key: cord-0713895-3zzie91h
authors: Rebelo, Tiago; Neutel, Elizabete; Alves, Eurico Castro; Barros, Francisco; Oliveira, Hélder; Machado, Humberto; Mendonça, Joana; Araújo, João Fortuna; Luís, João; Pêgo, José M.; Silva, José; Oliveira, Manuel; Sousa, Nuno; Figueiredo, Paulo; Barata, Pedro; Magalhães, Raquel Silva; Magalhães, Rui Miguel; Gomes, Sara H.
title: ATENA–A Novel Rapidly Manufactured Medical Invasive Ventilator Designed as a Response to the COVID-19 Pandemic: Testing Protocol, Safety, and Performance Validation
date: 2021-08-19
journal: Front Med (Lausanne)
DOI: 10.3389/fmed.2021.614580
sha: 8587c0a6fd49b1788c4e3113c8a89860eadbfbb3
doc_id: 713895
cord_uid: 3zzie91h

Background: The urgent need for mechanical ventilators to support respiratory insufficiency due to SARS-CoV-2 led to a worldwide effort to develop low-cost, easily assembled, and locally manufactured ventilators. The ATENA ventilator project was developed in a community-based approach targeting the development, prototyping, testing, and decentralized manufacturing of a new mechanical ventilator. Objective: This article aims to demonstrate ATENA's adequate performance and safety for clinical use. Material: ATENA is a low-cost ventilator that can be rapidly manufactured, easily assembled, and locally produced anywhere in the world. It was developed following the guidelines and requirements provided by European and International Regulatory Authorities (MHRA, ISO 86201) and National Authorities (INFARMED). The device was thoroughly tested using laboratory lung simulators and animal models. Results: The device meets all the regulatory requirements for pandemic ventilators. Additionally, the pre-clinical experiences demonstrated security and adequate ventilation and oxygenation, in vivo. Conclusion: The ATENA ventilator had a good performance in required tests in laboratory scenarios and pre-clinical studies. In a pandemic context, ATENA is perfectly suited for safely treating patients in need of mechanical ventilation.

The global pandemic Coronavirus Disease 2019 (COVID- 19) caused by SARS-CoV-2 created an urgent need for mechanical ventilators around the world (1) . Even though the majority of patients develop mild (40%) or moderate (40%) symptoms, ∼15% develop a severe condition that requires oxygen support and 5% end up with respiratory failure and need intensive care admission (2) (3) (4) .

The exponential pattern of viral transmission led to a rapid and overwhelming increase in hospitalizations and overflow to intensive care units for invasive ventilation. At the beginning of 2020, the number of available ventilators was scarce and contributed to a significant increase in morbimortality worldwide (5) (6) (7) . The fight against the global COVID-19 pandemic required innovative actions. Globally, thousands of experts, companies, and volunteers worked to fill the global shortage of commercial ventilators, by developing open-source ventilators or finding strategies (8) (9) (10) (11) (12) for shared ventilation (13, 14) . Likewise, in Portugal, CEiiA-an Engineering and Product Development Centre-led (15) the development of the ATENA ventilator in a community-based approach.

ATENA is a rapidly manufactured, low-cost, easily assembled, and locally produced mechanical invasive ventilator. It was developed in a short time, from design to prototype. The requirements for the ATENA ventilator were common to other proposals (11, 16) : (i) easily sourced components available to the general public; (ii) "open-source" compatibility, namely, availability of design and easiness to replicate; and (iii) high accuracy in a range of ventilation strategies that allow high airway pressures for ARDS patients.

This paper aims to demonstrate the performance and safety of ATENA as a pandemic ventilator adequate for COVID-19 patients, following the requirements of different regulatory agencies.

Overview ATENA is a pneumatic ventilator, requiring high-pressure air and oxygen supplies to drive the respiratory cycles. Its control system hardware was locally designed, based on commercially available and inexpensive components. The software was developed in-house.

The main body is built using a stainless-steel wheeled structure and four sealed metal industrial boxes. These boxes are attached on each side of the structure (see Figure 1 ). They contain the pneumatic, electrical, and control modules. ATENA's overall specifications are described in Table 1 (see also  Supplementary Table 1) .

The two upper boxes contain the respiratory circuit, with the required valves and sensors, and the control system. Gases in the respiratory circuit are at low pressure (<60 cmH 2 O). One of the lower housing boxes handles the input of air and oxygen at high pressure (>3 bar). The other contains the power module, composed of a battery, transformers, and safety fuses and breakers.

