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TWI652478B - Method of measuring hematocrit and method of testing blood - Google Patents

Method of measuring hematocrit and method of testing blood Download PDF

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TWI652478B
TWI652478B TW106135409A TW106135409A TWI652478B TW I652478 B TWI652478 B TW I652478B TW 106135409 A TW106135409 A TW 106135409A TW 106135409 A TW106135409 A TW 106135409A TW I652478 B TWI652478 B TW I652478B
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square wave
reaction zone
whole blood
blood sample
voltage
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TW106135409A
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Chinese (zh)
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TW201819902A (en
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陳筑瑄
顏鈺芳
董易庭
林芬菲
袁亦雲
謝文彬
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財團法人工業技術研究院
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Priority to EP17197685.5A priority Critical patent/EP3315964B1/en
Priority to US15/791,415 priority patent/US20180120258A1/en
Priority to CN201711019660.4A priority patent/CN108007830B/en
Publication of TW201819902A publication Critical patent/TW201819902A/en
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Publication of TWI652478B publication Critical patent/TWI652478B/en
Priority to US17/013,658 priority patent/US11714065B2/en

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Abstract

本發明提供血球容積比的量測方法與血液檢測方法。血球容積比的量測方法包括下列步驟。提供檢測試片。檢測試片包括反應區以及設置於反應區的一對電極。使全血樣品進入反應區。在全血樣品進入反應區之後,以方波伏安法對上述一對電極施加一組方波電壓,以得到與血球容積比相關的回饋值。全血樣品進入反應區的起始時間點與施加一組方波電壓的起始時間點相差0.1秒至200秒。依據回饋值推算出血球容積比。The invention provides a method for measuring the volume ratio of blood cells and a method for detecting blood. The method of measuring the hematocrit ratio includes the following steps. Provide test strips. The test strip includes a reaction zone and a pair of electrodes disposed in the reaction zone. The whole blood sample is allowed to enter the reaction zone. After the whole blood sample enters the reaction zone, a set of square wave voltages are applied to the pair of electrodes by square wave voltammetry to obtain a feedback value associated with the hematocrit ratio. The start time point at which the whole blood sample enters the reaction zone differs from the start time point at which a set of square wave voltages is applied by 0.1 second to 200 seconds. The blood cell volume ratio is calculated based on the feedback value.

Description

血球容積比的量測方法與血液檢測方法Blood volume ratio measurement method and blood detection method

本發明是有關於一種血球容積比的量測方法與一種血液檢測方法,且有關於對於全血樣品的一種血球容積比的量測方法與一種血液檢測方法。 The present invention relates to a blood cell volume ratio measuring method and a blood detecting method, and to a blood cell volume ratio measuring method and a blood detecting method for a whole blood sample.

血球容積比(hematocrit,Hct)主要是指加了抗凝血劑的全血經離心後沉澱的血細胞(主要為紅血球)在全血中佔有的比例。對於臨床實驗室檢測機台,都是使用血漿做為檢測的樣品。換言之,血液都先經過離心處理,得到的血漿再用以進行檢測。如此一來,血球容積比的差異對檢測結果就不至於造成干擾。 Hematocrit (Hct) mainly refers to the proportion of blood cells (mainly red blood cells) precipitated in whole blood after centrifugation of whole blood supplemented with anticoagulant. For clinical laboratory testing machines, plasma is used as a test sample. In other words, the blood is first centrifuged, and the obtained plasma is used for detection. As a result, the difference in blood cell volume ratio does not cause interference to the test results.

然而,對於醫護點檢測(point of care testing,POCT)或是病患可自行操作(over the counter,OTC)之檢測機台而言,為了減少檢驗所需的時間與成本,一般多是使用全血檢體進行直接的量測。也就是說,具有個體差異性的血球容積比會造成檢測的誤差。除此之外,檢測樣品保存的溫濕度或操作檢測機台時的溫濕度均會對血球容積比的檢測結果產生影響。 However, for point of care testing (POCT) or patient over-counter (OTC) testing machines, in order to reduce the time and cost required for testing, it is generally used The blood sample is directly measured. That is to say, the hematocrit ratio with individual differences can cause errors in detection. In addition, the temperature and humidity of the sample storage or the temperature and humidity when the machine is tested can affect the blood cell volume ratio detection result.

本發明實施例提供一種血球容積比的量測方法,包括下列步驟。提供檢測試片。檢測試片包括反應區以及設置於反應區的一對電極。使全血樣品進入反應區。在全血樣品進入反應區之後,以方波伏安法對一對電極施加一組方波電壓,以得到與血球容積比相關的回饋值。全血樣品進入反應區的起始時間點與施加一組方波電壓的起始時間點相差0.1秒至200秒。依據回饋值推算出血球容積比。 Embodiments of the present invention provide a method for measuring a blood cell volume ratio, including the following steps. Provide test strips. The test strip includes a reaction zone and a pair of electrodes disposed in the reaction zone. The whole blood sample is allowed to enter the reaction zone. After the whole blood sample enters the reaction zone, a square wave voltage is applied to the pair of electrodes by square wave voltammetry to obtain a feedback value associated with the hematocrit ratio. The start time point at which the whole blood sample enters the reaction zone differs from the start time point at which a set of square wave voltages is applied by 0.1 second to 200 seconds. The blood cell volume ratio is calculated based on the feedback value.

本發明實施例提供一種血液檢測方法,包括下列步驟。提供檢測試片。檢測試片包括第一反應區、設置於第一反應區的一對第一電極、第二反應區以及設置於第二反應區的一對第二電極。使全血樣品進入第一反應區與第二反應區。在全血樣品進入第一反應區之後,以方波伏安法對一對第一電極施加兩組方波電壓,以分別得到與血球容積比相關的第一回饋值與第二回饋值。對一對第二電極施加電壓,以得到第三回饋值而推算全血樣品中的目標分析物的濃度。判斷第一回饋值與第二回饋值的比值是否在預設範圍之間。若第一回饋值與第二回饋值的比值在預設範圍之間,則採用目標分析物的濃度,反之則提供檢測異常的訊息。 Embodiments of the present invention provide a blood detection method including the following steps. Provide test strips. The test strip includes a first reaction zone, a pair of first electrodes disposed in the first reaction zone, a second reaction zone, and a pair of second electrodes disposed in the second reaction zone. The whole blood sample is passed into the first reaction zone and the second reaction zone. After the whole blood sample enters the first reaction zone, two sets of square wave voltages are applied to the pair of first electrodes by square wave voltammetry to obtain a first feedback value and a second feedback value respectively associated with the hematocrit ratio. A voltage is applied to a pair of second electrodes to obtain a third feedback value to estimate the concentration of the target analyte in the whole blood sample. It is determined whether the ratio of the first feedback value to the second feedback value is between preset ranges. If the ratio of the first feedback value to the second feedback value is between the preset ranges, the concentration of the target analyte is used, and otherwise the message for detecting the abnormality is provided.

本發明實施例提供一種血球容積比的量測方法,包括下列步驟。提供檢測試片。檢測試片包括反應區以及設置於反應區的一對電極。使全血樣品進入反應區。以方波伏安法對一對電極連續施加多組方波電壓,以得到與血球容積比相關的多個回饋 值。相鄰兩組方波電壓的間隔為0.1秒至4秒。取得第n組方波電壓的回饋值,以推算出全血樣品的血球容積比。n為大於1的正整數。 Embodiments of the present invention provide a method for measuring a blood cell volume ratio, including the following steps. Provide test strips. The test strip includes a reaction zone and a pair of electrodes disposed in the reaction zone. The whole blood sample is allowed to enter the reaction zone. Applying multiple sets of square wave voltages to a pair of electrodes by square wave voltammetry to obtain multiple feedbacks related to the hematocrit ratio value. The interval between adjacent two groups of square wave voltages is from 0.1 second to 4 seconds. The feedback value of the nth group square wave voltage is obtained to calculate the hematocrit ratio of the whole blood sample. n is a positive integer greater than one.

本發明實施例提供一種血液檢測方法,包括下列步驟。提供檢測試片。檢測試片包括第一反應區、設置於第一反應區的一對第一電極、第二反應區以及設置於第二反應區的一對第二電極。使全血樣品進入第一反應區與第二反應區。以方波伏安法對一對第一電極連續施加多組方波電壓,以得到與血球容積比相關的多個回饋值。對一對第二電極施加電壓,以推算全血樣品中的目標分析物的濃度。判斷第1組以後的方波電壓的任意兩個回饋值的比值是否在預設範圍之間。若第1組以後的方波電壓的任意兩個回饋值的比值在預設範圍之間,則採用目標分析物的濃度,反之則提供檢測異常的訊息。 Embodiments of the present invention provide a blood detection method including the following steps. Provide test strips. The test strip includes a first reaction zone, a pair of first electrodes disposed in the first reaction zone, a second reaction zone, and a pair of second electrodes disposed in the second reaction zone. The whole blood sample is passed into the first reaction zone and the second reaction zone. A plurality of sets of square wave voltages are continuously applied to a pair of first electrodes by square wave voltammetry to obtain a plurality of feedback values related to the hematocrit ratio. A voltage is applied to a pair of second electrodes to estimate the concentration of the target analyte in the whole blood sample. It is judged whether the ratio of any two feedback values of the square wave voltage after the first group is between the preset ranges. If the ratio of any two feedback values of the square wave voltage after the first group is between the preset ranges, the concentration of the target analyte is used, and vice versa, a message for detecting the abnormality is provided.

