IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0945215
(2010-11-12)
|
등록번호 |
US-8709346
(2014-04-29)
|
발명자
/ 주소 |
- Saiki, Hiroshi
- Tanaka, Masanori
|
출원인 / 주소 |
|
대리인 / 주소 |
Wenderoth, Lind & Ponack, L.L.P.
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
8 |
초록
▼
An analysis device includes a separation chamber, a holding channel, a mixing chamber connected to the holding channel, an overflow channel connected between the holding channel and the separation chamber, a sample overflow chamber into which a sample solution remaining in the separation chamber is
An analysis device includes a separation chamber, a holding channel, a mixing chamber connected to the holding channel, an overflow channel connected between the holding channel and the separation chamber, a sample overflow chamber into which a sample solution remaining in the separation chamber is discharged, and a joint channel connecting the separation chamber and the sample overflow chamber. After the separated solution component fills the overflow channel with priority, a separated solid component is transferred to the holding channel via the overflow channel, and a predetermined amount of the solid component is measured. The solid component in the holding channel is transferred to the mixing chamber by a centrifugal force, and simultaneously, the sample solution remaining in the separation chamber is discharged to the sample overflow chamber by the siphon effect of the joint channel.
대표청구항
▼
1. An analysis device for storing and transferring a sample solution to be analyzed, said device comprising: a fluid storage chamber configured to have the sample solution injected and stored therein;a separation chamber configured to separate the sample solution into a solution component and a soli
1. An analysis device for storing and transferring a sample solution to be analyzed, said device comprising: a fluid storage chamber configured to have the sample solution injected and stored therein;a separation chamber configured to separate the sample solution into a solution component and a solid component by applying a centrifugal force generated by rotation of the analysis device;a holding channel configured to have a capillary force for holding a part of the solution component separated by the separation chamber;a first joint channel that joins the separation chamber and the holding channel, the first joint channel configured to have a capillary force;an air hole disposed on a boundary region between the first joint channel and the holding channel;a measurement cell configured to hold the part of the solution component separated by the separation chamber and transferred from the holding channel, the solution component being transferred by an external force;a sample overflow chamber positioned outwardly of the separation chamber with respect to an axial center of the analysis device when the analysis device is rotated around the axial center; anda second joint channel configured and arranged to collect the sample solution other than the part of the solution component into the sample overflow chamber, the second joint channel configured to have a capillary force, and the second joint channel having a siphon structure with a bend portion which is arranged so as to be positioned inwardly of a solution level of the sample solution stored in the separation chamber with respect to the axial center of the analysis device,wherein the solution level corresponds to a predetermined solution level of the sample solution when held in the separation chamber. 2. An analysis device as defined in claim 1 wherein the external force is the centrifugal force that is generated by rotation of the analysis device. 3. An analysis device as defined in claim 2 wherein the external force is a pressure that is generated by introduction of a gas from an air hole provided at a fluid separation position of the holding channel. 4. An analysis device as defined in claim 1 wherein the holding channel is configured to measure the solution to be held by a volume thereof. 5. An analysis device for storing and transferring a sample solution to be analyzed, said device comprising: a fluid storage chamber configured to have the sample solution injected and stored therein;a separation chamber configured to separate the sample solution into a solution component and a solid component by applying a centrifugal force generated by rotation of the analysis device;a holding channel configured to have a capillary force for holding a part of the solid component separated by the separation chamber;a first joint channel that joins the separation chamber and the holding channel, the first joint channel configured to have a capillary force;an air hole disposed on a boundary region between the first joint channel and the holding channel;a measurement cell configured to hold the part of the solid component separated by the separation chamber and transferred from the holding channel, the solid component being transferred by an external force;a sample overflow chamber positioned outwardly of the separation chamber with respect to an axial center of the analysis device when the analysis device is rotated around the axial center; anda second joint channel configured and arranged to collect the sample solution other than the part of the solid component into the sample overflow chamber, the second joint channel configured to have a capillary force, and the second joint channel having a siphon structure with a bend portion which is arranged so as to be positioned inwardly of a solution level of the sample solution stored in the separation chamber with respect to the axial center of analysis device,wherein the solution level corresponds to a predetermined solution level of the sample solution when held in the separation chamber. 6. An analysis device as defined in claim 5 further including a solution component holding channel connected to the separation chamber, for holding a part of the solution component separated from the sample solution in the separation chamber, anda measurement cell configured to hold the solution component filled in the solution component holding channel, mix/react the solution component with a reagent, and measure an absorbance or a turbidity of the mixed solution. 7. An analysis apparatus comprising: the analysis device defined in claim 2; and:a rotation drive device configured to rotate the analysis device around an axial center thereof. 8. An analysis apparatus on which the analysis device defined in claim 3 is mounted, including a rotation drive device configured to rotate the analysis device around an axial center thereof, anda gas introduction mechanism configured to transfer the solution in the analysis device,the rotation drive operable totransfer a sample solution to an outer circumference part of the fluid storage chamber by rotating the analysis device in which the sample solution is stored in the fluid storage chamber,suck the sample solution out of the separation chamber by a capillary force and store the sample solution in the holding channel by stopping the rotation of the analysis device,suck the sample solution out of the separation chamber by a capillary force and store the sample solution in the first joint channel having the siphon structure connected to the sample overflow chamber, andthe gas introduction mechanism configured to connect to the air hole disposed at the fluid separation position of the holding channel, and to the air hole disposed at the boundary region separation chamber, andsupply a gas via the air hole disposed at the boundary region so that the sample solution filled in the holding channel is separated at the fluid separation position and transferred to the measurement cell, and discharge the sample solution in the fluid storage chamber into the sample overflow chamber by the siphon structure of the first joint channel. 9. An analysis device as defined in claim 5 further including: an overflow channel disposed between the holding channel and the first joint channel; andanother overflow chamber connected to the overflow channel. 10. An analysis device as defined in claim 5 wherein another overflow chamber is connected to an overflow channel via a junction part,the holding channel and the overflow channel have a capillary tube size which is capable of generating a capillary flow of fluid, andan opening area of the overflow channel at the junction part between the overflow channel and the another overflow chamber is larger than that of the holding channel. 11. An analysis device as defined in claim 1 wherein the air hole is configured and arranged so as to enable air to enter the air hole and such that the external force is capable of applying pressure at the boundary of the holding channel and the first joint channel thereby transferring a predetermined amount of solution from the holding channel to the measurement cell. 12. An analysis device as defined in claim 1 wherein the second joint channel is configured and arranged to collect the sample solution other than the part of the solution component into the sample overflow chamber so as to prevent the sample solution other than the part of the solution component from entering the first joint channel.
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