A touch screen displays pressure, flow, and volume curves in addition to other important ventilation variables (see Figures 3A,C) . Ventilation modes and parameters are configurable via the touch screen ( Figure 3B ). Operation is started/stopped by pressing a physical button on the front of the ventilator.

Alarms are signaled by sound, light, and a specific alarm text on the display (see the top bar in Figure 3A ). Alarms need to be acknowledged and muted by pressing another physical button.

Ventilation mode and parameters are configured via the touch display. Figure 3B shows the VCV (volume-controlled ventilation) mode configuration screen. Other modes are visible as extra tabs. Once the operation mode is selected and configured, ventilation can be started by pressing the START/STOP button next to the display. Air and oxygen enter the system at a pressure of about 4.5 bar (air and O 2 inlets are indicated in Figure 2 ). To ensure adequate availability of oxygen for each inhalation, we installed a 0.75-L buffer tank after the oxygen inlet. Pressure is monitored via pressure sensors in each of the high-pressure circuits to detect any fault in the gas supply. Such faults trigger an alarm. These pressures can be checked on the ventilator display ( Figure 3C) .

Piezo-electric valves on the air and oxygen lines control the flow and oxygen content of the mixture delivered to the patient. The control system uses two flow sensors, one for each gas, for feedback control loops. An oxygen cell measuring the fraction of inspired oxygen (FiO 2 ) allows for mixture correction. Data from pressure sensors on both inspiratory and expiratory circuits are used to estimate the airway opening pressure. Depending on the mode of ventilation, the control system will deliver a constant flow, or variable flow, to reach a set pressure. All the aforementioned sensed variables are shown on the ventilator display (Figures 3A,C) .

The gas mixture leaves the ventilator through a 22mm tube outlet, compatible with standard medical tracheas, check valves, and filters. Additionally, two safety mechanisms prevent exposure to overpressure (manually adjustable pressure relief valve, maximum 60 cmH 2 O) and suffocation (oneway under-pressure valve). The connection ports for the overpressure and anti-suffocation valves are also standard 22mm tubes. Under normal operating conditions, the control system will prevent those conditions; the safety mechanisms are redundant systems.

To allow for both an unobstructed exhalation and fine control of flow during the PEEP phase, we selected a pneumatically controlled pinch valve. This valve has a large internal diameter, capable of large flows even in low-pressure conditions. During inhalation, the exhalation valve is closed. At the start of the exhalation, the valve fully opens until the pressure reaches the configured PEEP value. While keeping the PEEP, the exhalation valve is slightly open so that a small bias flow is present. This bias flow is useful for detecting an attempt by the patient to initiate a breath. A flow sensor in the exhalation circuit, in combination with both flow sensors in the inhalation circuit, lets us estimate the actual flow from/to the patient. Spontaneous breaths are detected by both a variation in pressure and a flow toward the patient during the exhalation period. We found this combined approach to be more robust than a single breath variable measurement.

ATENA was developed following the clinical requirements for the "minimally acceptable" performance of a mechanical ventilator aimed at the COVID-19 pandemic crisis. Those requirements and specifications were described in the Rapid Manufactured Ventilator System (RMVS) document by the UK Medicines & Healthcare products Regulatory Agency (MHRA) (17) and in the exceptional authorization by the National Authority for Drugs and Healthcare Products (deliberation of 29 June 2020, INFARMED) (18) .

The ATENA ventilator can operate in continuous mandatory ventilation (pressure-regulated volume control and pressureand volume-controlled modes) and in pressure support mode. ATENA's overall specifications and control ranges are presented in Table 1 . 

The main objective of the testing protocol was to demonstrate adequate safety and performance by the ATENA ventilator. We evaluated ATENA's accuracy and performance in five steps: (1) MHRA protocol, including endurance testing (17) ATENA was attached via the breathing circuit to a calibrated electronic gas flow analyzer ventilator tester (VT900A, Fluke Biomedical) and then to an adult test lung (ACCU LUNG TM Precision test, Fluke Biomedical) that simulates different respiratory systems with variable compliance (C) and resistance (R). The ventilator was also linked to an external computer that allowed the recording of pressure, flow, FiO 2 , and volume waveforms.

The assessment of the performance of ATENA was done under controlled conditions following MHRA's RMVS protocol (17) . We performed three sets of 36 trials for VC: (i) compliance, (ii) resistance, and (iii) tidal volume, and two sets of 36 trials for PC: (i) plateau pressure at 15 cmH 2 O and (ii) 30 cmH 2 O.

Concerning endurance testing, ATENA was connected to a passive lung simulator for 24 h. Ventilator settings at the beginning and the end of the test were reported, and the variation of the settings was analyzed.