為讓本發明的上述特徵和優點能更明顯易懂,下文特舉實施例,並配合所附圖式作詳細說明如下。 The above described features and advantages of the invention will be apparent from the following description.

200‧‧‧檢測試片 200‧‧‧Test strips

202‧‧‧第一反應區 202‧‧‧First reaction zone

204‧‧‧第一電極 204‧‧‧First electrode

204a‧‧‧第一工作電極 204a‧‧‧First working electrode

204b‧‧‧第一參考電極 204b‧‧‧First reference electrode

206‧‧‧第二反應區 206‧‧‧Second reaction zone

208‧‧‧第二電極 208‧‧‧second electrode

208a‧‧‧第二工作電極 208a‧‧‧second working electrode

208b‧‧‧第二參考電極 208b‧‧‧second reference electrode

A、B、C、D‧‧‧線 Lines A, B, C, D‧‧

Amp‧‧‧振幅 Amp‧‧‧ amplitude

E‧‧‧樣品注入處 E‧‧‧ sample injection

Efinal‧‧‧目標電壓 E final ‧‧‧target voltage

Eincr‧‧‧增幅電壓 E incr ‧‧‧Increased voltage

Einit‧‧‧初始電壓 E init ‧‧‧ initial voltage

F‧‧‧頻率 F‧‧‧frequency

S100、S100a、S102、S102a、S104、S104a、S106、S108、S110、S112、S114、S504、S504a、S506、S508、S510、S512、S514‧‧‧步驟 S100, S100a, S102, S102a, S104, S104a, S106, S108, S110, S112, S114, S504, S504a, S506, S508, S510, S512, S514‧‧

T0、T1、T2、T3、TS1‧‧‧起始時間點 T0, T1, T2, T3, TS1‧‧‧ starting point

V1、V2、VS‧‧‧方波電壓 V1, V2, VS‧‧‧ square wave voltage

V3、V3’‧‧‧電壓 V3, V3’‧‧‧ voltage

圖1A與圖1B分別是依照本發明一實施例的血球容積比的量測方法的流程圖與血液檢測方法的流程圖。 1A and FIG. 1B are respectively a flow chart of a method for measuring a blood volume ratio and a flow chart of a blood detecting method according to an embodiment of the present invention.

圖2是依照本發明一實施例的檢測試片的上視示意圖。 2 is a top plan view of a test strip in accordance with an embodiment of the present invention.

圖3是依照本發明一實施例的方波伏安法的電壓隨時間變化 的示意圖。 3 is a graph showing the voltage variation of a square wave voltammetry according to an embodiment of the invention. Schematic diagram.

圖4是依照圖1A與圖1B所示的實施例對全血樣品進行血球容積比與目標分析物濃度量測的順序的示意圖。 4 is a schematic illustration of the sequence of blood cell volume ratio and target analyte concentration measurements for whole blood samples in accordance with the embodiment illustrated in FIGS. 1A and 1B.

圖5A與圖5B分別是依照本發明另一實施例的血球容積比的量測方法的流程圖與血液檢測方法的流程圖。 5A and 5B are respectively a flow chart of a method for measuring a blood volume ratio and a flow chart of a blood detecting method according to another embodiment of the present invention.

圖6是依照圖5A與圖5B所示的實施例對全血樣品進行血球容積比與目標分析物濃度檢測的順序的示意圖。 Figure 6 is a schematic illustration of the sequence of blood cell volume ratio and target analyte concentration detection for a whole blood sample in accordance with the embodiment illustrated in Figures 5A and 5B.

圖7是依照本發明一實驗例在不同濕度下方波電壓的回饋值對血球容積比的作圖。 Figure 7 is a plot of the feedback value of the wave voltage versus the hematocrit ratio for different humidity levels in accordance with an experimental example of the present invention.

圖8是依照一比較例在不同濕度下方波電壓的回饋值對血球容積比的作圖。 Figure 8 is a plot of the feedback value of the wave voltage versus the hematocrit ratio for different humidity levels in accordance with a comparative example.

圖1A與圖1B分別是依照本發明一實施例的血球容積比的量測方法的流程圖與血液檢測方法的流程圖。圖2是依照本發明一實施例的檢測試片的上視示意圖。圖3是依照本發明一實施例的方波伏安法的電壓隨時間變化的示意圖。圖4是依照圖1A與圖1B所示的實施例對全血樣品進行血球容積比與目標分析物濃度檢測的順序的示意圖。 1A and FIG. 1B are respectively a flow chart of a method for measuring a blood volume ratio and a flow chart of a blood detecting method according to an embodiment of the present invention. 2 is a top plan view of a test strip in accordance with an embodiment of the present invention. 3 is a graph showing voltage versus time for square wave voltammetry in accordance with an embodiment of the present invention. 4 is a schematic illustration of the sequence of blood cell volume ratio and target analyte concentration detection for a whole blood sample in accordance with the embodiment illustrated in FIGS. 1A and 1B.

請參照圖1A與圖2,本發明一實施例的血球容積比(hematocrit,Hct)的量測方法包括下列步驟。 Referring to FIG. 1A and FIG. 2, a method for measuring a hematocrit (Hct) ratio according to an embodiment of the present invention includes the following steps.

進行步驟S100,提供檢測試片200。檢測試片200包括 第一反應區202以及設置於第一反應區202的一對第一電極204。在一些實施例中,一對第一電極204包括第一工作電極204a與第一參考電極204b。第一反應區202可位於第一工作電極204a與第一參考電極204b上,且暴露一部分的第一工作電極204a與第一參考電極204b。在一些實施例中,檢測試片200更包括第二反應區206以及設置於第二反應區206的一對第二電極208。一對第二電極208可包括第二工作電極208a與第二參考電極208b。第二反應區206可位於第二工作電極208a與第二參考電極208b上,且暴露一部分的第二工作電極208a與第二參考電極208b。 Step S100 is performed to provide the test strip 200. The test strip 200 includes The first reaction zone 202 and a pair of first electrodes 204 disposed in the first reaction zone 202. In some embodiments, a pair of first electrodes 204 includes a first working electrode 204a and a first reference electrode 204b. The first reaction region 202 may be located on the first working electrode 204a and the first reference electrode 204b, and expose a portion of the first working electrode 204a and the first reference electrode 204b. In some embodiments, the test strip 200 further includes a second reaction zone 206 and a pair of second electrodes 208 disposed in the second reaction zone 206. The pair of second electrodes 208 may include a second working electrode 208a and a second reference electrode 208b. The second reaction region 206 may be located on the second working electrode 208a and the second reference electrode 208b, and expose a portion of the second working electrode 208a and the second reference electrode 208b.

在全血樣品進入檢測試片200並通過第一反應區202(或第一反應區202與第二反應區206)後,第一電極204(或第一電極204與第二電極208)可接收電壓而使全血樣品在第一反應區202(或第一反應區202與第二反應區206)中進行反應。在一些實施例中,第一參考電極204b可與第二參考電極208b電性連接,或一對第一電極204與一對第二電極208可共用相同的參考電極。在一些實施例中,第二參考電極208b(或可與第一參考電極204b共用的參考電極)可偵測全血樣品進入檢測試片200的量。據此,可待全血樣品的量足夠後再施加電壓於第一工作電極204a與第二工作電極208a,而使全血樣品在第一反應區202與第二反應區206中開始反應。 After the whole blood sample enters the test strip 200 and passes through the first reaction zone 202 (or the first reaction zone 202 and the second reaction zone 206), the first electrode 204 (or the first electrode 204 and the second electrode 208) can receive The whole blood sample is reacted in the first reaction zone 202 (or the first reaction zone 202 and the second reaction zone 206) with a voltage. In some embodiments, the first reference electrode 204b can be electrically connected to the second reference electrode 208b, or the pair of first electrodes 204 and the pair of second electrodes 208 can share the same reference electrode. In some embodiments, the second reference electrode 208b (or a reference electrode that can be shared with the first reference electrode 204b) can detect the amount of whole blood sample entering the test strip 200. Accordingly, the amount of the whole blood sample is sufficient to apply a voltage to the first working electrode 204a and the second working electrode 208a, and the whole blood sample starts to react in the first reaction zone 202 and the second reaction zone 206.

在一些實施例中,第一反應區202可較第二反應區206更接近檢測試片200的樣品注入處E。此外,第一反應區202與 第二反應區206可經設置於相同的通道中。然而,在其他實施例中,第二反應區206也可比第一反應區202更接近樣品注入處E。此外,第一反應區202與第二反應區206更可左右設置或不同平面地設置。再者,第一反應區202與第二反應區206可經設置於不同的通道中。所屬領域中具有通常知識者可依設計需求調整第一反應區202與第二反應區206的相對位置關係,本發明並不以此為限。 In some embodiments, the first reaction zone 202 can be closer to the sample injection site E of the test strip 200 than the second reaction zone 206. In addition, the first reaction zone 202 and The second reaction zone 206 can be disposed in the same channel. However, in other embodiments, the second reaction zone 206 can also be closer to the sample injection site E than the first reaction zone 202. In addition, the first reaction zone 202 and the second reaction zone 206 may be disposed on the left and right sides or in different planes. Furthermore, the first reaction zone 202 and the second reaction zone 206 can be disposed in different channels. The relative positional relationship between the first reaction zone 202 and the second reaction zone 206 can be adjusted according to the design requirements, and the invention is not limited thereto.

