公开(公告)号：US20180177464A1

公开(公告)日：2018-06-28

申请号：US14715793

申请日：2015-05-19

Applicant: Google, Inc.

Inventor： Brian Derek DeBusschere ,  James Moad Reid ,  Jeffrey L. Rogers

IPC: A61B5/00 ,  A61B5/021 ,  A61B5/107 ,  A61B5/0205

CPC classification number: A61B5/7278 ,  A61B5/0013 ,  A61B5/0059 ,  A61B5/0075 ,  A61B5/0077 ,  A61B5/02028 ,  A61B5/0205 ,  A61B5/021 ,  A61B5/02125 ,  A61B5/02416 ,  A61B5/0816 ,  A61B5/1072 ,  A61B5/1079 ,  A61B5/489 ,  A61B5/6898 ,  A61B5/7246 ,  A61B5/725 ,  A61B5/7275 ,  A61B5/7285 ,  A61B5/742 ,  A61B5/7475 ,  A61B2560/0475 ,  A61B2562/0233 ,  A61B2576/00

Abstract: This document describes optical central venous pressure measurement. To determine the central venous pressure (CVP) of a person optically, video of a right side of the person's neck is captured. By way of example, a medical professional records a video of the right side of the person's neck using a smartphone. The right side of the person's neck is captured because it is where the person's external and internal jugular veins are located and pulsatile motions that are usable to measure CVP occur in those veins. The video is then processed according to video motion amplification techniques to generate a reconstructed video of the right side of the person's neck. In the reconstructed video, the pulsatile motion of the person's venous system that occurs at the right side of their neck is visually amplified. Using the reconstructed video, measurements are made of a distance between a peak of the visually-amplified pulsatile motion and an anatomical feature of the person. The measured distance between the peak of the visually-amplified pulsatile motion and the anatomical feature is used to determine CVP of the person. These techniques enable CVP to be determined without relying on estimates made by medical professionals.

公开(公告)号：US10376195B1

公开(公告)日：2019-08-13

申请号：US14731195

申请日：2015-06-04

Applicant: Google, Inc.

Inventor： James M. Reid ,  Jeffrey L. Rogers ,  Brian Derek DeBusschere

IPC: A61B5/0205 ,  A61B5/16 ,  A61B5/01 ,  A61B5/021 ,  A61B5/08 ,  A61B5/024 ,  A61B5/11 ,  A61B3/02 ,  G09B19/00 ,  A61B5/00

Abstract: This document describes automated nursing assessments. Automation of the nursing assessment involves a nursing-assessment device that makes determinations of a person's mood, physical state, psychosocial state, and neurological state. To determine a mood and physical state of a person, video of the person is captured while the person is positioned in front of an everyday object, such as a mirror. The captured video is then processed according to human condition recognition techniques, which produces indications of the person's mood and physical state, such as whether the person is happy, sad, healthy, sick, vital signs, and so on. In addition to mood and physical state, the person's psychosocial and neurological state are also determined. To do so, questions are asked of the person. These questions are determined from a plurality of psychosocial and neurological state assessment questions, which include queries regarding how the person feels, what the person has been doing, and so on. The determined questions are asked through audible or visual interfaces of the nursing-assessment device. The person's responses are then analyzed. The analysis involves processing the received answers according to psychosocial and neurological state assessment techniques to produce indications of the person's psychosocial and neurological state.

公开(公告)号：US20180296163A1

公开(公告)日：2018-10-18

申请号：US14809901

申请日：2015-07-27

Applicant: Google Inc.

Inventor： Brian Derek DeBusschere ,  Jeffrey L. Rogers

IPC: A61B5/00 ,  A61B5/024 ,  A61B5/0205 ,  A61B5/08 ,  A61B5/026 ,  A61B5/11 ,  A61B5/021

Abstract: This document describes ways in which to alter physiological signals to address corrupt, noisy, or otherwise faulty data. By so doing, accuracy and robustness in sensing and assessing a patient's cardiovascular health can be improved. These improved assessments permit better measures of health, such as relevant hemodynamics understood by heart rates, heart rate variability, cardiac arrhythmias, blood pressures, pulse-wave velocities, arterial stiffness, cardiac valve timing, thoracic fluids, ballistocardiogram force, photo-plethysmograms, blood oxygenation, and pressure-volume loops.