Electromagnetic compatibility, electrical interference, emission, and immunity tests were made following European and international standards (EN 60601-1-2, EN 61000-6-1, EN 61000-4-4, EN 61000-4-6, EN 55011, and ISO 80601-2-12).

Simultaneously, the ATENA ventilator was submitted to ISO requirements testing for basic safety and essential performance of critical care ventilators (ISO 80601-2-12:2020) (19) . For volumecontrolled ventilation, seven tests were done with variable compliance and resistance lung models, using different tidal volume, PEEP, and FiO 2 . To evaluate the performance of pressure-controlled ventilation, seven tests were done also with different compliance and resistance levels, using different airway pressure, PEEP, and FiO 2 . Additionally, one set of 14 tests was done to assess ATENA's accuracy in the measurement of tidal volume.

Following recommendations from INFARMED (19) , ATENA performed an additional set of tests with a simulated ARDS lung model (C = 20 ml/cmH 2 O and R = 5 cmH 2 O/L/s). This allowed us to evaluate the accuracy of the ventilator with an extreme variation of tidal volume (250-800 ml) in VCV and of PEEP (0-40 cmH 2 O) in PCV modes. We ran an extra test with a healthy lung model, to analyze ATENA's accuracy on FiO 2 control (21-100%). Those tests were done without pausing the ventilator, to evaluate ATENA's response to a change in configuration parameters. The same breathing simulator and gas flow analyzer were used.

To evaluate the performance of the pressure support ventilation mode, we used an ASL5000 breathing simulator (version 3.6, Active Servo Lung, IngMar Medical, Pittsburgh, PA, USA) with an active lung model in both healthy and ARDS conditions. The settings used for each healthy (C = 50 ml/cmH 2 O and R = 10 cmH 2 O/L/s) and ARDS patient (C = 30 ml/cmH 2 O and R = 20 cmH 2 O/L/s) were available from the simulator's patient library and were validated in previous studies (11, (20) (21) (22) .

ASL5000 tested ATENA's (i) capacity to detect apnea and switch to backup controlled mandatory ventilation (pressurecontrolled ventilation) and (ii) performance on the pressure support mode with increasing inspiratory muscle strength. Given that the ATENA ventilator has an inspiratory trigger flow with a sensitivity that varies between 0.2 SLPM (high sensitivity) and 3 SLPM (low sensitivity), we decided to test three trigger points (0.2, 1, and 2 SLPM). For both healthy and ARDS lung models, the same spontaneous breathing parameters were used (respiratory rate: 3/15 cpm; uncompensated residual capacity: 0.5 L; pause: 0%; inspiratory muscle pressure: 0/10/15 cmH 2 O; expiratory muscle pressure: 0 cmH 2 O; inspiratory rise time: 10%; inspiratory hold: 5%; inspiratory release time: 10%; expiratory rise time: 0%; expiratory hold: 0%; expiratory release time: 0%; effort: sinusoidal). A total of 21 tests were performed on pressure support of 10 cmH 2 O with a PEEP of 5 cmH 2 O for testing ATENA's capacity to support the weaning process from mechanical ventilation (23, 24) .

Pre-clinical tests were performed following the EU Directive 2010/63/EU, approved by the Animal Welfare Body (ORBEA EM/ICVS-I3Bs_005/2020) of the institution where the study was conducted (University of Minho) and by the national authority for animal protection-Direção Geral de Alimentação e Veterinária (DGAV 008337). Four porcine animals (Sus scrofa domesticus) (14 weeks; average weight 32 ± 3 kg) were used to evaluate ATENA's performance in vivo, with a special focus on blood gas exchange during the MRHA test protocol. Two animals were allocated to the volume-controlled (group 1), and two animals were allocated to the pressure-controlled (group 2) ventilation. Animals were anesthetized with an intramuscular administration of ketamine (20 mg/kg) and xylazine (2 mg/kg), followed by intravenous propofol administration (4 mg/kg). Total Intravenous Anesthesia (TIVA) was maintained with continuous propofol infusion (4.4 mg/kg) in combination with fentanyl (0.005 mg/kg/h) and midazolam (0.7 mg/kg/h) administered through a central venous catheter, together with the parenteral isotonic fluids administered for maintenance of water and electrolyte balance (6-10 ml/kg/h). Rocuronium (2.5 mg/kg/h) was administered to provide muscle relaxation and improve ventilator adaptation. After intubation, animals were adapted to the ATENA ventilator with a FiO 2 of 60%. An invasive arterial line was achieved for a continuous hemodynamic (Combitrans Monitoring-Set arterial, BBraun, Germany) and blood gas (CG4+ cartridges, i-Stat analyzer, Abbott, Chicago, IL) monitoring.