在一些實施例中,第一工作電極204a與第一參考電極204b的間距範圍為0.01mm至5mm。舉例而言,第一工作電極204a與第一參考電極204b的間距範圍可為0.01mm至1mm,或0.05mm至5mm。此外,第一工作電極204a的面積對於第一參考電極204b的面積的比值範圍為1至1.5。舉例而言,第一工作電極204a的面積對於第一參考電極204b的面積的比值範圍可為1至1.2。藉由控制第一工作電極204a與第一參考電極204b的間距以及面積比例於上述的範圍內,可使對第一工作電極204a施加電壓時,可得到穩定的回饋值。 In some embodiments, the distance between the first working electrode 204a and the first reference electrode 204b ranges from 0.01 mm to 5 mm. For example, the distance between the first working electrode 204a and the first reference electrode 204b may range from 0.01 mm to 1 mm, or from 0.05 mm to 5 mm. Further, the ratio of the area of the first working electrode 204a to the area of the first reference electrode 204b ranges from 1 to 1.5. For example, the ratio of the area of the first working electrode 204a to the area of the first reference electrode 204b may range from 1 to 1.2. By controlling the pitch and area ratio of the first working electrode 204a and the first reference electrode 204b within the above range, a stable feedback value can be obtained when a voltage is applied to the first working electrode 204a.

在一些實施例中,反應試劑可設置於第二反應區206上。反應試劑的材料可包括反應酵素,且更可包括電子媒介物。在其他實施例中,反應試劑亦可進一步延伸至第一反應區202上。 In some embodiments, the reagents can be disposed on the second reaction zone 206. The material of the reaction reagent may include a reaction enzyme, and may further include an electron vehicle. In other embodiments, the reagents may further extend to the first reaction zone 202.

進行步驟S102,使全血樣品進入第一反應區202。具體而言,全血樣品可透過毛細力或微流道設計由檢測試片200的樣品注入處E進入。此外,全血樣品除了進入第一反應區202之外, 更可進入至第二反應區206。 Step S102 is performed to allow the whole blood sample to enter the first reaction zone 202. Specifically, the whole blood sample can be entered from the sample injection site E of the test strip 200 by capillary force or microchannel design. In addition, the whole blood sample enters the first reaction zone 202, More access to the second reaction zone 206 is possible.

請參照圖1A以及圖2至圖4,隨後進行步驟S104,以方波伏安法(square wave voltammetry,SWV)對一對第一電極204施加一組方波電壓V1,以得到有關於血球容積比的第一回饋值。如此一來,第一工作電極204a可接收方波電壓V1而使全血樣品在第一反應區202中進行電性反應,以得到第一回饋值。特別來說,第一回饋值為一電流值。如圖3所示,方波電壓V1可為正電壓,其初始電壓Einit隨時間以一增幅電壓Eincr逐漸往目標電壓Efinal遞增。具體而言,方波電壓V1以初始電壓Einit為中心,經由固定頻率F施加一固定電壓振幅Amp之正負電壓振盪。接著,增加一固定增幅電壓Eincr,且以新的電壓值(Einit+Eincr)為中心作固定電壓振幅之振盪,直到電壓值中心達到目標電壓EfinalReferring to FIG. 1A and FIG. 2 to FIG. 4, step S104 is followed to apply a set of square wave voltage V1 to a pair of first electrodes 204 by square wave voltammetry (SWV) to obtain a blood cell volume. The first feedback value. In this way, the first working electrode 204a can receive the square wave voltage V1 to electrically react the whole blood sample in the first reaction zone 202 to obtain a first feedback value. In particular, the first feedback value is a current value. As shown in FIG. 3, the square wave voltage V1 can be a positive voltage, and its initial voltage E init gradually increases toward the target voltage E final with an increasing voltage E incr over time. Specifically, the square wave voltage V1 is centered on the initial voltage E init , and a positive and negative voltage oscillation of a fixed voltage amplitude Amp is applied via the fixed frequency F. Next, a fixed amplification voltage E incr is added , and the oscillation of the fixed voltage amplitude is centered on the new voltage value (E init + E incr ) until the center of the voltage value reaches the target voltage E final .

在給予適當的振幅Amp、頻率F及增幅電壓Eincr等參數的情況下,可以穩定地量測到全血樣品所產生的關於血球容積比的第一回饋值。在一些實施例中,方波電壓V1可具有固定的振幅Amp、頻率F及增幅電壓Eincr。舉例而言,頻率F可大於100Hz,例如可在100Hz至4000Hz的範圍中。振幅Amp可大於或等於0.01V,例如可在0.01V至0.4V的範圍中。增幅電壓Eincr可在0.01V至0.4V的範圍中,例如是在0.05V至0.2V的範圍中。除此之外,方波電壓V1的掃描範圍可在0V至0.8V之間。再者,電壓施加的時間範圍可在0.01秒至4秒的範圍中,例如是在0.01秒至2秒的範圍中。 In the case of giving parameters such as an appropriate amplitude Amp, frequency F, and amplification voltage E incr , the first feedback value about the hematocrit ratio produced by the whole blood sample can be stably measured. In some embodiments, the square wave voltage V1 can have a fixed amplitude Amp, a frequency F, and an amplification voltage E incr . For example, the frequency F can be greater than 100 Hz, for example in the range of 100 Hz to 4000 Hz. The amplitude Amp may be greater than or equal to 0.01 V, for example, in the range of 0.01 V to 0.4 V. The amplification voltage E incr may be in the range of 0.01 V to 0.4 V, for example, in the range of 0.05 V to 0.2 V. In addition to this, the scanning range of the square wave voltage V1 can be between 0V and 0.8V. Further, the time period during which the voltage is applied may be in the range of 0.01 second to 4 seconds, for example, in the range of 0.01 second to 2 seconds.

然而,所屬領域中具有通常知識者可依據第一電極204的材料、圖形、位置等條件的改變而調整上述的參數。舉例而言,當第一電極204的材料為碳墨(例如是網版印刷碳電極時(screen printed carbon electrode,SPCE))時,方波電壓V1的頻率F範圍可為100Hz至500Hz,且振幅Amp範圍可為0.01V至0.4V。此外,方波電壓V1的電壓掃描範圍可為0V至0.5V,且方波電壓V1的施加時間範圍可為0.01秒至2秒。作為另一個實例,當第一電極204的材料為金時,方波電壓V1的頻率F範圍可為500Hz至4000Hz,且振幅Amp範圍可為0.1V至0.4V。此外,方波電壓V1的電壓掃描範圍可為0V至0.5V,且方波電壓V1的施加時間範圍可為0.01秒至2秒。 However, those having ordinary skill in the art can adjust the above parameters according to changes in the materials, patterns, positions, and the like of the first electrode 204. For example, when the material of the first electrode 204 is a carbon ink (for example, a screen printed carbon electrode (SPCE)), the frequency F of the square wave voltage V1 may range from 100 Hz to 500 Hz, and the amplitude The Amp range can be from 0.01V to 0.4V. Further, the voltage sweep range of the square wave voltage V1 may be 0V to 0.5V, and the application time of the square wave voltage V1 may be 0.01 second to 2 seconds. As another example, when the material of the first electrode 204 is gold, the frequency F of the square wave voltage V1 may range from 500 Hz to 4000 Hz, and the amplitude Amp may range from 0.1 V to 0.4 V. Further, the voltage sweep range of the square wave voltage V1 may be 0V to 0.5V, and the application time of the square wave voltage V1 may be 0.01 second to 2 seconds.

請參照圖3與圖4,全血樣品進入檢測試片200的第一反應區202的起始時間T0與施加一組方波電壓V1於第一電極204的起始時間T1之間的間隔為0.1秒至200秒。在一些實施例中,起始時間T0與起始時間T1之間的間隔亦可為0.1秒至120秒、0.1秒至60秒、0.1秒至30秒、0.1秒至10秒、0.1秒至5秒、0.1秒至1秒、1秒至200秒、3秒至200秒或、5秒至200秒、10秒至200秒、20秒至200秒、50秒至200秒、1秒至120秒、3秒至60秒、5秒至30秒或5秒至10秒。 Referring to FIG. 3 and FIG. 4, the interval between the start time T0 of the whole blood sample entering the first reaction zone 202 of the test strip 200 and the start time T1 of applying a set of square wave voltage V1 to the first electrode 204 is 0.1 seconds to 200 seconds. In some embodiments, the interval between the start time T0 and the start time T1 may also be 0.1 second to 120 seconds, 0.1 second to 60 seconds, 0.1 second to 30 seconds, 0.1 second to 10 seconds, and 0.1 second to 5 seconds. Seconds, 0.1 second to 1 second, 1 second to 200 seconds, 3 seconds to 200 seconds or 5 seconds to 200 seconds, 10 seconds to 200 seconds, 20 seconds to 200 seconds, 50 seconds to 200 seconds, 1 second to 120 seconds , 3 seconds to 60 seconds, 5 seconds to 30 seconds, or 5 seconds to 10 seconds.

