公开(公告)号：US09157116B2

公开(公告)日：2015-10-13

申请号：US12866018

申请日：2009-02-09

Applicant: Kenneth J. Livak ,  Marc Unger

Inventor： Kenneth J. Livak ,  Marc Unger

IPC: C12P19/34 ,  C12Q1/68

CPC classification number: C12Q1/686 ,  C12Q1/6834 ,  C12Q2565/629

Abstract: High throughput methods are used that combine the features of using a matrix-type microfluidic device, labeled nucleic acid probes, and homogenous assays to detect and/or quantify nucleic acid analytes. The high throughput methods are capable of detecting nucleic acid analyes with high PCR and probe specificity, producing a low fluorescence background and therefore, a high signal to noise ratio. Additionally, the high throughput methods are capable of detecting low copy number nucleic acid analyte per cell.

Abstract translation: 使用高通量方法，其结合使用基质型微流体装置，标记的核酸探针和均质测定的特征来检测和/或定量核酸分析物。 高通量方法能够以高PCR和探针特异性检测核酸分析，产生低荧光背景，因此具有高的信噪比。 此外，高通量方法能够检测每个细胞的低拷贝数核酸分析物。

公开(公告)号：US20130171633A1

公开(公告)日：2013-07-04

申请号：US13548068

申请日：2012-07-12

Applicant: Lincoln McBride ,  Geoffrey Facer ,  Marc Unger ,  Michael Lucero ,  Hany Ramez Nassef

Inventor： Lincoln McBride ,  Geoffrey Facer ,  Marc Unger ,  Michael Lucero ,  Hany Ramez Nassef

IPC: C12Q1/68

CPC classification number: C12Q1/68 ,  B01L3/0248 ,  B01L3/5025 ,  B01L3/5027 ,  B01L3/502707 ,  B01L3/502715 ,  B01L3/50273 ,  B01L3/502738 ,  B01L7/52 ,  B01L2200/0642 ,  B01L2200/10 ,  B01L2200/142 ,  B01L2200/147 ,  B01L2300/06 ,  B01L2300/0636 ,  B01L2300/0816 ,  B01L2300/0819 ,  B01L2300/0861 ,  B01L2300/0864 ,  B01L2300/0867 ,  B01L2300/0874 ,  B01L2300/123 ,  B01L2300/1805 ,  B01L2400/0481 ,  B01L2400/0487 ,  B01L2400/06 ,  B01L2400/0638 ,  B01L2400/0655 ,  C12Q1/686 ,  G01N27/453

Abstract: An M×N matrix microfluidic device for performing a matrix of reactions, the device having a plurality of reaction cells in communication with one of either a sample inlet or a reagent inlet through a via formed within an elastomeric block of the device. Methods provided include a method for forming vias in parallel in an elastomeric layer of an elastomeric block of a microfluidic device, the method comprising using patterned photoresist masks and etching reagents to etch away regions or portions of an elastomeric layer of the elastomeric block.

Abstract translation: 一种用于执行反应矩阵的M×N矩阵微流体装置，所述装置具有多个反应池，其通过形成在装置的弹性体块内的通孔与样品入口或试剂入口之一连通。 提供的方法包括在微流体装置的弹性体块的弹性体层中平行形成通孔的方法，该方法包括使用图案化的光致抗蚀剂掩模和蚀刻试剂来蚀刻掉弹性体块的弹性体层的区域或部分。

公开(公告)号：US07867454B2

公开(公告)日：2011-01-11

申请号：US11929370

申请日：2007-10-30

Applicant: Federico Goodsaid ,  Marc Unger ,  Jiang Huang ,  Emerson Quan

Inventor： Federico Goodsaid ,  Marc Unger ,  Jiang Huang ,  Emerson Quan

IPC: B01L3/00

CPC classification number: B01L3/00 ,  B01L3/0248 ,  B01L3/5025 ,  B01L3/5027 ,  B01L3/502707 ,  B01L3/502715 ,  B01L3/50273 ,  B01L3/502738 ,  B01L7/52 ,  B01L2200/0642 ,  B01L2200/142 ,  B01L2200/147 ,  B01L2300/0636 ,  B01L2300/0816 ,  B01L2300/0819 ,  B01L2300/0861 ,  B01L2300/0864 ,  B01L2300/0867 ,  B01L2300/123 ,  B01L2300/1805 ,  B01L2400/0481 ,  B01L2400/0487 ,  B01L2400/0638 ,  B01L2400/0655 ,  C12Q1/686 ,  G01N27/453

Abstract: An M.times.N matrix microfluidic device for performing a matrix of reactions, the device having a plurality of reaction cells in communication with one of either a sample inlet or a reagent inlet through a via formed within an elastomeric block of the device. Methods provided include a method for forming vias in parallel in an elastomeric layer of an elastomeric block of a microfluidic device, the method comprising using patterned photoresist masks and etching reagents to etch away regions or portions of an elastomeric layer of the elastomeric block.

