Open access spreadsheet application for learning spontaneous breathing mechanics and mechanical ventilation

Part 1: mechanics of the spontaneous breathing cycle

The aim of this practical exercise is to help the student to understand the basis of spontaneous breathing cycle mechanics at rest. It is based on numerical simulation and shows, numerically and graphically, how the elastic and resistive properties of the lungs and rib cage determine the mechanics of the respiratory cycle. The simulation is based on a flow signal, which was recorded with a pneumotachograph in a resting healthy subject breathing spontaneously. A first Introduction worksheet presents the description of the application and poses the questions that the student should answer when proceeding through the exercise. As illustrated in figure 1, worksheets DATA 1 and FIG 2 depict typical baseline values of airway resistance (R_aw=2 cmH₂O·s·L^–1), lung elastance (E_L=5 cmH₂O·L^–1), and chest wall elastance (E_CW=5 cmH₂O·L^–1), the values of the flow signal (V̇) and the corresponding volume (V) computed by V̇ integration. It also presents the time course of alveolar (P_alv=−R_aw· V̇), pleural (P_pl=P_alv–P_L(FRC)–E_L·V), transpulmonary (P_L=P_alv–P_pl) and muscular (P_mus=P_alv–(E_L+E_CW)·V) pressures required to induce the specific ventilation (V̇, V) for the set values of R_aw, E_L and E_CW, by considering that the functional residual capacity (FRC) of the subject is 2.5 L and that the value of P_L at this volume is P_L (FRC)=5 cmH₂O. The student can see the numerical values of the signals at any time in the table in tab DATA 1 or in FIG 1 by placing the tip of the mouse pointer over the corresponding point of the graph.

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Figure 1

Mechanics of the spontaneous breathing cycle (Part 1). a) Screenshot of tab DATA 1 showing baseline values of airway resistance (R_aw), lung elastance (E_L), and chest wall elastance (E_CW), the values of the flow signals: flow (V̇), volume (V), and alveolar (P_alv), pleural (P_pl), transpulmonary (P_L) and muscular (P_mus) pressures. b) Screenshot of tab FIG 2 showing the time course of the signals for baseline parameters (dashed lines) and when R_aw was increased from 2 cmH₂O·s·L^–1 to 10 cmH₂O·s·L^–1 (solid lines). Orange cells allow students to change of their numerical values. See text for explanation.

FIG 2 allows the student to freely modify the value of R_aw, E_L, E_CW and P_L (FRC). This is intended to challenge them to predict how the different pressure signals will change and then to confirm their prediction by comparing the new pressure signals with baseline ones (figure 1b). The student can modify only one respiratory parameter (for instance to model airway obstruction, lung or chest wall restrictions) to observe the specific change induced in each of the pressures, and they can also modify simultaneously several parameter values to observe the combined effect.

Subsequently, tabs FIG 3 to FIG 5 are aimed at challenging the student to determine the values of respiratory parameters from observation of the signals, therefore moving from deductive to inductive reasoning. In the corresponding graphical representations, the different pressures computed after one (or more) parameters has been modified (solid lines) are compared with those of the baseline healthy subject (dashed lines) of tab FIG 2, and the student is asked which of the parameter(s) has been modified in each case.

Part 2: mechanical ventilation

The aim of this practical exercise is to understand the basics of mechanical ventilation by modelling the signals of V̇, V, airway opening pressure (P_ao) and alveolar pressure (P_alv) during mechanical ventilation with tracheal intubation of a patient with an anatomical dead space of 150 mL, alveolar dead space of 7%, and with the respiratory musculature paralysed and the ventilator set to provide constant inspiratory flow. The following parameter values are taken as the baseline: minute ventilation=7 L·min^–1, respiratory rate=10 breaths per min, inspiratory time=2 s, equipment dead space=100 mL and positive end-expiratory pressure (PEEP)=5 cmH₂O. The endotracheal tube has a nonlinear resistance R_et=K₁·V̇ +K₂·V̇², with K₁=1 cmH₂O·s·L^–1 and K₂=5 cmH₂O·(s·L⁻¹)². An Introduction tab describes the application and poses the questions to be answered by the student. The first questions are to determine the values of tidal volume, ratio of inspiratory/expiratory time and alveolar ventilation.

Tab FIG 1 simulates V̇, V, P_alv and P_ao signals in a mechanically ventilated patient without respiratory disease subjected to surgery, with the same baseline values as in Part 1. The student is asked to describe the specific time profile of the signals and to explore their values by placing the tip of the mouse pointer over the point of interest. Tab FIG 2 allows the student to assess the effect of the different parameters in the signals, by first predicting the effects of an up to three-fold increase in R_aw, E_L, and PEEP and subsequently checking their prediction by changing the parameter values in the spreadsheet (figure 2a). The student is also asked to assess the effect of the endotracheal tube by setting K₁=0 and K₂=0.

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Figure 2

Mechanical ventilation (Part 2). a) Screenshot of tab FIG 2 showing the simulated signals of flow, volume and airway opening (P_ao) and alveolar (P_alv) pressures during mechanical ventilation. Dashed and solid lines correspond to the baseline respiratory parameters and when respiratory resistance (R_aw) was increased from 2 cmH₂O·s·L^–1 to 5 cmH₂O·s·L^–1, respectively. b) Screenshot of tab FIG 6 showing the simulated signals of flow, volume and P_ao provided by a conventional ventilator during an end-expiratory occlusion manoeuvre to monitor the patient's respiratory mechanics. Orange cells allow students to change of their numerical values. MV: minute ventilation; f: respiratory rate; T_i: inspiratory time. See text for explanation.

As can be seen in the Introduction worksheet, the student is asked to go into the details of the data and figures to understand the time course of the different signals and their relationship. For instance, to calculate the duration of inspiration and expiration, and the values of respiratory rate, tidal volume and minute ventilation. Also, to analyse whether each of the pressures (P_alv, P_pl, P_L and P_mus) are positive, zero or negative at different times in inspiration and expiration and whether one of the pressures is more positive/negative than another one. Finally, the student is asked to select the signal values at specific points (e.g. beginning/end of inspiration/expiration or points with equal flow/volume) to derive R_aw, E_L and E_CW.

Tabs FIG 3 to FIG 5 simulate mechanical ventilation in patients with single or combined changes in R_aw, E_L, and PEEP and compare the ventilation signals with the baseline ones (tab FIG 1). The student is asked to analyse the changes that occurred during both inspiration and expiration and to answer which of the parameter(s) have been altered in each case. Finally, tabs FIG 6 and DATA 6 simulate the measurement of the patient's mechanics by an end-inspiratory airway occlusion manoeuvre (figure 2b). The student is asked to describe and interpret the time course of signals routinely displayed by ventilators (V̇, V, P_ao) along the manoeuvre and to compute R_aw and the total elastance of the respiratory system (E_RS=E_L + E_CW) before and after correction for the endotracheal tube.