進行步驟S106,依據第一回饋值推算出血球容積比。經實驗發現,第一回饋值(電流值)與血球容積比呈負相關的關係。統計對於不同已知血球容積比的全血樣品的第一回饋值,可將上 述的負相關的關係歸納為一關係式。此關係式可包括多項式或線性關係式。隨後,將對於一具有未知血球容積比的全血樣品的第一回饋值代入此關係式即可得到對應的血球容積比。 Step S106 is performed to calculate a blood cell volume ratio based on the first feedback value. It has been found through experimentation that the first feedback value (current value) has a negative correlation with the hematocrit ratio. Counting the first feedback value for a whole blood sample with different known hematocrit ratios, The negative correlations described are summarized as a relationship. This relationship can include polynomial or linear relationships. Subsequently, a first hedging value for a whole blood sample having an unknown hematocrit ratio is substituted into the relationship to obtain a corresponding hematocrit ratio.

值得注意的是,當檢測試片200暴露於大氣時,易於第一電極204上(或第一電極204與第二電極208上)形成水膜。此外,當全血樣品進入檢測試片200的第一反應區202(或進入第一反應區202與第二反應區206)時,易於全血樣品與第一電極204之間(及全血樣品與第二電極208之間)產生微氣泡。此水膜及微氣泡會使血球容積比的量測結果產生誤差。本實施例藉由全血樣品在第一反應區202停留一間隔時間後對第一電極204以方波伏安法施加一組方波電壓V1,可破壞全血樣品與第一電極204之間(及全血樣品與第二電極208之間)的水膜及微氣泡。如此一來,可避免環境中的濕氣及微氣泡對血球容積比的量測結果造成的影響。此外,本發明採用方波伏安法進行血球容積比的量測時,較不易受到目標分析物(例如是血糖)濃度的影響。因此,本發明方法可有效降低濕度、微氣泡及目標分析物濃度對於血球容積比量測產生誤差的影響。 It is to be noted that when the test strip 200 is exposed to the atmosphere, it is easy to form a water film on the first electrode 204 (or on the first electrode 204 and the second electrode 208). In addition, when the whole blood sample enters the first reaction zone 202 of the test strip 200 (or enters the first reaction zone 202 and the second reaction zone 206), it is easy to be between the whole blood sample and the first electrode 204 (and the whole blood sample) Microbubbles are generated between the second electrode 208 and the second electrode 208. This water film and microbubbles can cause errors in the measurement of the hematocrit ratio. In this embodiment, by applying a set of square wave voltage V1 to the first electrode 204 by the square wave voltammetry after the whole blood sample stays in the first reaction zone 202 for an interval, the whole blood sample and the first electrode 204 can be destroyed. Water film and microbubbles (and between the whole blood sample and the second electrode 208). In this way, the influence of moisture and microbubbles in the environment on the measurement of the hematocrit ratio can be avoided. In addition, when the present invention uses the square wave voltammetry to measure the hematocrit ratio, it is less susceptible to the concentration of the target analyte (for example, blood glucose). Therefore, the method of the present invention can effectively reduce the influence of humidity, microbubbles and target analyte concentration on the error of blood cell volume ratio measurement.

請參照圖1B以及圖2至圖4,本實施例的血液檢測的方法包括下列步驟。本實施例的血液檢測方法包括部分的圖1A所示的血球容積比的量測方法,其中相同或相似處則不再贅述。除此之外,相似的步驟以相似的元件符號標示。 Referring to FIG. 1B and FIG. 2 to FIG. 4, the blood detecting method of the present embodiment includes the following steps. The blood detecting method of the present embodiment includes a partial measuring method of the hematocrit ratio shown in FIG. 1A, and the same or similar portions will not be described again. In addition, similar steps are denoted by like reference numerals.

進行步驟S100a,提供檢測試片200。如圖2所示,檢測 試片200包括第一反應區202、設置於第一反應區202的一對第一電極204、第二反應區206以及設置於第二反應區206的一對第二電極208。 Step S100a is performed to provide the test strip 200. As shown in Figure 2, detection The test strip 200 includes a first reaction zone 202, a pair of first electrodes 204 disposed in the first reaction zone 202, a second reaction zone 206, and a pair of second electrodes 208 disposed in the second reaction zone 206.

進行步驟S102a,使全血樣品進入第一反應區202與第二反應區206。接著,進行步驟S104a,以方波伏安法對第一電極204施加一組方波電壓V1與一組方波電壓V2,以分別得到與血球容積比相關的第一回饋值與第二回饋值。具體而言,第一工作電極204a可分別接受方波電壓V1與方波電壓V2,而使全血樣品在第一反應區202中進行電性反應,以得到有關於血球容積比的第一回饋值與第二回饋值。此外,方波電壓V2相似於方波電壓V1,兩者之間的差異僅為施加的時間點不同。特別來說,施加方波電壓V1的起始時間T1早於施加方波電壓V2的起始時間T2。在一些實施例中,方波電壓V1的起始時間T1與方波電壓V2的起始時間T2之間的間隔可為0.1秒至200秒。在另一些實施例中,方波電壓V1的起始時間T1與方波電壓V2的起始時間T2之間的間隔可為0.1秒至3秒。 Step S102a is performed to allow the whole blood sample to enter the first reaction zone 202 and the second reaction zone 206. Next, in step S104a, a square wave voltage V1 and a set of square wave voltage V2 are applied to the first electrode 204 by square wave voltammetry to obtain a first feedback value and a second feedback value respectively related to the hematocrit ratio. . Specifically, the first working electrode 204a can receive the square wave voltage V1 and the square wave voltage V2, respectively, and the whole blood sample is electrically reacted in the first reaction zone 202 to obtain a first feedback about the blood cell volume ratio. The value and the second feedback value. Further, the square wave voltage V2 is similar to the square wave voltage V1, and the difference between the two is only different at the time point of application. In particular, the start time T1 at which the square wave voltage V1 is applied is earlier than the start time T2 at which the square wave voltage V2 is applied. In some embodiments, the interval between the start time T1 of the square wave voltage V1 and the start time T2 of the square wave voltage V2 may be 0.1 second to 200 seconds. In other embodiments, the interval between the start time T1 of the square wave voltage V1 and the start time T2 of the square wave voltage V2 may be 0.1 second to 3 seconds.

進行步驟S108,對第二電極208施加電壓V3,以得到第三回饋值而推算全血樣品中的目標分析物的濃度。在一些實施例中,可在方波電壓V1施加完後或施加前對第二電極208施加電壓V3。在其他實施例中,也可在方波電壓V1施加完過一段時間後或立即對第二電極208施加電壓V3。在另一實施例中,也可在方波電壓V2施加後,再對第二電極208施加電壓V3。特別留意的 是,施加電壓V3可獨立於任一時間下進行,本發明並不以此為限。對第二電極208施加電壓V3的方法可包括安培法(amperometry)、庫倫法(coulometry)、電位法(potentiometry)、伏安法(voltammetry)、電阻抗法(impedance)或其組合,本發明並不以此為限。在一些實施例中,目標分析物包括血糖、糖化血色素(HbA1c)、血乳酸、膽固醇、尿酸、三酸甘油酯、凝血因子或抗凝因子。 Step S108 is performed to apply a voltage V3 to the second electrode 208 to obtain a third feedback value to estimate the concentration of the target analyte in the whole blood sample. In some embodiments, the voltage V3 can be applied to the second electrode 208 after application of the square wave voltage V1 or prior to application. In other embodiments, the voltage V3 may also be applied to the second electrode 208 after a period of application of the square wave voltage V1 or immediately. In another embodiment, the voltage V3 may be applied to the second electrode 208 after the square wave voltage V2 is applied. Special attention Yes, the applied voltage V3 can be performed independently of any time, and the invention is not limited thereto. The method of applying the voltage V3 to the second electrode 208 may include amperometry, coulometry, potentiometry, voltammetry, impedance, or a combination thereof, and the present invention Not limited to this. In some embodiments, the analyte of interest comprises blood glucose, glycated hemoglobin (HbA1c), blood lactate, cholesterol, uric acid, triglycerides, coagulation factors, or anticoagulants.

以第三回饋值推算全血樣品中的目標方析物的濃度的方法包括先依據第一回饋值及第二回饋值中的至少一者推算出全血樣品中的血球容積比(如圖1A的步驟S106)。在一些實施例中,可選擇第一回饋值、第二回饋值或兩者平均值來推算出全血樣品中的血球容積比。接著,根據計算出的血球容積比與第三回饋值計算出目標分析物的濃度。對不同血球容積比的全血樣品進行檢測,可歸納出目標分析物的濃度對於第三回饋值具有不同的線性關係式。上述的線性關係式之間的斜率關係與常數項關係可依據計算出的血球容積比進行校正,而可得到目標分析物的濃度對於第三回饋值的一通式。據此,可將第三回饋值代入此通式而得到目標分析物的濃度。 The method for estimating the concentration of the target analyte in the whole blood sample by using the third feedback value comprises first deriving the blood volume ratio in the whole blood sample according to at least one of the first feedback value and the second feedback value (FIG. 1A) Step S106). In some embodiments, the first feedback value, the second feedback value, or both averages may be selected to derive a hematocrit ratio in the whole blood sample. Next, the concentration of the target analyte is calculated based on the calculated hematocrit ratio and the third feedback value. The detection of whole blood samples with different hematocrit ratios can be concluded that the concentration of the target analyte has a different linear relationship for the third feedback value. The relationship between the slope relationship and the constant term relationship between the linear relationships described above can be corrected according to the calculated hematocrit ratio, and a general formula of the concentration of the target analyte for the third feedback value can be obtained. Accordingly, the third feedback value can be substituted into the general formula to obtain the concentration of the target analyte.

