公开(公告)号：US20140236630A1

公开(公告)日：2014-08-21

申请号：US14181907

申请日：2014-02-17

Applicant: STC.UNM

Inventor： Glen H. Murata

IPC: G06Q50/22 ,  G06Q10/06

CPC classification number: G06Q50/22 ,  G06Q10/06398

Abstract: System and methods for collecting, sharing and analyzing data of Electronic Medical Records (EMRs) for improved health analytics. Quality of health care delivery is assessed and improved through use of data from EMRs. For example, data may be analyzed for a variety of purposes, including to determine variation in performance of a practice site, a group practice, or an individual clinician for the patient population on a given treatment or to identify a risk of disease for patients of the patient population.

Abstract translation: 收集，共享和分析电子病历数据（EMR）数据的系统和方法，以改善健康分析。 通过使用EMR的数据来评估和改进卫生保健服务的质量。 例如，为了各种目的，可以分析数据，包括确定在给定治疗时患者群体的实践部位，组实践或个体临床医生的性能变化，或者确定患者的疾病风险 病人人数。

公开(公告)号：US08785226B2

公开(公告)日：2014-07-22

申请号：US14032904

申请日：2013-09-20

Applicant: STC.UNM

Inventor： Seung Chang Lee ,  Steven R. J. Brueck

IPC: H01S5/10 ,  H01S5/323 ,  H01S5/343 ,  H01L21/00

CPC classification number: H01L21/02603 ,  B82Y10/00 ,  B82Y40/00 ,  B82Y99/00 ,  H01L21/0237 ,  H01L21/02439 ,  H01L21/02507 ,  H01L21/02521 ,  H01L21/02639 ,  H01L29/0665 ,  H01L29/0673 ,  H01L29/127 ,  H01L29/158 ,  H01L29/7783 ,  H01L29/7853 ,  H01L33/06 ,  H01L33/18 ,  H01S5/32 ,  Y10S977/951 ,  Y10S977/962

Abstract: Exemplary embodiments provide semiconductor nanowires and nanowire devices/applications and methods for their formation. In embodiments, in-plane nanowires can be epitaxially grown on a patterned substrate, which are more favorable than vertical ones for device processing and three-dimensional (3D) integrated circuits. In embodiments, the in-plane nanowire can be formed by selective epitaxy utilizing lateral overgrowth and faceting of an epilayer initially grown in a one-dimensional (1D) nanoscale opening. In embodiments, optical, electrical, and thermal connections can be established and controlled between the nanowire, the substrate, and additional electrical or optical components for better device and system performance.

Abstract translation: 示例性实施例提供用于其形成的半导体纳米线和纳米线器件/应用和方法。 在实施例中，平面内纳米线可以在图案化衬底上外延生长，其比用于器件处理和三维（3D）集成电路的垂直纳米线更有利。 在实施方案中，可以通过使用最初在一维（1D）纳米尺度开口中生长的外延层的横向过生长和刻面的选择性外延来形成平面内纳米线。 在实施例中，可以在纳米线，衬底和附加电气或光学部件之间建立和控制光学，电气和热连接，以获得更好的器件和系统性能。

公开(公告)号：US08698494B2

公开(公告)日：2014-04-15

申请号：US13776580

申请日：2013-02-25

Applicant: STC.UNM

Inventor： Laurel Sillerud ,  Todd M. Alam ,  Andrew F. McDowell

IPC: G01V3/00

CPC classification number: G01R33/32 ,  B82Y15/00 ,  G01N24/08 ,  G01N33/54326 ,  G01N33/553 ,  G01R33/281 ,  G01R33/302 ,  G01R33/34007 ,  G01R33/34046 ,  G01R33/34092 ,  G01R33/341 ,  G01R33/465 ,  G01R33/5601

Abstract: A biological detector includes a conduit for receiving a fluid containing one or more magnetic nanoparticle-labeled, biological objects to be detected and one or more permanent magnets or electromagnet for establishing a low magnetic field in which the conduit is disposed. A microcoil is disposed proximate the conduit for energization at a frequency that permits detection by NMR spectroscopy of whether the one or more magnetically-labeled biological objects is/are present in the fluid.

