TWM464753U - Micro body liquid detection chip - Google Patents
Micro body liquid detection chip Download PDFInfo
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- TWM464753U TWM464753U TW102212579U TW102212579U TWM464753U TW M464753 U TWM464753 U TW M464753U TW 102212579 U TW102212579 U TW 102212579U TW 102212579 U TW102212579 U TW 102212579U TW M464753 U TWM464753 U TW M464753U
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本創作係一種晶片,特別是動物或是人體的微形體液偵測晶片。This creation is a wafer, especially a micro-body fluid detection wafer for animals or humans.
習知技術,動物或是人體的體液檢測,係經由穿刺表層皮膚,進行取樣後,將所取樣的體液樣本,在體外的環境中,進行動物或是人體的體液檢測,因此若是需要長時間追蹤的體液檢測,不但因穿刺表層皮膚,進行取樣頻繁,容易傷害動物或是人體的組織,而且追蹤耗時。Conventional technology, animal or human body fluid testing, through the skin of the skin, after sampling, the sampled body fluid sample, in the external environment, animal or human body fluid testing, so if it takes a long time to track The body fluid test not only takes frequent sampling due to puncture of the superficial skin, but also easily damages the tissues of the animal or the human body, and the time is traced.
習知技術,如中華民國專利第M353438號,該創作為有關於一種患者看護報知之裝置,係包括有按壓感知器與主機,該按壓感知器設置於醫療器材上,按壓感知器可將測得結果以電訊號無線傳輸,該主機可供接收該按壓感知器所傳送之電訊號並且可發出一警告信號,俾當患者離開醫療器材而觸動該按壓感知器時,該主機即可發出一警告信號藉以提醒看護人員進行照料,達到了具有看護報知效果之實用進步性。A conventional technique, such as the Republic of China Patent No. M353438, which is a device for patient care notification, comprising a pressing sensor and a host, the pressing sensor being disposed on a medical device, and the pressing sensor can measure The result is wirelessly transmitted by the electric signal, and the host can receive the electric signal transmitted by the pressing sensor and can issue a warning signal. When the patient leaves the medical device and touches the pressing sensor, the host can issue a warning signal. In order to remind the caregivers to take care of them, it has achieved practical progress with the effect of nursing attention.
習知技術,如中華民國專利第201232423號,該發明係一種手指感測裝置可包括一手指感測像素陣列,以接收鄰近於該手指感測像素陣列之一使用者之手指。每一手指感測像素可包括一手指感測電極。該手指感測裝置可包括一手指驅動電極,該手指驅動電 極經組態以將一驅動信號經該使用者之手指耦接至該手指感測像素陣列。該手指感測裝置亦可包括差動像素量測電路,其耦接至該手指感測像素陣列且經組態以產生對該等手指感測像素之鄰近對的複數個像素間差異量測。A conventional technique, such as the Republic of China Patent No. 201232423, which is a finger sensing device that can include an array of finger sensing pixels to receive a finger adjacent to a user of the array of finger sensing pixels. Each finger sensing pixel can include a finger sensing electrode. The finger sensing device can include a finger driving electrode that drives the battery The pole is configured to couple a drive signal to the array of finger sensing pixels via the user's finger. The finger sensing device can also include a differential pixel measurement circuit coupled to the array of finger sensing pixels and configured to generate a plurality of inter-pixel difference measurements of adjacent pairs of the finger sensing pixels.
