1.A study on clinical applications of the PAV ventilation.
Chinese Journal of Medical Instrumentation 2007;31(4):293-294
This article analyses the principle of the PAV, researches into its clinical applications, estimates its merits and demerits, and discusses the new ventilation mode in contrast with the old ones.
Humans
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Respiration, Artificial
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methods
2.Breathing waveform and respiratory ring in the role of mechanical ventilation.
Chinese Journal of Medical Instrumentation 2010;34(2):143-145
To learn reading respiratory waveform and ring is a key step to good use of respirator, which will help clinicians to analyze the status of the use of respirator and real time changes in patient's lung mechanics from the changes of respiratory wave and ring, for making use of respirator reasonably, scientifically and objectively to provide advanced methods. This article only explains the physical basis of respiratory wave and ring.
Respiration
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Respiration, Artificial
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methods
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Respiratory Mechanics
3.Research on modeling and simulation of the system of position transformation mechanical ventilation.
Ji-ping XU ; Zai-wen LIU ; Xiao-yi WANG
Chinese Journal of Medical Instrumentation 2009;33(6):402-406
The principle of Position Transformation Mechanical Ventilation (PTMV) was introduced briefly, and the mechanical structure and the intelligent control algorithm were studied. According to the principle and function requirement of PTMV, the mechanical structure of slip pole driven rocking chair(SPDRC) was proposed, the dynamics model of SPDRC was established, and the auto disturbance rejection controller was designed. The integrated model of control system was structured by using ADAMS and MATLAB, and the model validation and simulation were implemented. The simulation results indicate that the mechanical structure is feasible and the control process of ADRC is precise and steady.
Algorithms
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Models, Biological
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Posture
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Respiration, Artificial
;
methods
4.Common ventilation modes of respiration machines and adjustment of parameters.
Chinese Journal of Medical Instrumentation 2009;33(1):64-66
The summary of common ventilation modes is presented in the paper. Characteristics, work principle, the advantage on the clinical application and parameter adjustment are analyzed to help users overcome the clinical difficulty using respirators.
Humans
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Pulmonary Ventilation
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Respiration, Artificial
;
methods
5.Respiratory support and treatment of severe inhalation injury.
Chinese Journal of Burns 2013;29(2):134-138
Although the study of inhalation injury is deepening gradually, its clinical treatment is still difficult, and its mortality rate remains high due to the complicated pathophysiologic characteristics. This article reviews the recent progress in research and treatment of inhalation injury, acute lung injury, and acute respiratory distress syndrome at home and abroad, focusing on the effect of mechanical ventilation models, including the non-invasive ventilation, lung protective ventilation, liquid ventilation, high frequency ventilation, on respiratory support in early stage of inhalation injury. The effects of medications for inhalation injury are summarized, and the prospect of stem cell therapy for inhalation injury is also discussed.
Burns, Inhalation
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therapy
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Humans
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Respiration, Artificial
;
methods
6.Researches on the mechanical ventilation trigger way.
Chinese Journal of Medical Instrumentation 2008;32(2):137-141
A mechanical ventilation trigger way is set forth and a technical analysis on the pressure trigger way and flow trigger way is made in this paper. And it is pointed out that the PEEPi's influence on the human organism is the reason for the latter two kinds of trigger ways' notable differences in the measured values of the inspiration time and breath work.
Humans
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Positive-Pressure Respiration
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Respiration, Artificial
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methods
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Work of Breathing
7.Modeling the noninvasive bi-level positive airway pressure ventilation therapy system and simulated application.
