Simple ventilators for emergency use based on Bag-Valve pressing systems: Lessons learned and future steps

As part of a plethora of global efforts to minimize the negative effects of the SARS-CoV2 (COVID-19) pandemic, we developed two different mechanisms that, after further development, could potentially be of use in the future in order to increase the capacity of ventilators with low-cost devices based on single-use-bag-valve mask systems. We describe the concept behind the devices and report a characterization of them. Finally, we make a description of the solved and unsolved challenges and propose a series of measures in order to better cope with future contingencies.


Introduction
The international health contingence caused by the rapid propagation of the SARS-CoV2 (COVID-19) has triggered an unprecedented type of collaborative and distributed development worldwide. From professional scientists, physicians and engineers in universities, research institutions and companies to individuals with home-based electronics and mechanics building capabilities have started intensive brainstorming, prototyping, re-engineering and testing of potential solutions to multiple aspects of the pandemic.
Taking into account the experience gained in China and Italy, two of the earliest and most affected countries by the pandemic so far, it is clear that a key piece of equipment required at hospitals are mechanical ventilators and that the number of available ventilators is insufficient with regard to the potential numbers needed in most countries worldwide. 1 On 13.03.2020, we decided to start an emergency project to develop and evaluate the potential of a platform for low-cost, easy-to-build ventilators to cope with the potential shortage of ventilators worldwide. During the following days, an interdisciplinary group was formed including people with backgrounds in Physics, Engineering, Informatics, Medicine, etc. to shape up ideas. Quickly two approaches were chosen, prototypes started to be built, tested and optimized for performance and reliability. In this contribution we present two ventilator prototypes of the most basic approach which are based on the use of a Bag-Valve manual ventilator.
The design framework shown here consists of the aspects of low cost design, easy modification of widespread standard components, or at least easy to manufacture, and basic ventilator capacity. In addition, we enumerate challenges pending to be solved for this concept to be converted into a real solution. It is worth mentioning that while we have tried to include as many of the options and to meet characteristics similar to a professional mechanical ventilator, our objective was to build a simplified, easy-and economical-to-build apparatus that, when fully developed, could potentially be of benefit to patients in need for mechanical ventilation in a circumstance in which no other option can be offered. We also want to make a clear statement that the devices presented here: equipment only. No clinical or preclinical trials have been conducted or approved up to the date of this publication.
3. We strongly discourage any attempt to use the devices presented here on humans. Its replication should only be for the purpose of further investigation and development.
Manually pumped ventilators have been used in the past to cope with epidemic-related patient surges. 2 It is also good noticing that pushing mechanisms for a bag-valve ventilator is an approach that has been pursued by various groups around the world both in the past, mostly as an academic exercise. [3][4][5] Yet, in recent days many groups around the world have taken this concept as a possibility to cope with the current crisis [6][7][8][9] . It is worth mentioning that our designs might have similarities and face similar deficiencies to other bag-valve pushing mechanisms. For some of those developments detailed construction schematics and other detailed information have been made available to the public.