In both groups, after 5 min of ventilation, arterial blood gas was collected to measure and record pH, PO 2 and PCO 2 , and HCO 3 , and a new ventilatory setting was selected. At the end of the experiment, with the animals still under deep anesthesia, euthanasia was performed by an intravenous administration of pentobarbital (200 mg/kg), with veterinary support.

In volume-controlled ventilation, a triplet of 36 trials for compliance, resistance, and tidal volume were done. In pressurecontrolled ventilation, the same number of tests were completed for PEEP, plateau pressure, and Concerning endurance testing, ATENA ran uninterrupted for 24 h, which represents 28,800 cycles. In volume-controlled ventilation, the set at the beginning of the test was as follows: tidal volume of 500 ml, respiratory rate 20 breaths/min, PEEP 5 cmH 2 O, and FiO 2 40%. The average of measured parameters in the first 13 min was a tidal volume of 512.73 ml, FiO 2 = 39.81%, and PEEP = 4.66 cmH 2 O. In the last 13 min of the 24 h, the average of the values measured were as follows: tidal volume = The relative error values measured between the initial and the last 13 min are tidal volume = 1.3%, FiO 2 = 0.2%, and PEEP = 7.4% for controlled ventilation and plateau pressure = 0%, O 2 = −1.2%, and PEEP = −7.6%.

In terms of electronic safety, the ATENA ventilator complies with the relevant requirements studied (EN 60601-1-2, EN 61000-6-1, EN 61000-4-4, EN 61000-4-6, EN 55011, and ISO 80601-2-12).

ATENA fulfilled the following criteria for basic safety and essential performance of critical care ventilators (ISO 80601-2-12:2020):

• Maximum error of the delivered and monitored tidal volume compared to the set value: ± (4 ml + 15% of the set value); • Maximum error of the PEEP compared to the set value: ± (2 cmH 2 O + 4% of the set value); • Maximum error of FiO 2 compared to the set value: ± (5% of the set value); and • Maximum error of P Plateau compared to the set value: ± (2 cmH 2 O + 4% of the set value).

Relevant data from volume-and pressure-controlled ventilation, as well as expired volume, measured criteria are presented in Supplementary Tables 2, 3 .

The results of additional tests are presented in Figure 6 . The data are presented and analyzed in terms of relative error between the values defined by the test conditions, configured in ATENA, and the values measured by the gas flow analyzer. The relationship is linear for all evaluated parameters (tidal volume, PEEP, FiO 2 , and P Plateau ).

The results obtained in tests 1 to 21 show that ATENA had an adequate performance for all trigger levels, for all inspiratory muscle pressures used in both healthy and ARDS simulated lungs (see Supplementary Table 4 ).

During the study period, all animals remained hemodynamically stable with no need for vasopressor support. Supplementary Tables 5, 6 display the relevant ventilatory settings and measures of ventilation variables in pre-clinical testing for volume-and pressure-controlled modes, respectively.

Test results demonstrated that the ATENA ventilator met the specifications in the MHRA RMVS guidelines. Its accuracy in terms of maximum bias and linearity errors is inside the performance limits for ISO 80601-2-12-2020 requirements. ATENA can achieve satisfactory performances for all volumecontrolled ventilation and pressure-controlled ventilation test conditions with a plateau pressure of 15 cmH 2 O. Limited performance was observed in only three tests for plateau pressure of 30 cmH 2 O, which explains the outlier values presented in Figure 5 :

#1 and 2-In the test with a plateau pressure of 30 cmH 2 O, compliance of 50 ml/cmH 2 O, resistance of 5 cmH 2 O/L/s, and respiratory rate of 20 cpm, both plateau pressure and PEEP were almost achieved. A high instantaneous flow (SLPM) would be required for the PEEP and plateau pressure setpoints to be reached. In fact, during these tests, tidal volumes as high as 1,000 ml were recorded. For a desired FiO 2 of 95%, the required instantaneous flow would exceed the maximum capabilities of ATENA's hardware. Due to the high FiO 2 setpoint, a single piezo-electric valve, the oxygen one, would limit the maximum flow to its capacity, ∼60 SLPM. It is important to notice that ATENA contains two piezo-electric valves, one for air and one for oxygen, each rated to a maximum of 60 SLPM. Again, the tidal volume observed in these tests is not adequate for the protective ventilation that is needed for COVID-19 patients. #3-For a plateau pressure of 30 cmH 2 O, compliance of 50 ml/cmH 2 O, and FiO 2 set to 95%, this last parameter could not be reached. This limitation is once again explained by ATENA's hardware capabilities that, when mostly using a single piezoelectric valve, are capable of reaching instantaneous flows of 60 SLPM.