接著,進行步驟S110,判斷第一回饋值與第二回饋值的比值是否在預設範圍之間。在一些實施例中,預設範圍可為0.85至1.18。若第一回饋值與第二回饋值的比值在預設範圍之間,則進行步驟S112,採用目標分析物的推算出的濃度。反之,若第一 回饋值與第二回饋值的比值小於或大於預設範圍,則進行步驟S114,提供檢測異常的訊息。換言之,若第一回饋值與第二回饋值的比值在預設範圍之間才採用目標分析物的推算出的濃度,反之則不採用。如此一來,可排除外在因素對檢測目標分析物濃度的干擾,降低誤判風險。一般而言,上述的外在因素可包括環境中的溫濕度的變化,或檢測試片200中的製作缺陷。 Next, proceeding to step S110, determining whether the ratio of the first feedback value to the second feedback value is between the preset ranges. In some embodiments, the preset range can be from 0.85 to 1.18. If the ratio of the first feedback value to the second feedback value is between the preset ranges, then step S112 is performed to use the calculated concentration of the target analyte. On the contrary, if the first If the ratio of the feedback value to the second feedback value is less than or greater than the preset range, then step S114 is performed to provide a message for detecting an abnormality. In other words, if the ratio of the first feedback value to the second feedback value is between the preset ranges, the calculated concentration of the target analyte is used, and vice versa. In this way, the interference of external factors on the concentration of the analyte of the detection target can be eliminated, and the risk of misjudgment can be reduced. In general, the external factors described above may include changes in temperature and humidity in the environment, or detection defects in the test strip 200.

基於上述,本實施例的血球容積比的量測方法利用全血樣品在第一反應區202停留一間隔時間後以方波伏安法對第一電極204施加方波電壓V1。如此一來,可破壞全血樣品與第一電極204之間(及全血樣品與第二電極208之間)的水膜及微氣泡。因此,可避免環境中的濕氣及微氣泡對量測血球容積比的結果造成影響,同時方波伏安法也不易受目標分析物濃度影響,故可得到較精確的血球容積比。另一方面,本實施例的血液檢測方法包括由上述得到的血球容積比以及對第二電極208施加電壓V3得到的第三回饋值推算出全血樣品中目標分析物的濃度。此外,藉由判斷第一回饋值和第二回饋值的比值是否落於特定範圍內而決定是否採用由此第三回饋值推算出的目標分析物的濃度,可排除外在因素對檢測目標分析物的濃度造成的干擾。 Based on the above, the blood cell volume ratio measuring method of the present embodiment applies the square wave voltage V1 to the first electrode 204 by square wave voltammetry after the whole blood sample stays in the first reaction zone 202 for an interval. In this way, the water film and microbubbles between the whole blood sample and the first electrode 204 (and between the whole blood sample and the second electrode 208) can be destroyed. Therefore, it is possible to avoid the influence of moisture and microbubbles in the environment on the measurement of the hematocrit ratio, and the square wave voltammetry is also less susceptible to the target analyte concentration, so that a more accurate hematocrit ratio can be obtained. On the other hand, the blood detecting method of the present embodiment includes estimating the concentration of the target analyte in the whole blood sample from the blood cell volume ratio obtained above and the third feedback value obtained by applying the voltage V3 to the second electrode 208. In addition, by determining whether the ratio of the first feedback value and the second feedback value falls within a specific range, determining whether to use the concentration of the target analyte calculated by the third feedback value, the external factor can be excluded from analyzing the detection target. Interference caused by the concentration of matter.

圖5A與圖5B分別是依照本發明另一實施例的血球容積比的量測方法的流程圖與血液檢測方法的流程圖。圖6是依照圖5A與圖5B所示的實施例對全血樣品進行血球容積比與目標分析物濃度檢測的順序的示意圖。 5A and 5B are respectively a flow chart of a method for measuring a blood volume ratio and a flow chart of a blood detecting method according to another embodiment of the present invention. Figure 6 is a schematic illustration of the sequence of blood cell volume ratio and target analyte concentration detection for a whole blood sample in accordance with the embodiment illustrated in Figures 5A and 5B.

請參照圖5A與圖6,本發明另一實施例的血球容積比的量測方法相似於圖1A所示的血球容積比的量測方法。以下僅針對兩者的差異處進行說明,相同或相似處則不再贅述。 Referring to FIG. 5A and FIG. 6, the blood cell volume ratio measuring method according to another embodiment of the present invention is similar to the blood cell volume ratio measuring method shown in FIG. 1A. The following only describes the differences between the two, and the same or similar parts will not be described again.

請參照圖2、圖5A與圖6,在進行步驟S100與步驟S102之後,進行步驟S504,以方波伏安法對第一電極204連續施加多組方波電壓(如圖6所示的多組方波電壓VS)。相鄰的兩組方波電壓VS的間隔為0.1秒至4秒。每一組方波電壓VS可等同於圖3所示的方波電壓V1,其彼此之間的差異僅在於施加的時間點不同。如此一來,第一工作電極204a可接收連續的多組方波電壓VS而使全血樣品在第一反應區202中進行電性反應,以得到有關於血球容積比的多個回饋值。 Referring to FIG. 2, FIG. 5A and FIG. 6, after performing step S100 and step S102, step S504 is performed to continuously apply a plurality of sets of square wave voltages to the first electrode 204 by square wave voltammetry (as shown in FIG. 6). Group square wave voltage VS). The interval between adjacent two groups of square wave voltages VS is from 0.1 second to 4 seconds. Each set of square wave voltages VS can be identical to the square wave voltage V1 shown in FIG. 3, which differs from each other only in the point in time of application. In this way, the first working electrode 204a can receive a continuous plurality of sets of square wave voltages VS to electrically react the whole blood sample in the first reaction zone 202 to obtain a plurality of feedback values related to the hematocrit ratio.

在一些實施例中,全血樣品進入第一反應區202(或進入第一反應區202與第二反應區206)的起始時間點T0等於對第一電極204施加第1組方波電壓VS的起始時間點TS1。舉例而言,起始時間點T0為全血樣品的量在第一反應區202(或第一反應區202與第二反應區206)上達到一門檻值的時間點。所屬領域中具有通常知識者可依據檢測需求而調整此門檻值,本發明並不以此為限。換言之,在上述的實施例中,當全血樣品進入第一反應區202(或第一反應區202與第二反應區206)時,即開始對第一電極204施加第一組方波電壓VS。在其他實施例中,亦可在全血樣品填滿第一反應區202(或進入第一反應區202與第二反應區206)之後,再對第一電極204施加第1組方波電壓VS。換言之,起始 時間點TS1亦可在起始時間點T0之後。所屬領域中具有通常知識者可依據檢測需求而調整起始時間點TS1與起始時間點T0的先後順序,本發明並不以此為限。 In some embodiments, the start time point T0 at which the whole blood sample enters the first reaction zone 202 (or enters the first reaction zone 202 and the second reaction zone 206) is equal to applying the first set of square wave voltages VS to the first electrode 204. The starting point is TS1. For example, the starting time point T0 is the time point at which the amount of the whole blood sample reaches a threshold value in the first reaction zone 202 (or the first reaction zone 202 and the second reaction zone 206). Those having ordinary knowledge in the art can adjust the threshold according to the detection requirement, and the invention is not limited thereto. In other words, in the above embodiment, when the whole blood sample enters the first reaction zone 202 (or the first reaction zone 202 and the second reaction zone 206), the first set of square wave voltages VS are applied to the first electrode 204. . In other embodiments, the first set of square wave voltages VS may be applied to the first electrode 204 after the whole blood sample fills the first reaction zone 202 (or enters the first reaction zone 202 and the second reaction zone 206). . In other words, the beginning The time point TS1 can also be after the start time point T0. A person having ordinary knowledge in the art can adjust the sequence of the start time point TS1 and the start time point T0 according to the detection requirement, and the present invention is not limited thereto.

進行步驟S506,取得第n組方波電壓VS的回饋值,以推算出全血樣品的血球容積比。n為大於1的正整數。在一些實施例中,取得第n組方波電壓VS的回饋值包含第1組以後的任一組方波電壓VS的回饋值、或者是取第1組以後多組方波電壓VS的平均回饋值。取第1組以後的方波電壓VS的回饋值的原因可包括第1組方波電壓VS的回饋值較容易受到外在環境的影響。換言之,第1組以後的方波電壓VS的回饋值可趨於穩定,而可據此推算出較精確的血球容積比。在一些實施例中,n為大於或等於3的正整數。所屬領域中具有通常知識者可依據量測情況選擇第1組以後的方波電壓VS中任一組回饋或其多組平均回饋值來推算血球容積比,本發明並不以此為限。此外,以第n組方波電壓VS的回饋值推算血球容積比的方法可參照圖1A的步驟S106的相關說明。 Step S506 is performed to obtain a feedback value of the n-th group square wave voltage VS to calculate a blood cell volume ratio of the whole blood sample. n is a positive integer greater than one. In some embodiments, the feedback value of the nth group of square wave voltages VS includes the feedback value of any group of square wave voltages VS after the first group, or the average feedback of the plurality of groups of square wave voltages VS after the first group. value. The reason for taking the feedback value of the square wave voltage VS after the first group may include that the feedback value of the first group square wave voltage VS is more susceptible to the external environment. In other words, the feedback value of the square wave voltage VS after the first group can be stabilized, and a more accurate hematocrit ratio can be derived therefrom. In some embodiments, n is a positive integer greater than or equal to 3. A person having ordinary knowledge in the art can select any one of the group wave feedbacks VS or the plurality of groups of average feedback values after the first group to calculate the hematocrit ratio according to the measurement condition, and the present invention is not limited thereto. Further, a method of estimating the blood cell volume ratio by the feedback value of the nth group square wave voltage VS can be referred to the related description of step S106 of FIG. 1A.

