key: cord-1022704-0oyprocs authors: Santos, Jose L. Francisco; Zanardi, Patricio; Alo, Veronica; Rodriguez, Marcelo; Magdaleno, Federico; De Langhe, Virginia; Dos Santos, Vanina; Murialdo, Giuliana; Villoldo, Andrea; Coria, Micaela; Quiros, Diego; Milicchio, Claudio; Garcia Saiz, Eduardo title: Pulmonary Edema in COVID-19 Treated with Furosemide and Negative Fluid Balance (NEGBAL): A Different and Promising Approach date: 2021-11-28 journal: J Clin Med DOI: 10.3390/jcm10235599 sha: 713b35fd48bb1304b5bc25938e5cebc7479fc8f0 doc_id: 1022704 cord_uid: 0oyprocs In COVID-19, pulmonary edema has been attributed to “cytokine storm”. However, it is known that SARS-CoV2 promotes angiotensin-converting enzyme 2 deficit, increases angiotensin II, and this triggers volume overload. Our report is based on COVID-19 patients with tomographic evidence of pulmonary edema and volume overload to whom established a standard treatment with diuretic (furosemide) guided by objectives: Negative Fluid Balance (NEGBAL approach). Retrospective observational study. We reviewed data from medical records: demographic, clinical, laboratory, blood gas, and chest tomography (CT) before and while undergoing NEGBAL, from 20 critically ill patients. Once the NEGBAL strategy was started, no patient required mechanical ventilation. All cases reverted to respiratory failure with NEGBAL, but subsequently two patients died from sepsis and acute myocardial infarction (AMI). The regressive analysis between PaO2/FiO2BAL and NEGBAL demonstrated correlation (p < 0.032). The results comparing the Pao2Fio2 between admission to NEGBAL to NEGBAL day 4, were statistically significant (p < 0.001). We noted between admission to NEGBAL and day 4 improvement in CT score (p < 0.001), decrease in the superior vena cava diameter (p < 0.001) and the decrease of cardiac axis (p < 0.001). Though our study has several limitations, we believe the promising results encourage further investigation of this different pathophysiological approach. In December 2019, a new coronavirus, known as severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), emerged in Wuhan, China [1] and spread throughout the world [2, 3] . In COVID-19, pulmonary edema is described [4] [5] [6] [7] ; however, the dominant paradigm is focused on cytokine storm [8] [9] [10] [11] [12] as responsible for lung injury and subsequent acute respiratory distress syndrome (ARDS) [5, 13] . Not everyone agreed with this paradigm. Sinha et al. [14] challenged the role of this cytokine storm given that median IL-6 levels in non-COVID patients ARDS are up to 200 times higher than in patients with severe COVID-19. Gattinoni et al. [15] maintained that COVID-19 presented as an "atypical form" of ARDS. On the other hand, Kuba et al. and Imai et al. reported that angiotensin-converting enzyme 2 (ECA2) levels during a SARS-CoV infection are decreased [16, 17] . Furthermore, in patients with COVID-19, plasma levels of Angiotensin II are higher than in healthy population [18] and stimulate an upregulation of aldosterone level, triggering sodium and water retention [19] [20] [21] [22] . SARS-CoV-2 enters through ACE2, and further downregulates ACE2 [18, 23, 24] expression so that this enzyme is unable to exert its protective effects. The dysregulated activity of the renin angiotensin aldosterone system (RAAS) [16] is partly responsible for pulmonary edema in COVID-19 [16, 24] . ACE2 is known for its effect as the main counter-regulatory mechanism for the reninangiotensin aldosterone system (RAAS), which is an essential player in blood pressure control by retaining sodium and water and increasing the intravascular fluid volume. SARS-CoV-2 binds ACE2 and accelerates the degradation of ACE2, and thus decreases the counteraction of ACE2 on RAAS. The final effect is increasing reabsorption of sodium and water, and therefore causing volume overload [16, 19, 20, 22] . The RAAS can be envisioned as a dual function system in which the vasoconstrictor/proliferative or vasodilator/antiproliferative actions are primarily driven by the ACE-ACE2 balance [19] . According to that, an increased ACE/ACE2 activity ratio generated