公开(公告)号：US20170351827A1

公开(公告)日：2017-12-07

申请号：US15008295

申请日：2016-01-27

Applicant: Google Inc.

Inventor： Jeffrey L. Rogers

IPC: G06F19/00

CPC classification number: G06F19/3418 ,  A61B5/0022 ,  A61B5/01 ,  A61B5/0255 ,  A61B5/0507 ,  A61B5/0816 ,  A61B5/1116 ,  A61B5/1126 ,  A61B5/4566 ,  A61B5/4812 ,  A61B5/4842 ,  A61B5/6891 ,  A61B5/7275 ,  A61B5/747 ,  A61B2505/07 ,  A61B2562/0247 ,  G01S7/415 ,  G01S13/88 ,  G06F19/00 ,  G16H50/30

Abstract: This document describes techniques and apparatuses enabling determination of health state trends for a consistent patient situation. Various noninvasive health monitors can be used to sense a patient's situation and health states, including disease progression, at those states. These noninvasive health monitors may also act passively and in a patient's normal course of life, which enhances many patient's desire to submit to monitoring, as well as increase consistency of use, as in many cases the patient does little or nothing to cause his or her health monitoring and health-trend determination. With health states determined for a consistent patient situation, more accurate and more robust health trends can be determined.

公开(公告)号：US20160338599A1

公开(公告)日：2016-11-24

申请号：US14720632

申请日：2015-05-22

Applicant: Google, Inc.

Inventor： Brian Derek DeBusschere ,  Jeffrey L. Rogers

IPC: A61B5/026 ,  A61B5/021 ,  A61B5/00 ,  A61B5/0265

CPC classification number: A61B5/0261 ,  A61B5/002 ,  A61B5/0077 ,  A61B5/02007 ,  A61B5/02108 ,  A61B5/02416 ,  A61B5/0265 ,  A61B5/0285 ,  A61B5/0295 ,  A61B5/6889 ,  A61B5/6891 ,  A61B5/6892 ,  A61B5/6898 ,  A61B5/7246 ,  G16H40/63

Abstract: This document describes synchronizing cardiovascular sensors for cardiovascular monitoring, such as through sensing relevant hemodynamics understood by pulse transit times, blood pressures, pulse-wave velocities, and, in more breadth, electrical conduction properties, cardiac rhythms, thoracic impedance, ballistocardiograms and pressure-volume loops. The techniques disclosed in this document use various cardiovascular sensors to sense hemodynamics, such as skin color and skin and other organ displacement. These cardiovascular sensors require little if any risk to the patient and are simple and easy for the patient to use.

Abstract translation: 本文件描述了同步用于心血管监测的心血管传感器，例如通过检测脉搏传递时间，血压，脉搏波速度以及更广泛的电传导性质，心律，胸阻抗，圆心电图和压力波的相关血流动力学， 卷循环。 本文中公开的技术使用各种心血管传感器来感测血液动力学，例如皮肤颜色和皮肤以及其他器官位移。 这些心血管传感器对患者的需求很小，对病人来说简单易用。

公开(公告)号：US20160321428A1

公开(公告)日：2016-11-03

申请号：US14699181

申请日：2015-04-29

Applicant: Google, Inc.

Inventor： Jeffrey L. Rogers

IPC: G06F19/00 ,  A61B5/01 ,  A61B5/145 ,  A61B5/024 ,  A61B5/11 ,  A61B5/00 ,  A61B5/021

CPC classification number: G06F19/3456 ,  A61B5/0008 ,  A61B5/01 ,  A61B5/021 ,  A61B5/024 ,  A61B5/11 ,  A61B5/14532 ,  G06F19/3418 ,  G06F19/3481

Abstract: This document describes customizable health monitoring. The techniques described enable a medical professional to monitor a person's health in their normal course of life, such as prior to each meal, during exercising, while at the office, and so forth. These techniques also enable monitoring that is tailored to that particular person to better understand a suspected problem or a known condition. By so doing, a medical professional can monitor a person over various times and situations, which adds detail and robustness to the data collected. The techniques permit remote tracking and data transfer as well, thereby enabling the health professional to gain the desired information quickly and easily without requiring the patient or the health professional to wait for, or waste time on, an in-person visit.

