The Experts below are selected from a list of 86853 Experts worldwide ranked by ideXlab platform
Jing Jeng - One of the best experts on this subject based on the ideXlab platform.
-
the advanced health and disaster aid network a light weight wireless medical system for Triage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
-
The advanced health and disaster aid network: A light-weight wireless medical system for tiage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
Tia Gao - One of the best experts on this subject based on the ideXlab platform.
-
the advanced health and disaster aid network a light weight wireless medical system for Triage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
-
The advanced health and disaster aid network: A light-weight wireless medical system for tiage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
Victor Shnayder - One of the best experts on this subject based on the ideXlab platform.
-
the advanced health and disaster aid network a light weight wireless medical system for Triage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
-
The advanced health and disaster aid network: A light-weight wireless medical system for tiage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
Logan Hauenstein - One of the best experts on this subject based on the ideXlab platform.
-
the advanced health and disaster aid network a light weight wireless medical system for Triage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
-
The advanced health and disaster aid network: A light-weight wireless medical system for tiage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
Bor-rong Chen - One of the best experts on this subject based on the ideXlab platform.
-
the advanced health and disaster aid network a light weight wireless medical system for Triage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
-
The advanced health and disaster aid network: A light-weight wireless medical system for tiage
IEEE Transactions on Biomedical Circuits and Systems, 2007Co-Authors: Tia Gao, Foad Dabiri, Victor Shnayder, Tammara Massey, Konrad Lorincz, Bor-rong Chen, Logan Hauenstein, David Crawford, Leo Selavo, Jing JengAbstract:Advances in semiconductor technology have resulted in the creation of miniature medical embedded systems that can wirelessly monitor the vital signs of patients. These lightweight medical systems can aid providers in large disasters who become overwhelmed with the large number of patients, limited resources, and insufficient information. In a mass casualty incident, small embedded medical systems facilitate patient care, resource allocation, and real-time communication in the advanced health and disaster aid network (AID-N). We present the design of electronic Triage tags on lightweight, embedded systems with limited memory and computational power. These electronic Triage tags use noninvasive, biomedical sensors (pulse oximeter, electrocardiogram, and blood pressure cuff) to continuously monitor the vital signs of a patient and deliver pertinent information to first responders. This electronic Triage system facilitates the seamless collection and dissemination of data from the incident site to key members of the distributed emergency response community. The real-time collection of data through a mesh network in a mass casualty drill was shown to approximately triple the number of times patients that were Triaged compared with the traditional paper Triage system.