相似於圖1A所示的血球容積比的量測方法,本實施例的血球容積比的量測方法藉由多次施加方波電壓VS,亦可破壞全血樣品與第一電極204之間(及全血樣品與第二電極208之間)的水膜及微氣泡。因此,可避免環境中的濕氣及微氣泡對血球容積比的量測結果造成影響。 Similar to the measurement method of the hematocrit ratio shown in FIG. 1A, the method for measuring the hematocrit ratio of the present embodiment can also destroy the whole blood sample and the first electrode 204 by applying the square wave voltage VS multiple times ( And a water film and microbubbles between the whole blood sample and the second electrode 208). Therefore, it is possible to avoid the influence of moisture and microbubbles in the environment on the measurement result of the blood volume ratio.

請參照圖5B與圖6,本實施例的血液檢測方法相似於圖 1B所示的血液檢測方法,且包括圖5A所示的血球容積比的量測方法。以簡潔起見,對於相同或相似處不再贅述。 Referring to FIG. 5B and FIG. 6, the blood detecting method of this embodiment is similar to the figure. The blood detecting method shown in 1B, and including the blood cell volume ratio measuring method shown in Fig. 5A. For the sake of brevity, the same or similar parts will not be described again.

進行步驟S100a與步驟S102a之後,進行步驟S504a,以方波伏安法對第一電極204連續施加多組方波電壓VS。兩組方波電壓的間隔為0.1秒至4秒。每一組方波電壓VS可等同於圖3所示的方波電壓V1,其彼此之間的差異僅在於施加的時間點不同。如此一來,第一工作電極204a可接收連續的多組方波電壓VS而使全血樣品在第一反應區202中進行電性反應,以得到有關於血球容積比的多個回饋值。 After step S100a and step S102a are performed, step S504a is performed to continuously apply a plurality of sets of square wave voltages VS to the first electrode 204 by square wave voltammetry. The interval between the two groups of square wave voltages is from 0.1 second to 4 seconds. Each set of square wave voltages VS can be identical to the square wave voltage V1 shown in FIG. 3, which differs from each other only in the point in time of application. In this way, the first working electrode 204a can receive a continuous plurality of sets of square wave voltages VS to electrically react the whole blood sample in the first reaction zone 202 to obtain a plurality of feedback values related to the hematocrit ratio.

進行步驟S508,對第二電極208施加電壓V3’,以推算全血樣品中的目標分析物的濃度。在一些實施例中,第1組方波電壓VS的起始時間點TS1可在電壓V3’的起始時間點T3之前。第1組方波電壓VS的起始時間點TS1可等同於全血樣品進入第一反應區202的起始時間點T0,或可在起始時間點T0之後。再者,電壓V3’的起始時間點T3可在第n組方波電壓VS以後。n為大於1的正整數。在一些實施例中,n為大於或等於3的正整數。在其他實施例中,第1組方波電壓VS的起始時間點TS1可在電壓V3’的起始時間點T3之後,或可等於電壓V3’的起始時間點T3,本發明並不以此為限。 Step S508 is performed to apply a voltage V3' to the second electrode 208 to estimate the concentration of the target analyte in the whole blood sample. In some embodiments, the start time point TS1 of the first group of square wave voltages VS may precede the start time point T3 of the voltage V3'. The start time point TS1 of the first group square wave voltage VS may be equivalent to the start time point T0 at which the whole blood sample enters the first reaction zone 202, or may be after the start time point T0. Furthermore, the starting time point T3 of the voltage V3' may be after the nth group of square wave voltages VS. n is a positive integer greater than one. In some embodiments, n is a positive integer greater than or equal to 3. In other embodiments, the starting time point TS1 of the first group of square wave voltages VS may be after the starting time point T3 of the voltage V3', or may be equal to the starting time point T3 of the voltage V3', the present invention does not This is limited.

在步驟S508中,推算全血樣品中的目標分析物的濃度的方法可包括先依據第1組以後的任一組方波電壓VS的回饋值或其多組方波電壓VS的平均回饋值計算全血樣品中的血球容積比。接 著,以類似於圖1B所示的步驟S108的方法得到目標分析物的濃度對電壓V3’的回饋值的通式。據此,可將電壓V3’的回饋值代入上述通式而得到目標分析物的濃度。 In step S508, the method for estimating the concentration of the target analyte in the whole blood sample may include calculating according to the feedback value of any group of square wave voltages VS after the first group or the average feedback value of the plurality of groups of square wave voltages VS. Hematocrit ratio in whole blood samples. Connect The general formula of the feedback value of the concentration of the target analyte to the voltage V3' is obtained in a manner similar to the step S108 shown in Fig. 1B. According to this, the feedback value of the voltage V3' can be substituted into the above formula to obtain the concentration of the target analyte.

進行步驟S510,判斷第1組以後的方波電壓的任意兩個回饋值的比值是否在預設範圍之間。在一些實施例中,預設範圍為0.85至1.18。 Step S510 is performed to determine whether the ratio of any two feedback values of the square wave voltage after the first group is between the preset ranges. In some embodiments, the preset range is from 0.85 to 1.18.

若第1組以後的方波電壓的任意兩個回饋值的比值在預設範圍之間,則進行步驟S512,採用目標分析物的推算出的濃度。反之,若第1組以後的方波電壓的任意兩個回饋值的比值不在預設範圍之間,而是小於或大於預設範圍,則進行步驟S514,提供檢測異常的訊息。 If the ratio of any two feedback values of the square wave voltages after the first group is between the preset ranges, step S512 is performed to calculate the calculated concentration of the target analyte. On the other hand, if the ratio of any two feedback values of the square wave voltage after the first group is not between the preset ranges, but is smaller or larger than the preset range, step S514 is performed to provide a message for detecting an abnormality.

相似於圖1B所示的血液檢測方法,本實施例的血液檢測方法亦可藉由步驟S510、步驟S512以及步驟S514排除外在因素對檢測目標分析物濃度的干擾。 Similar to the blood detecting method shown in FIG. 1B, the blood detecting method of the present embodiment can also eliminate the interference of external factors on the detection target analyte concentration by steps S510, S512, and S514.

接下來,將以實驗例與比較例來說明本發明實施例的效果。 Next, the effects of the embodiments of the present invention will be described by way of experimental examples and comparative examples.

<實驗例1><Experimental Example 1>

對於具有不同的血球容積比與不同的血糖含量的全血樣品依序進行如圖1A所示的步驟S100、步驟S102與步驟S104。請參照圖2至圖4,實驗例1的方波電壓V1的初始電壓Einit為0V,固定電壓振幅Amp為0.01V,增幅電壓Eincr為0.01V,且頻率F為300Hz。此外,全血樣品進入檢測試片200的第一反應區202 的起始時間T0與施加一組方波電壓V1於第一電極204的起始時間T1之間的間隔為0.5秒。 Step S100, step S102, and step S104 shown in FIG. 1A are sequentially performed for whole blood samples having different hematocrit ratios and different blood sugar contents. Referring to FIGS. 2 to 4, the initial voltage Einit of the square wave voltage V1 of Experimental Example 1 is 0 V, the fixed voltage amplitude Amp is 0.01 V, the amplification voltage Eincr is 0.01 V, and the frequency F is 300 Hz. In addition, the whole blood sample enters the first reaction zone 202 of the test strip 200. The interval between the start time T0 and the start time T1 at which the set of square wave voltage V1 is applied to the first electrode 204 is 0.5 second.

<比較例1><Comparative Example 1>

比較例1以差分脈衝伏安法(differential pulse voltammetry)對上述具有不同的血球容積比與不同的血糖含量的全血樣品施加電壓而得到回饋值。比較例1的差分脈衝伏安法的初始電壓為0V,固定電壓振幅為0.05V,增幅電壓為0.045V,且間隔時間(interval time)為0.02秒。此外,全血樣品進入檢測試片200的第一反應區202的起始時間與以差分脈衝伏安法施加電壓於第一電極204的起始時間之間的間隔為0.5秒。 In Comparative Example 1, a voltage was applied to a whole blood sample having different hematocrit ratios and different blood sugar contents by differential pulse voltammetry to obtain a feedback value. The differential voltage voltammetry of Comparative Example 1 had an initial voltage of 0 V, a fixed voltage amplitude of 0.05 V, an amplification voltage of 0.045 V, and an interval time of 0.02 sec. Further, the interval between the start time of the whole blood sample entering the first reaction zone 202 of the test strip 200 and the start time of applying the voltage to the first electrode 204 by differential pulse voltammetry is 0.5 second.

<實驗例1與比較例1的比較><Comparison of Experimental Example 1 and Comparative Example 1>

下表1整理實驗例1的結果,且下表2整理比較例1的結果。 Table 1 below summarizes the results of Experimental Example 1, and Table 2 below summarizes the results of Comparative Example 1.