本創作提供一種微形體液偵測晶片,其中係將射頻識別(RF ID)標籤晶片植入人體或動物的皮下組織內,由於射頻識別(RF ID)標籤晶片,係由體外射頻識別(RF ID)讀取晶片提供充電能量,因此本創作微形體液偵測晶片,具有無需電池電力功能的優點。被動式的充電結構,使得本創作射頻識別(RF ID)標籤晶片植入人體,無需植入電池電力,即可將本創作中生物體液檢測晶片所偵測的生化訊號,經由人體或動物的表層組織,傳輸至體外的射頻識別(RF ID)讀取晶片,因此本創作可以避免習知技術中,穿刺表層皮膚,進行取樣頻繁,容易傷害動物或是人體的組織的缺點,再者本創作將生物體液檢測晶片植入,並結合射頻識別(RF ID)標籤晶片,持續傳輸生化訊號,可以達到減少追蹤耗時的目的。This creation provides a micro-body fluid detection wafer in which a radio frequency identification (RF ID) tag wafer is implanted into the subcutaneous tissue of a human or animal, due to radio frequency identification (RF ID) tag wafers, which are externally radio frequency identified (RF ID). The reading of the wafer provides charging energy, so the micro-body fluid detecting chip of the present invention has the advantage of eliminating the need for battery power. The passive charging structure enables the creation of the radio frequency identification (RF ID) tag wafer into the human body, and the biochemical signal detected by the biological fluid detecting chip in the present invention can be organized through the surface layer of the human body or animal without the need to implant battery power. The radio frequency identification (RF ID) is transmitted to the external body to read the wafer, so this creation can avoid the disadvantages of the prior art, puncture the skin of the skin, frequently sample, and easily damage the tissue of the animal or the human body. The body fluid detection wafer is implanted and combined with radio frequency identification (RF ID) tag wafers to continuously transmit biochemical signals, which can reduce the tracking time.
本創作提供一種微形體液偵測晶片,減少醫療看護人員、核能電廠工作人員、以及監獄戒護人員,採用人工醫療生化偵測的耗時耗力,此外,對於臨床藥物施用的追蹤,本創作也提供長期有效的體液偵測追蹤結構。This creation provides a micro-body fluid detection chip that reduces the time-consuming and labor-intensive use of biomedical biochemical detection by medical caregivers, nuclear power plant staff, and prison guards. In addition, for the tracking of clinical drug administration, this creation A long-term effective body fluid detection tracking structure is also provided.
本創作一實施例,係提供一種微形體液偵測晶片,其係包括:一射頻識別(RF ID)標籤晶片,其係植入動物或人體的一皮下組織;一生物體液檢測晶片,其係連結該射頻識別(RF ID)晶片,並植入動物或人體的一皮下組織;一射頻識別(RF ID)讀取晶片,其 係讀取該射頻識別(RF ID)標籤晶片內的訊號。An embodiment of the present invention provides a micro-body fluid detecting chip, comprising: a radio frequency identification (RF ID) tag wafer implanted in a subcutaneous tissue of an animal or a human body; and a biological fluid detecting chip, the system Connecting the radio frequency identification (RF ID) wafer and implanting a subcutaneous tissue of the animal or human body; a radio frequency identification (RF ID) reading wafer, The signal in the radio frequency identification (RF ID) tag wafer is read.
11‧‧‧表層組織11‧‧‧Surface organization
12‧‧‧皮下組織12‧‧ ‧Subcutaneous organization
13‧‧‧微血管13‧‧‧microvascular
21‧‧‧頻識別(RF ID)標籤晶片21‧‧‧Frequency Identification (RF ID) Tag Wafer
22‧‧‧生物體液檢測晶片22‧‧‧ Biological fluid detection chip
23‧‧‧頻識別(RF ID)讀取晶片23‧‧‧frequency identification (RF ID) reading chip
圖1 微形體液偵測晶片中射頻識別標籤充電圖。Figure 1 Charging diagram of the RFID tag in the micro-body fluid detection chip.
圖2 微形體液偵測晶片中射頻識別標籤傳遞生化訊號圖。Figure 2 shows the biochemical signal map of the radio frequency identification tag in the micro-body fluid detection chip.
本創作一實施例,如圖1、圖2所示,係提供一種微形體液偵測晶片,其係包括:一射頻識別(RF ID)標籤晶片21,其係植入動物或人體的一皮下組織12;一生物體液檢測晶片22,其係連結該射頻識別(RF ID)晶片,並植入動物或人體的一皮下組織12;一射頻識別(RF ID)讀取晶片23,其係讀取該射頻識別(RF ID)標籤晶片21內的訊號。In an embodiment of the present invention, as shown in FIG. 1 and FIG. 2, a micro-body fluid detecting chip is provided, which comprises: a radio frequency identification (RF ID) tag wafer 21 implanted under a skin of an animal or a human body. Tissue 12; a biological fluid detection wafer 22 coupled to the radio frequency identification (RF ID) wafer and implanted into a subcutaneous tissue 12 of an animal or human body; a radio frequency identification (RF ID) reading wafer 23, which is read The signal within the radio frequency identification (RF ID) tag wafer 21.
