0.7 V, and the second conductive material 2C is carbon, the second working voltage ranges from 0.2 V to 0.8 V and preferably ranges from 0.4 V to 0.7 V. In another embodiment of the present invention, the first conductive material 1C is platinum, and the second conductive material 2C is gold. It must be noted that the form of the aforementioned platinum can be platinum metal, platinum black, platinum paste, other platinum-containing materials, or a combination thereof. In addition, the value of the first working voltage can be the same as that of the second working voltage, but the invention is not limited thereto.
It must be noted that the term “drive” in the present invention means applying a voltage causing a potential of one electrode to be higher than that of the other electrode, so that the electrode with the higher potential starts the oxidation reaction. Therefore, the potential difference between the first working electrode 120 and the counter electrode 210 causing the first working electrode 120 to be driven is the first working voltage, and the potential difference between the second working electrode 130 and the counter electrode 210 causing the second electrode 130 to be driven is the second working voltage.
Please refer to
However, in
Therefore, the micro biosensor 10 of the present invention includes the isolated layer 150, which is preferably configured on the first functional membrane 140. The position of the isolated layer 150 corresponds to at least a part of the first sensing section 121 of the first working electrode 120 to at least shield a part of the active surface, or even extends to at least shield a part of the second sensing section 131. Specifically, a configuration area of the isolated layer 150 may be 0.5-10 times the area of the active surface of the first sensing section 121, preferably 1-8 times, more preferably 2-6 times, and the most preferably 4-5 times.
In the first embodiment, the isolated layer 150 is configured to shield the top of the first sensing section 121 and the second sensing section 131, as shown in
As for the target analyte, whether the target analyte can be allowed to pass through the isolated layer 150 is determined depending on the material and/or the thickness of the isolated layer 150. Therefore, the diffusion path of the target analyte 310 can be (1) passing through the second sensing section 131 of the second working electrode 130 first, and then diffusing to the first sensing section 121 of the first working electrode 120, and/or (2) directly diffusing to the active surface of the first sensing section 121 of the first working electrode 120 from the isolated layer 150 depending on the condition of the isolated layer 150. Due to the different characteristics of the conductive materials, the interferant 320 will be directly consumed by the second sensing section 131, and since most of the target analyte 310 can pass through the second sensing section 131 or directly reach the first sensing section 121, the target analyte 310 can be sensed in the sensing range 1S of the first sensing section 121. Therefore, the isolated layer 150 of the micro biosensor 10 of the present invention can ensure the interferant 320 is consumed by the second sensing section 131 before reaching the first sensing section 121, thereby effectively reducing the interference of the interferant 320 on the physiological signal measured by the first sensing section 131 to be less than or equal to an error range, such as 20%, preferably 10%, to increase the accuracy of the biological signal. Specifically, more than 90% interferants can be effectively consumed via the sensing structure provided by the present invention.
In addition, the permeability of the isolated layer, such as the isolating object and the isolating degree, can be adjusted according to the choice of the material (such as the hydrophilicity or hydrophobicity of the material), the design of the thickness, or a combination thereof, to allow the substances such as glucose and oxygen to pass through the isolated layer and at least isolate the interferant, or completely isolate glucose, oxygen and the interferant from directly diffusing to the active surface of the first sensing section 121. For example, when the isolated layer with a high permeability is used, the thickness of the isolated layer with the high permeability should be larger than that of the isolated layer with a low permeability. In an embodiment, the isolated layer 150 can include poly-p-xylylene to stop the passage of glucose and the interferant. In another embodiment, the isolated layer 150 can include thermoplastic polyurethane, such as polycarbonate-based urethane, polycarbonate based silicone elastomer, polyether based thermoplastic polyurethane, or a combination thereof, to at least stop the passage of the interferant. In another embodiment, the isolated layer 150 also can include a cellulosic derivative or a mixture of cellulosic derivatives, polyvinyl chloride, Nafion, or a combination thereof. Specifically, the thickness of the isolated layer 150 can range from 1 μm to 80 μm depending on the material used, preferably 3 μm to 24 μm, and more preferably 5 μm to 10 μm. In the previous embodiment, when the isolated layer 150 includes poly-p-xylylene, the thickness thereof is 1 μm; and when the isolated layer 150 includes polycarbonate-based urethane, the thickness thereof ranges from 3 μm to 10 μm. In addition, the isolated layer 150 can be, but not limited to, manufactured on the first functional membrane 140 by a spraying process or a mask and screen printing. It should be additionally stated that the isolated layer of the present invention is not an insulation between the two electrodes on the substrate in the prior art or any insulation in the manufacturing process.
The first functional membrane 140 has a thickness H defined by a distance between the active surface of the first sensing section 121 and the active surface of the second sensing section 131 and the isolated layer 150, to have enough space to undergo the electrochemical reactions for the first sensing section 121 and the target analysis, and the second sensing section 131 and the interferant. The thickness H affects the sensitivity of the sensing. The thickness H is no less than 0.05 μm and no larger than 50 μm, preferably between 0.1 μm and 20 μm, more preferably between 2 μm and 8 μm, and the most preferably between 3 μm and 5 μm, to ensure and enhance the interference eliminating effect.