Yueyang YUAN ; Li ZHOU ; Haoxuan HUANG ; Wei LIU ; Xingshuo HU ; Lixin XIE
Journal of Biomedical Engineering 2023;40(2):343-349
Without artificial airway though oral, nasal or airway incision, the bi-level positive airway pressure (Bi-PAP) has been widely employed for respiratory patients. In an effort to investigate the therapeutic effects and measures for the respiratory patients under the noninvasive Bi-PAP ventilation, a therapy system model was designed for virtual ventilation experiments. In this system model, it includes a sub-model of noninvasive Bi-PAP respirator, a sub-model of respiratory patient, and a sub-model of the breath circuit and mask. And based on the Matlab Simulink, a simulation platform for the noninvasive Bi-PAP therapy system was developed to conduct the virtual experiments in simulated respiratory patient with no spontaneous breathing (NSB), chronic obstructive pulmonary disease (COPD) and acute respiratory distress syndrome (ARDS). The simulated outputs such as the respiratory flows, pressures, volumes, etc, were collected and compared to the outputs which were obtained in the physical experiments with the active servo lung. By statistically analyzed with SPSS, the results demonstrated that there was no significant difference ( P > 0.1) and was in high similarity ( R > 0.7) between the data collected in simulations and physical experiments. The therapy system model of noninvasive Bi-PAP is probably applied for simulating the practical clinical experiment, and maybe conveniently applied to study the technology of noninvasive Bi-PAP for clinicians.
Humans
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Respiration, Artificial/methods*
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Positive-Pressure Respiration/methods*
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Respiration
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Ventilators, Mechanical
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Lung
8.Design of a noninvasive ventilator's turbine.
Ya-Xu ZHOU ; Zhao-Yan HU ; Min ZHAN ; Bin GE ; Hai-Ming XIE
Chinese Journal of Medical Instrumentation 2008;32(2):97-82
The design principles of a noninvasive ventilator's turbine are studied and discussed in this paper. The design is completed from its several aspects and in combination of related theories, using SolidWorks tools. Abundant experimental results prove that this design's technical specifications meet all the requirements.
Equipment Design
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Respiration, Artificial
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instrumentation
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methods
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Ventilators, Mechanical
9.Tracheostomy.
Journal of Clinical Otorhinolaryngology Head and Neck Surgery 2015;29(17):1581-1586
Tracheostomy is to establish an artificial airway by making an opening at anterior tracheal wall. Due to the blossom of mechanical ventilation and intensive care unit after 1950s, tracheostomy is the most favorable surgical method to access airway at present. In addition to traditional surgical tracheostomy, percutaneous dilational tracheostomy have gained increasing popularity and become an alternative procedure because of its merits such as easier manipulation, shorter operative duration and less complications. This review summarized tracheostomy from definition, history and current status, anatomy and physiology, indications, contraindications, timing, complications and management. We also elaborate our understanding of current contraercy and give some suggestions based on our clinical experience.
Humans
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Intensive Care Units
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Respiration, Artificial
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Trachea
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surgery
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Tracheostomy
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methods
10.Mechanical ventilation in acute respiratory distress syndrome.
Chinese Journal of Contemporary Pediatrics 2013;15(6):496-501
The goal of mechanically ventilating patients with acute respiratory distress syndrome (ARDS) is to ensure adequate oxygenation and minimal ventilator-associated lung injury. Non-invasive ventilation should be cautiously used in patients with ARDS. Protective ARDS mechanical ventilation strategies with low tidal volumes can reduce mortality. Driving pressure is the most reasonable parameter to optimize tidal volume. Available evidence does not support the routine use of higher positive end expiratory pressure (PEEP) in patients with ARDS. The optimal level of PEEP may be titrated by the inflection point obtained from static pressure-volume curve. Promising therapies include prone position ventilation, high frequency oscillatory ventilation and extracorporeal membrane oxygenation as salvage treatment. While mechanically ventilating, it is also important for ARDS patients to maintain spontaneous breathing via assisted ventilation mode such as bilevel positive airway pressure, pressure support ventilation and neurally adjusted ventilation assist. Exogenous surfactant, inhaled nitric oxide, bronchodilators, airway pressure release ventilation and partial liquid ventilation are not recommended therapies.
Humans
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Positive-Pressure Respiration
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Respiration, Artificial
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methods
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Respiratory Distress Syndrome, Adult
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therapy
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Tidal Volume