Abstract translation: 一种用于执行反应矩阵的M.times.N矩阵微流体装置，该装置具有多个反应池，其通过形成在装置的弹性体块内的通孔与样品入口或试剂入口之一连通。 提供的方法包括在微流体装置的弹性体块的弹性体层中平行形成通孔的方法，该方法包括使用图案化的光致抗蚀剂掩模和蚀刻试剂来蚀刻掉弹性体块的弹性体层的区域或部分。

公开(公告)号：US20100120038A1

公开(公告)日：2010-05-13

申请号：US12548132

申请日：2009-08-26

Applicant: Alain Mir ,  Ramesh Ramakrishnan ,  Marc Unger ,  Bernhard G. Zimmermann

Inventor： Alain Mir ,  Ramesh Ramakrishnan ,  Marc Unger ,  Bernhard G. Zimmermann

IPC: C12Q1/68 ,  G01N33/48

CPC classification number: C12Q1/686 ,  C12N15/1065 ,  C12Q1/6853 ,  Y10T436/143333 ,  C12Q2537/143 ,  C12Q2525/161

Abstract: The present invention provides assay methods that increase the number of samples and/or target nucleic acids that can be analyzed in a single assay.

Abstract translation: 本发明提供了增加可以在单次测定中分析的样品和/或靶核酸数量的测定方法。

公开(公告)号：US20090257920A1

公开(公告)日：2009-10-15

申请号：US12422612

申请日：2009-04-13

Applicant: Geoffrey Facer ,  Brian Fowler ,  Emerson Cheung Quan ,  Marc Unger

Inventor： Geoffrey Facer ,  Brian Fowler ,  Emerson Cheung Quan ,  Marc Unger

IPC: B01L3/00 ,  G05D11/02

CPC classification number: F16K99/0015 ,  B01F5/02 ,  B01F13/0059 ,  B01L3/502707 ,  B01L3/502738 ,  B01L2200/10 ,  B01L2200/12 ,  B01L2200/16 ,  B01L2300/0627 ,  B01L2300/0816 ,  B01L2300/0874 ,  B01L2300/0887 ,  B01L2300/123 ,  B01L2400/0481 ,  B01L2400/0638 ,  B33Y80/00 ,  C12Q1/686 ,  F16K99/0026 ,  F16K99/0059 ,  F16K2099/008 ,  F16K2099/0084 ,  G01N2021/0346 ,  Y10T137/0329 ,  Y10T137/2164 ,  Y10T137/2169 ,  Y10T137/2559 ,  Y10T137/2655 ,  Y10T137/2688 ,  Y10T137/87249

Abstract: Multilevel microfluidic devices include a control line that can simultaneously actuate valves for both sample and reagent lines. Microfluidic devices are configured to contain a first reagent in a first chamber and a second reagent in a second chamber, where either or both of the first and second reagents are contained at a desired or selected pressure. Operation of a microfluidic device includes transmitting second reagent from the second chamber to the first chamber, for mixing or contact with the first reagent. Microfluidic device features such as channels, valves, chambers, can be at least partially contained, embedded, or formed by or within one or more layers or levels of an elastomeric block.

Abstract translation: 多级微流体装置包括一个控制管线，可同时为样品和试剂管线起动阀门。 微流体装置被配置为在第二室中的第一室和第二试剂中含有第一试剂，其中第一试剂和第二试剂中的任一种或两者以所需或选择的压力包含。 微流体装置的操作包括将第二试剂从第二室传输到第一室，用于与第一试剂混合或接触。 诸如通道，阀，腔室的微流体装置特征可以至少部分地包含，嵌入或由弹性体块的一个或多个层或层形成或形成。

公开(公告)号：US20080292504A1

公开(公告)日：2008-11-27

申请号：US11929370

申请日：2007-10-30

Applicant: Federico Goodsaid ,  Marc Unger ,  Jiang Huang ,  Emerson Quan

Inventor： Federico Goodsaid ,  Marc Unger ,  Jiang Huang ,  Emerson Quan

IPC: G01N21/64 ,  B01J19/00

CPC classification number: B01L3/00 ,  B01L3/0248 ,  B01L3/5025 ,  B01L3/5027 ,  B01L3/502707 ,  B01L3/502715 ,  B01L3/50273 ,  B01L3/502738 ,  B01L7/52 ,  B01L2200/0642 ,  B01L2200/142 ,  B01L2200/147 ,  B01L2300/0636 ,  B01L2300/0816 ,  B01L2300/0819 ,  B01L2300/0861 ,  B01L2300/0864 ,  B01L2300/0867 ,  B01L2300/123 ,  B01L2300/1805 ,  B01L2400/0481 ,  B01L2400/0487 ,  B01L2400/0638 ,  B01L2400/0655 ,  C12Q1/686 ,  G01N27/453