Please refer to
In another embodiment, the isolated layer 150 can be disposed to wrap the left side of the sensing structure as shown in
Please refer to
Please refer to
It can be seen that the length of the second sensing section 131 may be altered corresponding to the first sensing section 121. Therefore, in order to effectively reduce the influence of the interferant on the measurement, the aforementioned phrase “the second sensing section 131 is adjacent to at least one side of the first sensing section 121” specifically refers that a ratio of the portion of the periphery of the first sensing section 121 adjacent to the second sensing section 131 to a total of the periphery of the first sensing section ranges from 30% to 100%.
Furthermore, as mentioned above, in order for the interference eliminating range 2S of the second sensing section 131 to contact the surroundings of the first sensing section 121 and at least partially overlap the measurement range 1S of the first sensing section 121, a gap between the second sensing section 131 and the first sensing section 121 in the sensing area 116 of the micro biosensor 10 of the present invention in all preceding embodiments is no larger than 0.5 mm Preferably, the gap between the second sensing section 131 and the first sensing section 121 is no larger than 0.2 mm; more preferably, the gap ranges from 0.01 mm to 0.2 mm; still more preferably, the gap ranges from 0.01 mm to 0.1 mm; and further preferably, the gap ranges from 0.02 mm to 0.05 mm
In the preceding embodiments, the micro biosensor 10 of the present invention further includes a counter electrode 210 configured on the second surface 112 of the substrate 110, and extended from the first end 113 to the second end 114. The counter electrode 210 is coupled to at least one of the first working electrode 120 and the second working electrode 130, for measuring the physiological signal by cooperating with the first working electrode 120, and consuming the interferant by cooperating with the second working electrode 130. The counter electrode 210 can also function as a reference electrode based on the material it used. Specifically, the counter electrode 210 of the present invention can form an electronic circuit with the first working electrode 120 to freely flow the current on the first working electrode 120, to ensure that the counter electrode 210 can also provide a stable relative potential as a reference potential, while the electrochemical reaction occurs on the first working electrode 120. In another embodiment, the micro biosensor of the present invention can include two counter electrodes, and/or the counter electrode also can be configured on the first surface 111 of the substrate 110 (figure not shown). In a further embodiment, in addition to the counter electrode, the micro biosensor of the present invention also includes a reference electrode used for providing a reference potential. Specifically, the counter electrode and the reference electrode are separate and not electrically connected, and the counter electrode is coupled to the first working electrode 120 and/or the second working electrode 130. The counter electrode and the reference electrode can be both configured on the first surface 111 or the second surface 112 of the substrate 110 (figure not shown), or respectively configured on different surfaces of the substrate 110.
In the preceding embodiments, the first conductive material 1C of the first sensing section 121 can be the same as the second conductive material 2C of the second sensing section 131. In this embodiment, the chemical reagent is configured only to cover the first sensing section 121 of the first working electrode 120, or an interferant elimination layer can be additionally added on the second sensing section 131 of the second working electrode 130, followed by the chemical reagent is coated on the first sensing section 121 of the first working electrode 120 and the interferant elimination layer based on the convenience of the process, etc., which still meets the purpose of consuming the interferant through the second sensing section 131 to obtain the accurate physiological signals.
In the preceding embodiments, the micro biosensor 10 of the present invention further includes a second functional membrane 160 as shown in
In the preceding embodiments, the micro biosensor 10 of the present invention further includes a filler 170 as shown in
In the preceding embodiments, the sensing structure of the micro biosensor 10 of the present invention further can include the first working electrode 120, the second working electrode 130, the counter electrode 210, the first functional membrane 140, the isolated layer 150, the second functional membrane 160 and the filler 170 formed in the sensing area 116 of the substrate 110. In another embodiment, the sensing structure of the micro biosensor 10 of the present invention further can include the first working electrode 120, the second working electrode 130, the counter electrode 210, the reference electrode, the first functional membrane 140, the isolated layer 150, the second functional membrane 160 and the filler 170 formed in the sensing area 116 of the substrate 110.
To sum up, the isolated layer in the micro biosensor of the present invention can isolate at least part of the interferant to delineate or program the diffusive path of the interferant as one passing through the second working electrode first, to gain an increased opportunity of the interferant to interact with the second sensing section of the second working electrode to consume the interferant, so that the interference on the measurement of the first sensing section caused by the interferant is reduced, and thus the micro biosensor can measure more accurate physiological parameters.
Although the present invention has been described with reference to certain exemplary embodiments thereof, it can be understood by those skilled in the art that a variety of modifications and variations may be made to the present invention without departing from the spirit or scope of the present invention defined in the appended claims, and their equivalents.
This application is a Continuation-In-Part of U.S. patent application Ser. No. 16/944,328, filed on Jul. 31, 2020, which claims the benefit of U.S. Provisional Application No. 62/882,162, filed Aug. 2, 2019, and U.S. Provisional Application No. 62/988,549, filed Mar. 12, 2020; this application also claims the benefit of U.S. Provisional Application No. 63/224,736, filed on Jul. 22, 2021, in the United States Patent and Trademark Office, the disclosures of which are incorporated herein in their entirety by reference.
Number | Date | Country | |
---|---|---|---|
62882162 | Aug 2019 | US | |
62988549 | Mar 2020 | US | |
63224736 | Jul 2021 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16944328 | Jul 2020 | US |
Child | 17814340 | US |