其中該射頻識別(RF ID)讀取晶片23,係提供射頻能量,透過該表層組織11至該射頻識別(RF ID)標籤晶片21,用以提供能量給該射頻識別(RF ID)標籤晶片21,如圖1所示。The radio frequency identification (RF ID) reading chip 23 is configured to provide RF energy through the surface layer 11 to the radio frequency identification (RF ID) tag wafer 21 for providing energy to the radio frequency identification (RF ID) tag wafer 21 ,As shown in Figure 1.
其中該射頻識別(RF ID)標籤晶片21,從該射頻識別(RF ID)讀取晶片23獲得能量後,將該生物體液檢測晶片22中的醫生化訊號,透過該表層組織11,傳輸至該該射頻識別(RF ID)讀取晶片23,如圖2所示。The radio frequency identification (RF ID) tag chip 21, after obtaining energy from the radio frequency identification (RF ID) reading chip 23, transmits the medical signal in the biological fluid detecting chip 22 through the surface layer 11 to the The radio frequency identification (RF ID) reads the wafer 23 as shown in FIG.
其中該生物體液檢測晶片22,其係檢測並判讀與該生物體液檢測晶片22接觸體液的一生化成分,該體液係散佈於該微血管13、以及該皮下組織12之間,如圖1、圖2所示。The biological fluid detecting chip 22 detects and interprets a biochemical component in contact with the biological fluid detecting chip 22 in contact with the body fluid, and the body fluid is interspersed between the micro blood vessel 13 and the subcutaneous tissue 12, as shown in FIG. 1 and FIG. Shown.
其中該生化成分,包括:血糖指數濃度,以提供糖尿病的危險範圍追蹤。The biochemical component, including: glycemic index concentration, is used to provide a trace of the risk range of diabetes.
其中該生化成分,包括:藥物指數濃度,以提供藥物轉換代 謝範圍追蹤。The biochemical component, including: drug index concentration, to provide a drug conversion generation Xie range tracking.
其中該生化成分,包括:核污染指數濃度,以提供動物或人體的核污染範圍追蹤。The biochemical component, including: nuclear pollution index concentration, is provided to provide a range of nuclear contamination of animals or humans.
其中該生化成分,包括:癌症指數濃度,以提供動物或人體的癌症範圍追蹤。Among the biochemical components, including: cancer index concentration, to provide a range of cancers for animals or humans.
其中該生化成分,包括:肝臟指數濃度,以提供動物或人體的肝臟病範圍追蹤。The biochemical component, including: liver index concentration, is provided to provide a trace of the liver disease range of the animal or human.
其中該生化成分,包括:腎臟指數濃度,以提供動物或人體的腎臟病範圍追蹤。Among the biochemical components, including: kidney index concentration, to provide a range of kidney disease for animals or humans.
其中該生化成分,包括:毒品指數濃度,以提供動物或人體的毒品範圍追蹤。Among the biochemical components, including: drug index concentration, to provide a range of drugs for animal or human body tracking.
其中該生化成分,包括:毒物指數濃度,以提供動物或人體的毒物範圍追蹤。The biochemical component, including: the concentration of the toxicant index, is provided to provide a range of toxicants for the animal or human body.
其中該生化成分,包括:感染指數濃度,以提供動物或人體的感染範圍追蹤。The biochemical component, including: the concentration of the infection index, is provided to provide an indication of the extent of infection in the animal or human body.
其中該微形體液偵測晶片的射頻工作範圍係900Mhz。The radio frequency working range of the micro-body fluid detecting chip is 900 Mhz.
11‧‧‧表層組織11‧‧‧Surface organization
12‧‧‧皮下組織12‧‧ ‧Subcutaneous organization
13‧‧‧微血管13‧‧‧microvascular
21‧‧‧射頻識別(RF ID)標籤晶片21‧‧‧ Radio Frequency Identification (RF ID) tag wafer
22‧‧‧生物體液檢測晶片22‧‧‧ Biological fluid detection chip
23‧‧‧射頻識別(RF ID)讀取晶片23‧‧‧ Radio Frequency Identification (RF ID) Reading Chip
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