Abstract: An M.times.N matrix microfluidic device for performing a matrix of reactions, the device having a plurality of reaction cells in communication with one of either a sample inlet or a reagent inlet through a via formed within an elastomeric block of the device. Methods provided include a method for forming vias in parallel in an elastomeric layer of an elastomeric block of a microfluidic device, the method comprising using patterned photoresist masks and etching reagents to etch away regions or portions of an elastomeric layer of the elastomeric block.

Abstract translation: 一种用于执行反应矩阵的M.times.N矩阵微流体装置，该装置具有多个反应池，其通过形成在装置的弹性体块内的通孔与样品入口或试剂入口之一连通。 提供的方法包括在微流体装置的弹性体块的弹性体层中平行形成通孔的方法，该方法包括使用图案化的光致抗蚀剂掩模和蚀刻试剂来蚀刻掉弹性体块的弹性体层的区域或部分。

公开(公告)号：US20080230387A1

公开(公告)日：2008-09-25

申请号：US11929625

申请日：2007-10-30

Applicant: Lincoln McBride ,  Marc Unger ,  Michael Lucero ,  Hany Ramez Nassef ,  Geoffrey Facer

Inventor： Lincoln McBride ,  Marc Unger ,  Michael Lucero ,  Hany Ramez Nassef ,  Geoffrey Facer

IPC: G01N27/26

CPC classification number: B01L3/00 ,  B01L3/5027 ,  B01L3/502723 ,  B01L3/502738 ,  B01L7/52 ,  B01L2200/0642 ,  B01L2200/142 ,  B01L2200/147 ,  B01L2300/0816 ,  B01L2300/0861 ,  B01L2300/123 ,  B01L2400/0481 ,  B01L2400/0638 ,  C12Q1/686

Abstract: A variety of elastomeric-based microfluidic devices and methods for using and manufacturing such devices are provided. Certain of the devices have arrays of reaction sites to facilitate high throughput analyses. Some devices also include reaction sites located at the end of blind channels at which reagents have been previously deposited during manufacture. The reagents become suspended once sample is introduced into the reaction site. The devices can be utilized with a variety of heating devices and thus can be used in a variety of analyses requiring temperature control, including thermocycling applications such as nucleic acid amplification reactions, genotyping and gene expression analyses.

Abstract translation: 提供了各种基于弹性体的微流体装置和用于使用和制造这种装置的方法。 某些设备具有反应位置阵列以便于高通量分析。 一些装置还包括位于盲制通道末端的反应位置，在制造过程中试剂已经预先沉积。 一旦将样品引入反应部位，试剂就会悬浮。 该装置可以与各种加热装置一起使用，因此可用于需要温度控制的各种分析，包括热循环应用，如核酸扩增反应，基因分型和基因表达分析。

公开(公告)号：US07291512B2

公开(公告)日：2007-11-06

申请号：US11316282

申请日：2005-12-21

Applicant: Marc Unger

Inventor： Marc Unger

IPC: H01L21/00

CPC classification number: H01L21/00 ,  B01L3/0241 ,  B01L3/5025 ,  B01L3/502707 ,  B01L3/502738 ,  B01L2300/0816 ,  B01L2300/0887 ,  B01L2400/0481 ,  B01L2400/0655 ,  F04B43/043 ,  F16K99/0001 ,  F16K99/0015 ,  F16K99/0051 ,  F16K99/0053 ,  F16K99/0059 ,  F16K2099/0074 ,  F16K2099/0078 ,  F16K2099/008

Abstract: A valve structure comprises an elastomeric block formed with first and second microfabricated recesses separated by a membrane portion of the elastomeric block. The valve is actuated by positioning a compliant electrode on a first side of the first recess proximate to and in physical communication with the membrane. Where the valve is to be electrostatically actuated, a second electrode is positioned on a second side of the first recess opposite the first side. Application of a potential difference across the electrodes causes the compliant electrode and the membrane to be attracted into the flow channel. Where the valve is to be electrostrictively actuated, a second electrode is positioned on the same side of the recess as the compliant electrode. Application of a potential difference across the electrodes causes the electrodes to be attracted such that elastomer membrane portion material between them is compressed and bows into the flow channel. Either of the electrostrictively or the electrostatically-actuated valve structures may include an electrically-conducting fluid in the second recess to serve as the compliant electrode.