The majority of ISO requirements were met by ATENA. However, for the accuracy tests of volume-controlled ventilation (Supplementary Table 2 , tests 1 and 2), in a simulated healthy patient (C = 50 ml/cmH 2 O and linear R of up to 20 cmH 2 O/L/s, tidal volume 500 ml), the PEEP parameter was underperforming. These results were considered to be sufficient for the adequate validation of ATENA since it is not expected that patients who developed bilateral pneumonia due to COVID-19 with the need for invasive ventilation (the scope of use for the ATENA ventilator) present a lung compliance of 50 ml/cmH 2 O (25). Furthermore, ATENA displays the accurately measured PEEP, so even if underperforming, it will provide the clinician the required data to make an informed decision.

Simultaneously, the analysis of the small PEEP coefficients of variation in tests performed in volume-and pressure-controlled ventilation allows us to affirm the stability and safety of this parameter in situations that mimic clinical practice.

Taking into account all of the above, it is possible to conclude that the ATENA adequately performed for all test conditions set by the MHRA's RMVS and ISO guidelines, except for a single set of conditions not commonly found in day-to-day clinical practice and may therefore be ruled as less relevant for a pandemic COVID-19 ventilator.

Results from the additional tests that extended the setting parameters of tidal volume, PEEP, FiO 2 , and plateau pressure to their extreme limits prove that ATENA can perform adequately in an enlarged range of values.

We studied ATENA's performance on pressure support (PS) ventilation mode with the settings commonly used for weaning a patient from the ventilator (pressure support of 10 cmH 2 O and PEEP of 5 cmH 2 O). The analysis of the results in these settings revealed that ATENA was able to provide PS ventilation in the range of flow trigger values under study and its performance was not impaired when we assessed different levels of inspiratory muscle strength, in both healthy and ARDS lung models.

Noteworthy, even though two HME/HEPA filters were included on the 1.5-m breathing tubes, during the pressure support tests, the muscle pressure required to successfully trigger the ventilator was adequate. This indicates that the trigger sensitivity is robust and is adapted to real working conditions.

During in vivo animal model studies, ATENA behaved within expectations for the required standards across the full range of configurations, in both volume-and pressure-controlled modes, maintaining excellent oxygenation and ventilation performance. In both groups, changes in partial gas pressure and arterial pH secondary to changes in ventilatory parameters were biologically expected. In no trial was oxygenation compromised, and an improvement in the partial pressure of oxygen in arterial blood in response to the increase in ventilation/min was always observed. At the same time, the hyperventilation that conditioned the presence of respiratory alkalosis in numerous blood gases assertively demonstrates the effectiveness of ATENA in ventilation.

The novel ATENA Medical Ventilator, here described, was extensively tested, fulfilling MHRA and ISO requirements and specifications. Additional tests for extended parameter limits, pressure support, and pre-clinical studies demonstrated that it can perform as required. The ventilator is capable of controlled modes VCV, PCV, and PRVC, and mode PSV, and is therefore entirely appropriate for clinical use in adult COVID-19 patients. Further clinical trials must be performed to ultimately and unequivocally validate ATENA in clinical practice.

The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.

The animal study was reviewed and approved by EU CEiiA's engineering team and were responsible for conceiving, developing, prototyping, and testing the ventilator throughout its development and validation. EN, EA, HM, JP, NS, PB, and SG: medical core team and Defined the specifications, tested, and validated the ATENA ventilator throughout its development and validation phases. TR, JA, SG, and JP: study conception and design of the paper. TR, JA, FB, PF, JP, RaM, and SG: acquisition of data, analysis and interpretation of data, and drafting the article. TR, JA, SG, RaM, and JP: in-depth revising the manuscript critically for important intellectual content. All authors contributed to the study and final approval of the version to be published and all agree to be accountable for all aspects of the work, thereby ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Financial support and sponsorship by CEiiA, INOV4COVID program, donations from scientific patronage, and commercial sales.

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The authors of this paper would like to acknowledge the support of all patrons, public and private institutions, medical and healthcare staff, universities, research institutions, enterprises, and ultimately all individuals who kindly gave their time, effort, and resources to the development of the ATENA Rapidly Manufactured Medical Ventilator. 

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fmed. 2021.614580/full#supplementary-material

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.