Design considerations
While the use of mechanical ventilation is a clinical practice that is normally only used on patients that require it as a life-sustaining measure, inappropriate ventilation of a patient could result in damage to the lungs that would also be lifethreatening. [10][11][12] The breathing process might seem a relatively simple one at first glance. To first approximation it is not very different to inflating and deflating a balloon, however, that simplistic view is what physicists would call a spherical-cowapproximation. There are a number of subtleties that make respiration more complex. In the following, we provide a brief description of the breathing process based on 13 . Under normal circumstances, inhalation is driven by the unconscious motion of a series of muscles, mainly the diaphragm as the key muscle together with different other muscle groups of the chest wall, that increase the volume of the thoracic cavity. This leads to a decrease of the pressure in the lungs which, at its time, results in the flow of fresh air into the lungs through the airway. The subsequent relaxation of said muscles increases the pressure in the lungs that produces the exhalation. Therefore inhalation is usually produced by "negative" thoracic pressure, while exhalation is produced by "positive" thoracic pressure. When mechanical ventilation is applied, usually through an endotracheal tube, the inhalation is no longer driven by negative pressure produced by the patient, but by positive pressure provided by the ventilator that "forces" air into lungs, this is a complete game-changer in many senses. For instance, natural "negative" pressure inspiration can not over inflate the lungs and its internal ramified structures, the alveoli, which can potentially be damaged by overpressure when "positive" pressure is applied. This could lead to damage of the lung, which is usually already compromised by the underlying condition, such as pneumonia caused by COVID-19. Therefore, the volume per inspiration (tidal volume) and the appropriate pressures across the breathing cycle must be limited.
Unlike healthy subjects, who maintain a small volume of air in the lungs once the exhalation is over, critical patients in some cases produce a full exhalation, this causes the fluids that are in the lung to completely fill all the cavities, which means that it is more difficult to inflate the lung again in the following breath cycle, and making it more prone to injury by the mechanical ventilation, therefore, a minimal positive pressure (Positive End-Expiratory Pressure; PEEP) should be maintained in the lung at the end of the expiration in order to prevent the collapse of the lungs. It is worth mentioning that bag-valve resuscitators are single-use-products, thus, for each new patient, a new resuscitator is needed. Yet, hygienic standards are easy to follow, as the two mechanism prototypes themselves are not part of the pneumatic system itself. In addition, a connecting hose between the bag-valve system and the mask or endotracheal tube will be needed, which is normally not used in manual resuscitation. The total volume of that hose has to be significantly smaller than the tidal volume pumped in order to ensure appropriate exhaustion of the exhaled CO 2 to the atmosphere.
In addition to the purely pneumatic considerations, there are other aspects to be taken into account. For instance, forcing air into the lungs of a patient at a rate determined by the ventilator instead of the natural rhythm determined by the patient is extremely uncomfortable and requires deep sedation, which might complicate other aspects of the progress evaluation and treatment of the patient. Hence, a feedback mechanism, usually by pressure or flow, is desirable in order to trigger the breath cycle of the ventilator and thus improve the patient-ventilator synchrony. Furthermore the gas used for ventilation should be enriched in oxygen content (FiO 2 ) since the lung capacity of the patient is diminished, and ideally the gas mixture should be humidified and warmed-up since the endotracheal tube bypasses the upper part of the airway (nose & pharynx), which usually performs these two functions.
During the four weeks that the prototyping process took in our group, we tried to incorporate as many of the desirable characteristics as possible to our prototypes, however, each degree of sophistication increases the cost of the device, the fabrication time and most importantly the potential failure points. In the face of the contingence careful reliability tests can not be thoroughly performed for appropriately long periods. In Table 1 the typical setting parameters for a mechanical ventilator are shown 14

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Prototype 1 (Contingence Life-support Air Pressure Emergency Respirator; CLAPER)
The first approach we demonstrate here was the construction of a bag-valve pusher that would be able to operate in continuous mode without the requirement of digital control, at least for a first simplified version, even if it did not meet all the ideal requirements. The system consists of a motor that drives a small gear, which at its time drives two larger gears coupled to each other in order for them to move synchronously but in opposite directions. The two gears have an additional eccentric axis that is used to move a coupling rod each, which moves an oscillatory arm which is fixed at one end to the baseplate of the mechanical system. A convex piece is attached to the other end of the arm which is used to press the bag-valve at regular intervals. The position of the fixed point of the arm can be varied and this provides the user with control over the tidal volume. The positions are well depicted in Fig. 6 in the methods section. The frequency can be varied as well by changing the voltage supplied to the motor. The ensemble is shown in Fig. 1. However, the inclusion of a microcontroller opens the possibility of controlling not only the breathing frequency and the volume pumped, but the inspiration/expiration time ratio, pressure limits, and pressure/flow triggers. Measurements of pressure and flow were performed on the CLAPER device in order to quantify its performance and decide if it is within the expected parameters for a mechanical ventilator as described in the Methods section. The measurement results are shown in Fig. 2. The tests were performed using the different positions of the pivot in order to have some control over the tidal volume pumped which is a parameter that needs to be controlled for its use. Fig. 2(a) shows the time evolution of the pressure along 4 breathing cycles for various positions of the pivot. The points in Fig. 2(b) show the peak pressure achieved for the different pivot positions, showing that peak pressures between 8.9 and 25.9 cm H 2 O were achieved. Fig. 2(c) shows the evolution of the flow for the breathing cycle and the peak inspiratory and expiratory flows are shown in panel (d). From those measurements it is possible to obtain the evolution of the volume pumped, which is shown in Fig. 2(e). The peak values of 3/12 . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity.

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The copyright holder for this preprint this version posted May 5, 2020. .  Table 1. that evolution, shown in Fig. 2(f) are the tidal volumes that were achieved for the different positions of the pivot, in this same plot we included gray boxes that depict the tidal volume ranges for patients of different predicted-body-weights which are labeled for each box as a reference. As observed in the plot, by varying the positions it is possible to modulate the tidal volume stepwise for patients from about 30 kg to about 100 kg.
An additional test that was carried out is to measure the maximum obtainable pressure from the system. It is important to mention that this is related to the motor used. In particular we drive our prototype with a ∼60 RPM that can deliver a maximum torque of 180 N cm. If a stronger motor is used, that will provide a higher maximum pressure, and vice versa. The measurement was carried out by blocking the outlet of the system, which gives the same effect as an infinitely stiff lung, the maximum pressure we achieved under the given conditions was 44.8 cm H 2 O, which is comparable to commercially available ventilator settings.