表2 Table 2

由上表1與表2可知,在使用差分脈衝伏安法的比較例1中,同樣血糖濃度樣本所得到的電流回饋值的確可以區分出樣本中的血球容積比的不同,但在同一血球容積比不同血糖含量之樣本中,使用差分脈衝伏安法得到的電流回饋值卻會與樣品中的血糖含量呈明顯之正相關的關係,而此一與血糖含量成正相關之關係在方波伏安法的實驗例1中較不明顯。由此可知,相較於差分脈衝法,方波伏安法對於全血樣品中的血糖含量較不敏感,故量測樣本中的血球容積比時,較不受血糖濃度引起之電流變化干 擾,可更精確地量測全血樣品的血球容積比。 As can be seen from the above Table 1 and Table 2, in Comparative Example 1 using the differential pulse voltammetry, the current feedback value obtained by the same blood glucose concentration sample can distinguish the difference in the hematocrit ratio in the sample, but in the same hematocrit volume. In the samples with different blood glucose levels, the current feedback value obtained by differential pulse voltammetry is significantly positively correlated with the blood glucose content in the sample, and this relationship with the blood glucose content is positively correlated with the square wave voltammetry. The experimental example 1 of the method is less obvious. It can be seen that square wave voltammetry is less sensitive to blood glucose content in whole blood samples than differential pulse method. Therefore, when the blood volume ratio in the sample is measured, it is less affected by the current change caused by blood glucose concentration. Disturbance, which can more accurately measure the hematocrit ratio of whole blood samples.

<實驗例2><Experimental Example 2>

對於已知具有不同血球容積比的全血樣品A至全血樣品E分別進行如圖1A所示的步驟S100、步驟S102以及步驟S104。全血樣品A的已知血球容積比為20%,全血樣品B的已知血球容積比為31%,全血樣品C的已知血球容積比為40%,全血樣品D的已知血球容積比為51%且全血樣品E的已知血球容積比為60%。請參照圖2至圖4,實驗例2的方波電壓V1的初始電壓Einit為0.15V,固定電壓振幅Amp為0.17V,增幅電壓Eincr為0.04V,且頻率F為750Hz。此外,全血樣品進入檢測試片200的第一反應區202的起始時間T0與施加一組方波電壓V1於第一電極204的起始時間T1之間的間隔為5秒。 The whole blood sample A to the whole blood sample E which are known to have different hematocrit ratios are respectively subjected to step S100, step S102, and step S104 as shown in FIG. 1A. The known hematocrit ratio of whole blood sample A is 20%, the known hematocrit ratio of whole blood sample B is 31%, the known hematocrit ratio of whole blood sample C is 40%, and the known blood cell of whole blood sample D is The volume ratio was 51% and the known hematocrit ratio of whole blood sample E was 60%. Referring to FIGS. 2 to 4, the initial voltage Einit of the square wave voltage V1 of Experimental Example 2 is 0.15 V, the fixed voltage amplitude Amp is 0.17 V, the amplification voltage Eincr is 0.04 V, and the frequency F is 750 Hz. Further, the interval between the start time T0 of the whole blood sample entering the first reaction zone 202 of the test strip 200 and the start time T1 of applying the set of square wave voltage V1 to the first electrode 204 is 5 seconds.

<比較例2><Comparative Example 2>

比較例2與實驗例2相似,兩者的差異僅在於比較例的起始時間T0等於起始時間T1,亦即起始時間T0與起始時間T1之間不具有間隔。如此一來,當全血樣品進入檢測試片200的第一反應區202時,立即對第一電極204施加方波電壓V1。 Comparative Example 2 is similar to Experimental Example 2 except that the start time T0 of the comparative example is equal to the start time T1, that is, there is no interval between the start time T0 and the start time T1. As such, when the whole blood sample enters the first reaction zone 202 of the test strip 200, the square wave voltage V1 is applied to the first electrode 204 immediately.

<實驗例2與比較例2的比較><Comparison of Experimental Example 2 and Comparative Example 2>

下表3整理實驗例2與比較例2的結果。 Table 3 below summarizes the results of Experimental Example 2 and Comparative Example 2.

一般而言,方波電壓的回饋值與全血樣品的血球容積比呈負相關的關係。由上表3可知,實驗例2的結果可符合上述負相關的關係。相較而言,無法由比較例2的結果觀察出上述負相關的關係。由此可知,使全血樣品在第一反應區202停留一間隔時間後再對第一電極204以方波伏安法施加一組方波電壓V1,可提高量測血球容積比及/或進行血液檢測的準確度。 In general, the feedback value of the square wave voltage is inversely related to the hematocrit ratio of the whole blood sample. As can be seen from the above Table 3, the results of Experimental Example 2 can conform to the above negative correlation. In comparison, the above negative correlation cannot be observed from the results of Comparative Example 2. Therefore, it can be known that after the whole blood sample stays in the first reaction zone 202 for an interval time, a square wave voltage V1 is applied to the first electrode 204 by square wave voltammetry, thereby increasing the blood volume ratio and/or performing the measurement. The accuracy of blood testing.

<實驗例3><Experimental Example 3>

在實驗例3中,於不同濕度環境下依序進行如圖5A所示的步驟S100、步驟S102與步驟S504。在實驗例3中,以方波伏安法對第一電極連續施加多組方波電壓VS,相鄰兩組方波電壓VS的間隔為1秒。接著,以第3組的方波電壓VS的回饋值推算全血樣品的血球容積比。在進行上述步驟之前,先將對檢測試片200的第一電極204施加電壓的機台置於濕度分別為31%、60%以及90%的環境並平衡30分鐘。隨即,對於具有不同血球容積比的全血樣品(血球容積比分別為20%、31%、40%、50%以及59%)進行上述的步驟S100、步驟S102以及步驟S504。在步驟S504中,方波電壓VS的初始電壓Einit為0.1V,且目標電壓Efinal為0.4V。 In Experimental Example 3, steps S100, S102, and S504 shown in FIG. 5A were sequentially performed in different humidity environments. In Experimental Example 3, a plurality of sets of square wave voltages VS were continuously applied to the first electrode by square wave voltammetry, and the interval between adjacent two groups of square wave voltages VS was 1 second. Next, the blood cell volume ratio of the whole blood sample is estimated from the feedback value of the third group square wave voltage VS. Before performing the above steps, the machine for applying a voltage to the first electrode 204 of the test strip 200 was placed in an environment having a humidity of 31%, 60%, and 90%, respectively, and equilibrated for 30 minutes. Immediately thereafter, the above-described step S100, step S102, and step S504 are performed for the whole blood samples having different hematocrit ratios (the blood cell volume ratios are 20%, 31%, 40%, 50%, and 59%, respectively). In step S504, the initial voltage E init of the square wave voltage VS is 0.1 V, and the target voltage E final is 0.4 V.

圖7是依照本發明實驗例3在不同濕度下方波電壓的回饋值對血球容積比的作圖。 Fig. 7 is a graph showing the ratio of the feedback value of the wave voltage to the blood cell volume ratio in Experimental Example 3 according to the present invention.

圖7的縱座標為方波電壓VS的回饋值,且橫座標為血球容積比。此外,方形資料點代表對於相對濕度60%的方波電壓VS的第3個回饋值、圓形資料點代表對於相對濕度31%的方波電壓VS的第3個回饋值且三角形資料點代表對於相對濕度90%的方波電壓VS的第3個回饋值。 The ordinate of Fig. 7 is the feedback value of the square wave voltage VS, and the abscissa is the hematocrit ratio. In addition, the square data points represent the third feedback value of the square wave voltage VS with a relative humidity of 60%, the circular data points represent the third feedback value of the square wave voltage VS for the relative humidity of 31%, and the triangular data points represent The third feedback value of the square wave voltage VS with a relative humidity of 90%.

<比較例3>比較例3與上述實驗例3相似,惟比較例3係取第1組的方波電壓VS的回饋值推算全血樣品的血球容積比。 <Comparative Example 3> Comparative Example 3 is similar to Experimental Example 3 except that Comparative Example 3 estimates the hematocrit ratio of the whole blood sample by taking the feedback value of the square wave voltage VS of the first group.

圖8是依照比較例3在不同濕度下方波電壓的回饋值對血球容積比的作圖。 Fig. 8 is a graph showing the ratio of the feedback value of the wave voltage to the hematocrit ratio in the lower humidity according to Comparative Example 3.

圖8的縱座標為方波電壓VS的回饋值,且橫座標為血球容積比。此外,方形資料點代表對於相對濕度90%的方波電壓VS的第1個回饋值、圓形資料點代表對於相對濕度60%的方波電壓VS的第1個回饋值且三角形資料點代表對於相對濕度31%的方波電壓VS的第1個回饋值。 The ordinate of Fig. 8 is the feedback value of the square wave voltage VS, and the abscissa is the hematocrit ratio. In addition, the square data points represent the first feedback value of the square wave voltage VS with a relative humidity of 90%, the circular data points represent the first feedback value of the square wave voltage VS for the relative humidity of 60%, and the triangular data points represent The first feedback value of the square wave voltage VS with a relative humidity of 31%.