Abstract translation: 生物检测器包括用于接收含有一个或多个待纳入检测体的磁性纳米颗粒标记的生物体的流体的导管，以及一个用于建立其中设置导管的低磁场的永磁体或电磁体。 微线圈靠近导管设置，以允许通过NMR光谱法检测流体中是否存在一个或多个磁性标记的生物体的频率。

公开(公告)号：US20140086795A1

公开(公告)日：2014-03-27

申请号：US14092409

申请日：2013-11-27

Applicant: STC.UNM ,  University of Florida Research Foundation, Inc.

Inventor： Kirk S. Schanze ,  Motokatsu Ogawa ,  Jonathan Robert Sommer ,  David G. Whitten ,  Thomas S. Corbitt

IPC: A01N25/28 ,  A61L2/23

CPC classification number: A01N25/28 ,  A01N25/00 ,  A01N25/10 ,  A01N25/34 ,  A01N43/90 ,  A61L2/23 ,  Y10S977/712 ,  Y10S977/903 ,  Y10T428/2982 ,  A01N41/04 ,  A01N2300/00

Abstract: Hollow conjugated polyelectrolyte (HCPE) microcapsules contain at least one conjugated polyelectrolyte and at least one other polyelectrolyte of complementary charge and the microcapsule has a hollow core. The conjugated polyelectrolyte is a polymer with a multiplicity of charged repeating units where a portion of the charged repeating units form a pi-conjugated sequence. The complementary polyelectrolyte is a polymer with a complementary charged repeating unit to the charged repeating units of the conjugated polyelectrolyte. The HCPE microcapsules can be formed by successively coating a sacrificial core with alternating layers of complementary polyelectrolytes, at least one of which is a conjugated polyelectrolyte. The sacrificial core can be removed to form the hollow center of a HCPE microcapsule. The HCPE microcapsules can be contacted with a medium containing microbes where the HCPE microcapsules associate with the microbes and efficiently kill the microbes when irradiated with light or other electromagnetic radiation.

Abstract translation: 中空共轭聚电解质（HCPE）微胶囊含有至少一种共轭聚电解质和至少一种其他互补电荷的聚电解质，微胶囊具有中空芯。 共轭聚电解质是具有多个带电重复单元的聚合物，其中一部分带电重复单元形成π-共轭序列。 互补聚电解质是与共轭聚电解质的带电重复单元具有互补的带电重复单元的聚合物。 HCPE微胶囊可以通过连续地涂覆具有互补聚电解质交替层的牺牲芯形成，其中至少一种是共轭聚电解质。 可以去除牺牲芯以形成HCPE微胶囊的中空中心。 HCPE微胶囊可以与含有微生物的培养基接触，其中HCPE微胶囊与微生物结合，并在用光或其他电磁辐射照射时有效杀死微生物。

公开(公告)号：US11981789B2

公开(公告)日：2024-05-14

申请号：US16647404

申请日：2018-09-17

Applicant: STC.UNM ,  Sang Eon Han ,  Sang M. Han

Inventor： Sang Eon Han ,  Sang M. Han

IPC: G01N21/47 ,  B82Y40/00 ,  C08J9/26 ,  G01N21/27 ,  G01N23/2202 ,  G01N23/2251 ,  G02B5/02 ,  G06T7/50 ,  H01J37/26

CPC classification number: C08J9/26 ,  B82Y40/00 ,  G01N21/278 ,  G01N23/2202 ,  G01N23/2251 ,  G02B5/0268 ,  G06T7/50 ,  H01J37/26 ,  G02B2207/109

Abstract: A method and resulting device that mimics the light scattering properties of a random structural pattern using microspheres.