Abstract translation: 阀结构包括由弹性体块的膜部分分开的第一和第二微细加工凹部形成的弹性体块。 通过将顺应性电极定位在第一凹部的靠近膜并且与膜物理连通的第一侧上来致动阀。 在阀被静电致动的地方，第二电极位于与第一侧相对的第一凹槽的第二侧上。 在电极之间施加电位差使得柔性电极和膜被吸引到流动通道中。 在阀被电致伸缩的情况下，第二电极位于与顺应性电极相同的凹槽侧。 在电极之间施加电位差导致电极被吸引，使得它们之间的弹性体膜部分材料被压缩并弯曲到流动通道中。 电致伸缩阀或静电致动阀结构中的任何一个可以包括在第二凹槽中用作柔性电极的导电流体。

公开(公告)号：US20060099116A1

公开(公告)日：2006-05-11

申请号：US11302605

申请日：2005-12-13

Applicant: Ian Manger ,  Cunsheng Hao ,  Marc Unger

Inventor： Ian Manger ,  Cunsheng Hao ,  Marc Unger

IPC: B01L3/00

CPC classification number: G01N1/10 ,  B01L3/0241 ,  B01L3/5027 ,  B01L3/502707 ,  B01L3/502715 ,  B01L3/50273 ,  B01L2200/027 ,  B01L2300/0816 ,  B01L2300/0887 ,  B01L2400/0481 ,  G01N30/7266 ,  H01J49/0018 ,  H01J49/165 ,  Y10T436/117497 ,  Y10T436/24 ,  Y10T436/25 ,  Y10T436/25125 ,  Y10T436/25375 ,  Y10T436/2575

Abstract: This invention provides microfluidic devices and methods for using the same. Microfluidic devices of the present invention comprises a first elastic layer, a fluid flow channel within the elastic layer; and a means for providing a fluid sample from the fluid flow channel to an analytical device. The present invention also provides an analytical apparatus comprising such a microfluidic device and an analytical device.

Abstract translation: 本发明提供了微流体装置及其使用方法。 本发明的微流体装置包括第一弹性层，弹性层内的流体流动通道; 以及用于将流体样品从流体流动通道提供到分析装置的装置。 本发明还提供一种包括这种微流体装置和分析装置的分析装置。

公开(公告)号：US20060000513A1

公开(公告)日：2006-01-05

申请号：US11213598

申请日：2005-08-26

Applicant: David Fernandes ,  Hou-Pu Chou ,  Marc Unger

Inventor： David Fernandes ,  Hou-Pu Chou ,  Marc Unger

IPC: F15C3/00

CPC classification number: F15C3/00 ,  A61M2206/22 ,  B01L3/502707 ,  B01L3/50273 ,  B01L3/502738 ,  B01L2200/0621 ,  B01L2200/14 ,  B01L2300/123 ,  B01L2400/0487 ,  B01L2400/0638 ,  B01L2400/0655 ,  F15C3/04 ,  F16K99/0001 ,  F16K99/0009 ,  F16K99/0015 ,  F16K99/0034 ,  F16K99/0059 ,  F16K2099/0074 ,  F16K2099/008 ,  F16K2099/0082 ,  F16K2099/0084 ,  G06F17/509 ,  G06F2217/16 ,  H01H2029/008 ,  Y10T137/206 ,  Y10T137/2202 ,  Y10T137/2218 ,  Y10T137/2224 ,  Y10T137/7879 ,  Y10T137/7891 ,  Y10T137/7892

Abstract: The present invention provides microfabricated fluidic systems and methods. Microfabricated fluidic devices of the present invention include switches that can be opened and closed to allow or block the flow of fluid through a channel in response to the pressure level in a gate of the switch. The microfabricated fluidic switches may be coupled together to perform logic functions and Boolean algebra, such as inverters, AND gates, NAND, gates, NOR gates, and OR gates. The logic gates may be coupled together to form flip-flops that latch signals. The present invention also includes microfabricated fluidic pressure multipliers that increase the pressure in a second chamber relative to a first chamber. Microfabricated fluidic devices of the present invention also include pressure sources. A pressure source of the present includes a pump coupled to a reservoir through unidirectional valves. The pressure source may be high pressure source or a low pressure source. Microfabricated fluidic devices of the present invention may also include devices that perform analog functions such as switching regulator.