Abstract translation: 本文档描述了可定制的健康监控。 所描述的技术使得医疗专业人员能够在正常的生活过程中监视人的健康状况，例如在每餐之前，锻炼期间，在办公室等等。 这些技术还可以实现针对该特定人员的监控，以更好地了解疑似问题或已知状况。 通过这样做，医疗专业人员可以监控一个人在不同的时间和情况，这增加了收集的数据的细节和鲁棒性。 该技术还允许远程跟踪和数据传输，从而使卫生专业人员能够快速，容易地获得所需信息，而不需要病人或卫生专业人员等待或浪费时间进行亲自访问。

公开(公告)号：US10080528B2

公开(公告)日：2018-09-25

申请号：US14715793

申请日：2015-05-19

Applicant: Google, Inc.

Inventor： Brian Derek DeBusschere ,  James Moad Reid ,  Jeffrey L. Rogers

IPC: A61B5/00 ,  A61B5/021 ,  A61B5/107 ,  A61B5/0205 ,  A61B5/024 ,  A61B5/08

CPC classification number: A61B5/7278 ,  A61B5/0013 ,  A61B5/0059 ,  A61B5/0075 ,  A61B5/0077 ,  A61B5/02028 ,  A61B5/0205 ,  A61B5/021 ,  A61B5/02125 ,  A61B5/02416 ,  A61B5/0816 ,  A61B5/1072 ,  A61B5/1079 ,  A61B5/489 ,  A61B5/6898 ,  A61B5/7246 ,  A61B5/725 ,  A61B5/7275 ,  A61B5/7285 ,  A61B5/742 ,  A61B5/7475 ,  A61B2560/0475 ,  A61B2562/0233 ,  A61B2576/00

Abstract: This document describes optical central venous pressure measurement. To determine the central venous pressure (CVP) of a person optically, video of a right side of the person's neck is captured. By way of example, a medical professional records a video of the right side of the person's neck using a smartphone. The right side of the person's neck is captured because it is where the person's external and internal jugular veins are located and pulsatile motions that are usable to measure CVP occur in those veins. The video is then processed according to video motion amplification techniques to generate a reconstructed video of the right side of the person's neck. In the reconstructed video, the pulsatile motion of the person's venous system that occurs at the right side of their neck is visually amplified. Using the reconstructed video, measurements are made of a distance between a peak of the visually-amplified pulsatile motion and an anatomical feature of the person. The measured distance between the peak of the visually-amplified pulsatile motion and the anatomical feature is used to determine CVP of the person. These techniques enable CVP to be determined without relying on estimates made by medical professionals.

公开(公告)号：US20180000355A1

公开(公告)日：2018-01-04

申请号：US15704825

申请日：2017-09-14

Applicant: Google Inc.

Inventor： Brian Derek DeBusschere ,  Jeffrey L. Rogers

IPC: A61B5/0205 ,  A61B5/021 ,  A61B5/00 ,  A61B5/024 ,  A61B5/11 ,  A61B5/103

CPC classification number: A61B5/0205 ,  A61B5/0077 ,  A61B5/0082 ,  A61B5/021 ,  A61B5/02125 ,  A61B5/02427 ,  A61B5/02433 ,  A61B5/0261 ,  A61B5/1032 ,  A61B5/1102

Abstract: This document describes assessing cardiovascular function using an optical sensor, such as through sensing relevant hemodynamics understood by pulse transit times, blood pressures, pulse-wave velocities, and, in more breadth, ballistocardiograms and pressure-volume loops. The techniques disclosed in this document use various optical sensors to sense hemodynamics, such as skin color and skin and other organ displacement. These optical sensors require little if any risk to the patient and are simple and easy for the patient to use.

公开(公告)号：US20160206244A1

公开(公告)日：2016-07-21

申请号：US14599954

申请日：2015-01-19

Applicant: Google, Inc.

