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Chinese Journal of Critical Care & Intensive Care Medicine(Electronic Edition) ›› 2019, Vol. 05 ›› Issue (03): 249-257. doi: 10.3877/cma.j.issn.2096-1537.2019.03.009

Special Issue:

• Basic Science Researches • Previous Articles     Next Articles

An analysis of the flow-time curves in the super early phase of expiration on mechanical ventilation

Yunzhen Wu1,()   

  1. 1. Department of Critical Care Medicine, Dongying People′s Hospital, Dongying 257091, China
  • Received:2018-05-10 Online:2019-08-28 Published:2019-08-28
  • Contact: Yunzhen Wu
  • About author:
    Corresponding author: Wu Yunzhen, Email:

Abstract:

Objective

To analyze the respiratory state of patients receiving mechanical ventilation by analyzing the shapes and influence factors of flow-time curve in the super early phase of expiration.

Methods

Two test lungs with different compliance (C) and two tubes with different resistance (R) were prepared. Four combinations were developed with one test lung coupled with one tube. The test lungs and tubes were then connected to a PB840 ventilator. The start points of expiratoration (the end point of inspiration) were set in three scenarios with different ventilation mode. First: different circuit pressure (Pc0) and same alveolar pressure (Pa0) and PEEP. Second case: different Pa0 and same Pc0 and PEEP. Third: different PEEP and same Pc0 and Pa0. The characteristics of the flow-time curves were observed. The effects of Pc0, Pa0, PEEP, C and R on the flow-time curves were also observed.

Results

1.Two key points determined the morphological characteristics of flow-time curves in the super early phase. One was the point of peak flow (the maximum expiratory flow, V1). The other was the break point (the intersection point between the rapid decline and slow decline of flow volume, V4). 2. (1) The higher Pc0 was, the greater V1 was, when the C, R, Pa0, and PEEP were kept the same. (2) The higher Pa0 was, the greater V1 and V4 were, when the C, R, Pc0, and PEEP were kept the same. However, the degree of V4 rise is less than V1 rise. (3) The higher PEEP was, the smaller V1 and V4 were, when C, R, Pc0, and Pa0 were kept the same. (4) The greater R was, the smaller V1 and V4 were, when C,Pc0, Pa0, and PEEP were kept the same. (5) V1 and V4 did not change obviously when C changed, and Pc0, Pa0 and PEEP were kept the same.

Conclusion

The pressure of the circuit and the pressure of the alveolus at the end of inspiration affect the peak expiratory flow positively. But PEEP and the airway resistance do negatively. The pressure of the alveolus at the end of inspiration affects the break expiratory flow positively. But the PEEP value and airway resistance do negatively. The airway resistance affects the distance between the peak point and the break point positively. But the compliance does negatively.

Key words: Mechanical ventilation, Flow-time curve, Pressure-time curve, Lung compliance, Airway resistance

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