公开(公告)号：US11517858B2

公开(公告)日：2022-12-06

申请号：US16903608

申请日：2020-06-17

Applicant: National Technology & Engineering Solutions of Sandia, LLC ,  STC.UNM

Inventor： Hongyou Fan ,  Susan Rempe ,  Ying-Bing Jiang

IPC: B01D69/02 ,  B01D71/80 ,  B01D69/10 ,  B01D67/00

Abstract: A nanoporous polymer membrane with vertically aligned pore channels can be synthesized through self-assembly of amphiphilic block copolymers on a supporting substrate. The pore surface chemistry can be functionalized for selective anion transport.

公开(公告)号：US11491215B2

公开(公告)日：2022-11-08

申请号：US16543463

申请日：2019-08-16

Applicant: LAWRENCE LIVERMORE NATIONAL SECURITY, LLC ,  STC.UNM

Inventor： Nicholas Fischer ,  Amy Rasley ,  Terry Wu ,  Julie Lovchik

IPC: A61K39/02 ,  A61K39/39 ,  B82Y5/00 ,  A61K39/00

Abstract: Provided herein are antigenic combinations and related compositions, methods and systems for immunizing a host from an infection caused by Francisella bacterium. The antigenic combination comprises an antigenic polysaccharide component from a Francisella bacterium capable of triggering a humoral immune response in an individual, a protein antigen component from the Francisella bacterium capable of triggering a cellular immune response in the individual, and an adjuvant, the antigenic Francisella polysaccharide component, the Francisella protein antigen component and the adjuvant are in a suitable amount to immunize an individual against the Francisella bacterium.

公开(公告)号：US11066592B2

公开(公告)日：2021-07-20

申请号：US16607356

申请日：2018-04-20

Applicant: STC.UNM ,  Michael S. Stenko ,  Edward N. Matteo ,  Thomas Dewers

Inventor： Mahmoud Reda Taha ,  Michael S. Stenko ,  John Stormont ,  Edward N. Matteo ,  Moneeb Genedy ,  Thomas Dewers

IPC: E21B33/14 ,  C09K8/42 ,  B82Y30/00

Abstract: A method and sealant to seal microcracks as small as 30 μm by causing methyl methacrylate combined with one or more nanoparticles to flow into the microcrack to be sealed.

公开(公告)号：US11060989B2

公开(公告)日：2021-07-13

申请号：US16431264

申请日：2019-06-04

Applicant: National Technology & Engineering Solutions of Sandia, LLC ,  STC.UNM

Inventor： David T. Hanson ,  Philip Rocco Miller ,  Ronen Polsky ,  Patrick J. Hudson ,  Kaitlyn J. H. Read

IPC: G01N27/02 ,  G01N33/00

Abstract: A sensor uses microneedle electrodes and multi-frequency electrical impedance spectroscopy to monitor plant water status in real time. The microneedle can be between 10 and 1000 microns in length, enabling precise placement in a variety of plant tissues. The impedance behavior can distinguish electrical properties and physiological functions of different plant tissue types. Therefore, impedance measurements can be used to monitor water stress to prevent irreversible damage to a plant and to enable improvement of plant biomass or fruit yield.

公开(公告)号：US20210151953A1

公开(公告)日：2021-05-20

申请号：US16081028

申请日：2017-02-28

Applicant: STC.UNM

Inventor： Marek Osinski ,  Gennady A. Smolyakov

IPC: H01S5/10 ,  H01S5/40 ,  H01S5/12 ,  H01S5/0225 ,  H01S5/02 ,  H01S5/026

Abstract: The present invention provides one or more injection-lockable whistle-geometry semiconductor ring lasers, which may be cascaded, that are integrated on a common silicon-on-insulator (SOI) substrate with a single-frequency semiconductor master laser, wherein the light output from the semiconductor master laser is used to injection-lock the first of the semiconductor ring lasers. The ring lasers can be operated in strongly injection-locked mode, while at least one of them is subjected to direct injection current modulation.