<實驗例3與比較例3的比較><Comparison of Experimental Example 3 and Comparative Example 3>

下表4整理圖7所示的實驗例3的數據,且下表5整理圖8所示的比較例3的數據。 Table 4 below summarizes the data of Experimental Example 3 shown in Fig. 7, and Table 5 below summarizes the data of Comparative Example 3 shown in Fig. 8.

由表4與表5可知,實驗例3與比較例3的的回饋值大致上均是與全血樣品中的血球容積比呈現負相關的關係。以相同 的血球容積比而言,實驗例3對於不同相對濕度的回饋值相當一致。以血球容積比21%的樣品作為範例,實驗例3的對於相對濕度31%、60%與90%的回饋值的最大差異僅為29.5。相較之下,以相同的血球容積比而言,比較例3對於不同相對濕度的回饋值則變異較大。以血球容積比21%的樣品作為範例,比較例3的對於相對濕度31%、60%與90%的回饋值的最大差異為173.8。因此,由上述的實驗例3與比較例3可知,本發明實施例藉由方波伏安法對全血樣品進行施加電壓檢測,且取第1組以後的回饋值來推算血球容積比,可避免環境中的濕氣對其結果造成的影響。 As can be seen from Tables 4 and 5, the feedback values of Experimental Example 3 and Comparative Example 3 were substantially negatively correlated with the hematocrit ratio in the whole blood sample. Same as The blood cell volume ratio of Experiment 3 is quite consistent for the feedback values of different relative humidity. Taking the sample having a hematocrit ratio of 21% as an example, the maximum difference of the feedback values of the experimental examples 3 for the relative humidity of 31%, 60%, and 90% was only 29.5. In contrast, Comparative Example 3 has a large variation in feedback values for different relative humidity in terms of the same hematocrit ratio. Taking a sample having a hematocrit ratio of 21% as an example, the maximum difference of the feedback values of Comparative Example 3 for relative humidity of 31%, 60%, and 90% was 173.8. Therefore, it can be seen from the above Experimental Example 3 and Comparative Example 3 that the embodiment of the present invention applies a voltage detection to a whole blood sample by square wave voltammetry, and estimates the blood cell volume ratio by taking the feedback value after the first group. Avoid the effects of moisture in the environment on its results.

綜上所述,本發明實施例的血球容積比的量測方法藉由全血樣品在第一反應區停留一間隔時間後再以方波伏安法對檢測試片的第一電極施加方波電壓、或者是以方波伏安法對第一電極連續施加多組方波電壓,都可有效破壞全血樣品與電極之間的水膜與微氣泡。如此一來,可降低環境中的濕氣及微氣泡對血球容積比的量測造成的影響,故可量測到較精確的血球容積比。此外,本發明採用方波伏安法進行血球容積比的量測時,較不易受到目標分析物濃度的影響。 In summary, the method for measuring the hematocrit ratio of the embodiment of the present invention applies a square wave to the first electrode of the test strip by square wave voltammetry after the whole blood sample stays in the first reaction zone for an interval time. The voltage or the continuous application of multiple sets of square wave voltages to the first electrode by square wave voltammetry can effectively destroy the water film and microbubbles between the whole blood sample and the electrode. In this way, the influence of moisture and microbubbles in the environment on the measurement of the hematocrit ratio can be reduced, so that a more accurate hematocrit ratio can be measured. In addition, the present invention uses the square wave voltammetry to measure the hematocrit ratio, which is less susceptible to the target analyte concentration.

本發明實施例的血液檢測方法根據上述量測到的血球容積比以及對第二電極施加電壓得到的另一回饋值推算出全血樣品中目標分析物的濃度。在一些實施例中,藉由判斷取得兩組方波電壓的回饋值的比值是否落於特定範圍內,而決定是否採用由此回饋值推算出的目標分析物的濃度。在連續施加多組方波電壓的 實施例中,藉由判斷取得第1組以後的方波電壓的任意兩個回饋值的比值是否落於特定範圍內,而決定是否採用此回饋值推算出的目標分析物的濃度。如此一來,本發明實施例的血液檢測方法可排除外在因素對檢測目標分析物的濃度造成的干擾。 The blood detecting method according to the embodiment of the present invention estimates the concentration of the target analyte in the whole blood sample based on the measured blood cell volume ratio and another feedback value obtained by applying a voltage to the second electrode. In some embodiments, it is determined whether the concentration of the target analyte derived from the feedback value is used by determining whether the ratio of the feedback values of the two sets of square wave voltages is within a specific range. Applying multiple sets of square wave voltages continuously In the embodiment, it is determined whether or not the ratio of the arbitrary two feedback values of the square wave voltage after the first group is within a specific range, and whether or not the concentration of the target analyte estimated by the feedback value is used. In this way, the blood detecting method of the embodiment of the present invention can eliminate the interference caused by external factors on detecting the concentration of the target analyte.

雖然本發明已以實施例揭露如上,然其並非用以限定本發明,任何所屬技術領域中具有通常知識者,在不脫離本發明的精神和範圍內,當可作些許的更動與潤飾,故本發明的保護範圍當視後附的申請專利範圍所界定者為準。 Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and any one of ordinary skill in the art can make some changes and refinements without departing from the spirit and scope of the present invention. The scope of the invention is defined by the scope of the appended claims.

Claims (5)

一種血球容積比的量測方法,包括:提供檢測試片,其中所述檢測試片包括反應區以及設置於所述反應區的一對電極;使全血樣品進入所述反應區;在所述全血樣品進入所述反應區之後,以方波伏安法對所述一對電極施加一組方波電壓,以得到與血球容積比相關的回饋值,其中所述全血樣品進入所述反應區的起始時間點與施加所述一組方波電壓的起始時間點相差0.1秒至200秒;以及依據所述回饋值推算出血球容積比,其中所述推算血球容積比的方法包括:藉由使用已知血球容積比的標準全血樣品得到回饋值對於血球容積比的通式;以及以所述全血樣品的所述回饋值代入所述通式的回饋值,以得到對應的血球容積比的值。 A method for measuring a blood cell volume ratio, comprising: providing a test strip, wherein the test strip includes a reaction zone and a pair of electrodes disposed in the reaction zone; allowing a whole blood sample to enter the reaction zone; After the whole blood sample enters the reaction zone, a set of square wave voltages are applied to the pair of electrodes by square wave voltammetry to obtain a feedback value associated with the hematocrit ratio, wherein the whole blood sample enters the reaction The start time point of the zone is different from the start time point of applying the set of square wave voltages by 0.1 second to 200 seconds; and the blood cell volume ratio is calculated according to the feedback value, wherein the method for estimating the blood cell volume ratio comprises: Generating a feedback value for a hematocrit ratio by using a standard whole blood sample of a known hematocrit ratio; and substituting the feedback value of the whole blood sample into the feedback value of the formula to obtain a corresponding blood cell The value of the volume ratio. 如申請專利範圍第1項所述的血球容積比的量測方法,其中所述一對電極包括工作電極與參考電極,所述工作電極與所述參考電極的間距範圍為0.01mm至5mm,及/或所述工作電極的面積對於所述參考電極的面積的比值範圍為1至1.5。 The method for measuring a hematocrit ratio according to the first aspect of the invention, wherein the pair of electrodes comprises a working electrode and a reference electrode, and the distance between the working electrode and the reference electrode ranges from 0.01 mm to 5 mm, and / The ratio of the area of the working electrode to the area of the reference electrode ranges from 1 to 1.5. 如申請專利範圍第1項所述的血球容積比的量測方法,其中所述一組方波電壓的頻率範圍為100Hz至4000Hz、所述一組 方波電壓的振幅大於或等於0.01V、及/或所述一組方波電壓中的電壓增幅範圍為0.01V至0.4V。 The method for measuring a hematocrit ratio according to claim 1, wherein the set of square wave voltages has a frequency ranging from 100 Hz to 4000 Hz, the group The amplitude of the square wave voltage is greater than or equal to 0.01 V, and/or the voltage increase in the set of square wave voltages ranges from 0.01 V to 0.4 V. 如申請專利範圍第1項所述的血球容積比的量測方法,其中所述一組方波電壓的電壓掃描範圍為0V至0.8V,及/或所述一組方波電壓的施加時間範圍為0.01秒至4秒。 The method for measuring a hematocrit ratio according to claim 1, wherein the voltage sweep range of the set of square wave voltages is 0V to 0.8V, and/or the application time range of the set of square wave voltages. It is 0.01 seconds to 4 seconds. 一種血球容積比的量測方法,包括:提供檢測試片,其中所述檢測試片包括反應區以及設置於所述反應區的一對電極;使全血樣品進入所述反應區;以方波伏安法對所述一對電極連續施加多組方波電壓,以得到與血球容積比相關的多個回饋值,其中相鄰兩組方波電壓的間隔為0.1秒至4秒;取得第n組方波電壓的回饋值,以推算出所述全血樣品的血球容積比,其中n為大於1的正整數。 A method for measuring a blood cell volume ratio, comprising: providing a test strip, wherein the test strip includes a reaction zone and a pair of electrodes disposed in the reaction zone; allowing a whole blood sample to enter the reaction zone; Voltammetry continuously applies a plurality of sets of square wave voltages to the pair of electrodes to obtain a plurality of feedback values related to a hematocrit ratio, wherein an interval between adjacent two groups of square wave voltages is 0.1 second to 4 seconds; The feedback value of the group square wave voltage is used to derive the hematocrit ratio of the whole blood sample, where n is a positive integer greater than one.
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