Prototype 2 (experimental Actuated Resuscitator Machine; eARM)
The second approach is based on a simpler mechanical design. The mechanism consists of two arms that squeeze the bag-valve resuscitator, which is placed between them. The motion of the arms is driven by a string that is attached to a string role driven by a motor. Once the resuscitator is squeezed, the direction in which the motor is rotating has to be reversed. In the simplest case, this can be achieved using a microswitch, which marks the end position and relays, which switch the polarity of the voltage applied to a DC motor. A more advanced approach, which we present here, includes using a microcontroller and an H-bridge to invert the motion of a DC motor. Placing two microswitches at the two ends of the arms' travel, in the initial (open) and final positions (closed), enables positional feedback to a microcontroller. By changing the position of the microswitch, which indicates the final (closed) state, the pressure and tidal volume can be tuned. The use of a microcontroller enables the control and monitoring of the breathing rate, inspiration to expiration ratio, and opens the possibility to implement complex feedback-based controls (e.g. PEEP control, triggered inspiration). A render of the prototype is shown in Fig. 3.
Measurements of pressure and flow were also performed on the eARM using the same equipment as for CLAPER as describen in the Methods section. An additional tube of approximately 2 m length and 1 cm in diameter was used for connecting the test lung to the bag-valve resuscitator. An additional valve from another bag-valve resuscitator was placed between the tube and the test lung, in order to prevent "exhaled" air from residing in the tube and being "inhaled" with the next inspiration. The tests measurements were performed at five different positions of the microswitch indicating the final (closed) position in order to control the tidal volume. The breathing rate was set to 20 BPM and the inspiration to expiration ratio to 1:1. The measurement results are shown in Fig. 4. In the left part of Fig. 4 the time evaluation of pressure, flow, and volume are shown over 4 breathing cycles for the five positions of the microswitch. The average of the peak pressure, peak volume, and peak inspiratory and expiratory flow for each position of the microswitch are shown in the right part of Fig. 4. Since both prototypes rely on a bag 4/12 . CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity.

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The copyright holder for this preprint this version posted May 5, 2020. . Figure 5. Measurements performed in order to demonstrate the additional features that can be implemented relatively easily with a digital control and a pressure sensor. Respiration rate was set to 15 BPM with inspiration to expiration ratio set to 1:2.
The system was also set to trigger a breathing cycle in case of a potential inspiration (marked in gray) and to maintain PEEP, which was done with an additional mechanical PEEP valve and pressure dependent motor control. valve resuscitator, a similar outcome of the test measurements was expected and also achieved. As a microcontroller is already used for this prototype, an additional pressure sensor was installed. This way we were able to show the potential of such a device to also control PEEP as well as potential for triggered inspiration (Augmented spontaneous breathing [ASB] mode). The test measurements with the implemented pressure control are shown in Fig. 5.

Discussion and Conclusions
The performance shown by the two prototypes for the "core" characteristics are comparable to professional ventilators, however there are also some characteristics that are not implemented such as special sequences that help physicians evaluate the state of the patient. The volumes and pressures achieved during the tests are consistent with the clinical requirements, and both systems permit controlling the volumes and breathing rates within the ranges normally used in intensive care units, of course there are still challenges to be overcome in future research: 1. Reliability of the mechanisms, software, etc.: Since these were fast track developments, there has not been enough time to undergo appropriate long term reliability tests on these pieces of equipment. Although we did run tests for several days on both prototypes, appropriate tests for weeks or months under realistic operation conditions are still needed and will require a significant amount of time, incompatible with the urgent requirement of ventilators to deal with the ongoing international crisis.
2. Mass production with appropriate standards: Given that the concept of the devices presented here with the necessary adjustments for industrial production are expected to become medical equipment, the fabrication has to be performed in appropriate industrial environments with the necessary manufacture equipment and by trained personnel. In addition appropriate quality control has to be implemented. Once again, it is not clear how this could be done in a timely manner to face the COVID-19 pandemic.
3. Regulatory approval or exemption: Being medical equipment, the use of the devices presented here, or variations around them, requires appropriate approval by the health regulatory agencies of the different countries that intend to use them. Such a process is, under normal circumstances, time consuming, involves a significant amount of bureaucratic paperwork and financial investment, not to mention extensive preclinical and clinical trials. While some countries, such as the USA have issued a declaration of "liability immunity for activities related to medical countermeasures against COVID-19", 15 most countries have not taken similar measures, therefore, the use of these devices depends either on the creation of similar policies of general application, or the expedited approval of specific devices.