Inventor： Jeffrey L. Rogers

IPC: A61B5/00 ,  A61B5/0205 ,  A61B5/103 ,  A61B5/021

CPC classification number: A61B5/6891 ,  A47K13/30 ,  A61B5/0022 ,  A61B5/01 ,  A61B5/02028 ,  A61B5/0205 ,  A61B5/021 ,  A61B5/0255 ,  A61B5/0402 ,  A61B5/05 ,  A61B5/1032 ,  A61B5/1102 ,  A61B5/1126 ,  A61B5/40 ,  A61B5/42 ,  A61B5/441 ,  A61B5/45 ,  A61B5/4509 ,  A61B5/4528 ,  A61B5/4842 ,  A61B5/6892 ,  A61B5/6898 ,  A61B5/7246 ,  A61B5/7275 ,  A61B5/742 ,  A61B5/746 ,  A61B5/747 ,  A61B5/7475 ,  A61B8/06 ,  A61B8/0875 ,  A61B8/0883 ,  A61B8/14 ,  A61B8/4477 ,  A61B8/483 ,  A61B2505/07 ,  A61B2562/0204 ,  A61B2562/0233 ,  A61B2562/0247 ,  G01K11/006 ,  G06F19/00

Abstract: This document describes the assessment of human physiological systems in a manner that can be applied throughout the population. Various noninvasive sensors (including wearable, passive contact, and noncontact) can be used to detect vitals and other parameters and combined with mathematical models to assess the functional state of physiological systems. For example, the health of the cardiovascular system is ultimately determined by organ blood perfusion and molecular gas exchange. In lieu of measuring these functional metrics directly, invasive sensors can be used to monitor cardiac pressures and volumes, along with pressure transit through the vascular to quantify cardiovascular health. While known to be effective these invasive techniques often require surgery and are resource intensive limiting their use to the few cases where the risks and costs are of clear immediate benefit. In contrast, noninvasive health monitors present little if any risk to the person and are simple and easy for the person to use. Further, the techniques described herein can determine trends in a person's cardiovascular health. With these trends, a person can know if the effort they are expending to improve their heart health is actually making a difference. Further, negative trends can be found that can spur people to improve their health or to get medical attention. By so doing, these techniques may reduce mortality.

Abstract translation: 本文件以可应用于整个人群的方式描述人体生理系统的评估。 各种无创传感器（包括可穿戴式，无源接触式和非接触式）可用于检测生物体和其他参数，并结合数学模型来评估生理系统的功能状态。 例如，心血管系统的健康最终由器官血液灌注和分子气体交换决定。 代替直接测量这些功能指标，侵入性传感器可用于监测心脏压力和体积，以及通过血管的压力传递以量化心血管健康。 虽然这些侵入性技术是有效的，但是这些侵入性技术通常需要手术，并且是资源密集型的，将其用于限制风险和成本明显立即获益的少数情况。 相比之下，非侵入性健康监护人对人的风险很小，对人来说简单易用。 此外，本文描述的技术可以确定人的心血管健康的趋势。 有了这些趋势，一个人可以知道他们为改善心脏健康而付出的努力是否真的有所改变。 此外，可以发现可以促使人们改善健康或得到医疗照顾的负面趋势。 通过这样做，这些技术可以降低死亡率。

公开(公告)号：US10216905B2

公开(公告)日：2019-02-26

申请号：US15008295

申请日：2016-01-27

Applicant: Google Inc.

Inventor： Jeffrey L. Rogers

IPC: G06F19/00 ,  A61B5/0255 ,  A61B5/05 ,  A61B5/08 ,  A61B5/11 ,  A61B5/00 ,  G01S13/88 ,  G01S7/41 ,  G16H50/30 ,  A61B5/01

Abstract: This document describes techniques and apparatuses enabling determination of health state trends for a consistent patient situation. Various noninvasive health monitors can be used to sense a patient's situation and health states, including disease progression, at those states. These noninvasive health monitors may also act passively and in a patient's normal course of life, which enhances many patient's desire to submit to monitoring, as well as increase consistency of use, as in many cases the patient does little or nothing to cause his or her health monitoring and health-trend determination. With health states determined for a consistent patient situation, more accurate and more robust health trends can be determined.