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Additional features:
In addition to the central characteristics such as volumes, pressures, etc. required from a professional mechanical ventilator, there are a number of other characteristics that need to be met. For instance, the system has to be enclosed in an easy-to-clean fluid spill resistant casing, it requires battery support for the case of a power cut or for patient transportation, among other characteristics. The possibility to provide real-time pressure, flow and volume plots on a screen is also a characteristic that would be desirable as well as the possibility to program other inhalation/exhalation sequences that are of use for clinicians as diagnostic tools.
In conclusion, we believe that our two proof-of-concept approaches to re-engineer and upscale simple low cost manual bag-valve-systems to a low-cost ventilator were successful and provide what promises, after further development, be of benefit to patients in need of mechanical ventilation in the absence of other options. However, a number of questions remain open and this implies the need of reliability tests, clinical trials, as well as fulfilling regulatory and legal formalities. Furthermore, significant commitment from companies that can manufacture them, or even military industry, will be needed if these concepts are to be converted into real solutions within a reasonable timescale. An important aspect is that, perhaps for the first time a global collection of efforts appeared spontaneously in a very short period, and not only to address the mechanical ventilator availability problem, but many other aspects, yet most of these efforts were disorganized and the convergence of the emergencydevelopment, emergency-manufacture and emergency-legal/regulatory-clearance do not seem to be converging at appropriate speeds to deal with the problem. These aspects will need to be addressed in order to better respond to future crises.

Pressure and volume measurements
The measurements were performed by inflating a calibrated MAQUET test lung 190 for a maximum tidal volume of 1l, all the tests were conducted using normal atmospheric air at room temperature and pressure. A calibrated digital flow and pressure measurement system was used for the characterization. CLAPER prototype Figure 6. Schematic representation of the baseplate. Sizes shown are just for reference and have not been optimized. The design will require adjustments.

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The copyright holder for this preprint this version posted May 5, 2020. .   . Schematic representation of the bag-pusher. Sizes shown are just for reference and have not been optimized. The design will require adjustments.

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The copyright holder for this preprint this version posted May 5, 2020.   Design considerations: 1. A flexible and strong string is required (e.g. braided nylon cord), which should be able to carry enough weight, depending on the pressure which is to be achieved.

2.
A spiral form in the string roll (see Figure 12) reduces jitter from string rolling up badly. Choosing a sufficient r2, in a way that squeezing is achieved in only a few turns, also helps avoiding jitter.
3. The string roll should enable easy installation/attachment of the string (e.g. twice through a hole in the string role).
4. An attachment on the arms (b2) helps pressing the bag-valve resuscitator while leaving space for the string roll (g > 2r2) 5. To avoid potential damages of the bag-valve resuscitator at the maximum squeezing, an additional space between the arms (dg) should be left.

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. CC-BY 4.0 International license It is made available under a is the author/funder, who has granted medRxiv a license to display the preprint in perpetuity. (which was not certified by peer review) The copyright holder for this preprint this version posted May 5, 2020. . https://doi.org/10.1101/2020.04.29.20084749 doi: medRxiv preprint 6. Movable microswitches make setting up the device easier. The tunable position of the upper microswitch is essential for a manual volume and pressure control.
7. Two microswitches are needed to monitor and set respiration rate and inspiration to expiration ratio. Also if 1:1 ratio is the goal, keep in mind that opening and closing times differ.
8. Since bag-valve resuscitators are not designed for continuous long-term use, their characteristics and material can deteriorate with time. Regular rechecking and if necessary replacement are advised. Therefore, a design enabling relatively easy and quick replacement of it should be realized. 9. Arm length (l), spacing between the two rotational axis (d), bag-valve resuscitator position (h), string roll radius (r) and accordingly a motor with appropriate characteristics (torque, rpm) have to be chosen in a way, that the squeezing process runs smoothly with the desired pace while reaching the desired pressure and volume.
10. By increasing l, the motor's leverage also increases, if h stays unchanged. This means that a motor with less torque could perform the squeezing. However, in this case the end points of the arms have to travel a greater distance from released to squeezed state, meaning that the motor has to rotate faster at the same r2 of the string role to maintain the same rate of squeezing (BPM). By increasing the r2, the speed of the motor could be kept unchanged, however, this would cancel out the leverage gained by increasing l. Nevertheless, these relations allow for some tunability of the design according to the needs. Figure 12. Schematic of the eARM system with arms in the maximum compression position. The design will require adjustments.

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