by the downregulation action of SARS-CoV2 on ACE2 [18, [22] [23] [24] will lead to increased Angiotensin II [18] and increased catabolism of Angiotensin 1-7, towards vasoconstriction, endothelial dysfunction, prothrombosis, proinflammatory, and antinatriuretic effect [19, 22] . Acute pulmonary edema is caused mostly by one of the following mechanisms: pulmonary venous pressure elevation-volume overload-or augmentation of the alveolar capillary membrane permeability-inflammation [25] . In fact, both mechanisms sometimes coexist and the distinction is irrelevant. There are bibliographic mentions of pulmonary edema in COVID 19 [4] [5] [6] [7] , as well as evidence of volume overload in COVID-19: Lang et al. describes frequent and pronounced vasculature in affected lung areas that may be suggestive of disordered vasoregulation [26] . Eslami et al. observed increased cardiothoracic ratio [27] and it is also described as right ventricular dilatation [28, 29] . In this setting, a different approach emerged: moderate or severe COVID-19 could experience a severe acute pulmonary edema with a "dual hit". A "first hit" of pneumonitisaugmentation of the alveolar capillary membrane permeability-can lead to low hydrostatic pressure pulmonary edema. The "second hit" is high pressure pulmonary edema, caused by increase of hydrostatic pressure [25, 30] secondary to volume overload, a result of dysregulation of the RAAS [16] [17] [18] [19] [20] [21] [22] . This results in a "dual hit" that triggers severe acute pulmonary edema. If this edema does not resolve, then comes a "third hit" with secondary inflammation, superinfection, fibrosis, and finally the typical ARDS. With all of this in mind, we looked for and detected pulmonary edema before ARDS was triggered. We searched cases of moderate and severe COVID-19, and found tomographic evidence of pulmonary edema, detected by dilated superior vena cava, large pulmonary arteries, diffuse interstitial infiltrates, and dilated right ventricle [31] . At the detection of pulmonary edema in COVID-19 patients, we established a standard treatment consisting of oral hydric restriction and diuretics [25, 32] . The effects of furosemide on pulmonary edema were well established decades ago [25] . At the time of submission of our study, we did not find any literature that proposed the model of pulmonary edema and volume overload secondary to the dysregulation of the renin angiotensin aldosterone system in COVID-19. The Ethics in Investigation Committee (Mar del Plata, Argentina) approved the study. All investigations were conducted in accordance with the 1964 Declaration of Helsinki and its later amendments. Patients were not involved in the design, or conduct, or reporting, or dissemination plans of our research. This single-center retrospective, observational study was conducted on patients from 22 June 2021 to 16 August 2021, with confirmed diagnosis of COVID-19 and pulmonary edema, who were admitted to our high complexity center in Mar del Plata, Argentina, and underwent a treatment with furosemide in continuous intravenous infusion, guided by objectives: Negative Fluid Balance approach (NEGBAL). Inclusion criteria were as follows: (1) confirmed diagnosis of COVID-19 through realtime reverse transcriptase polymerase chain reaction (RT-PCR) assay with samples obtained from nasopharyngeal swab or positive antinucleocapsid IgM antibodies; (2) PaO2/FiO2 (ratio of arterial oxygen partial pressure to fractional inspired oxygen) <200; (3) age older than 18 years, and (4) tomographic evidence of acute pulmonary edema, defined as dilated superior vena cava, large pulmonary arteries, diffuse interstitial infiltrates with Kerley lines, and dilated right ventricle or dilated cardiac axis. Exclusion criteria were as follows: (1) patients with prior indication for diuretics for another reason, (2) renal failure, (3) cardiac failure (diagnosis by echocardiography), (4) hepatic failure, (5) hypernatremia or hyponatremia, (6) hypotension or shock. We reviewed data from medical records of 20 consecutive adult patients: demographic; clinical, laboratory; Pro b-type natriuretic peptide (pro-BNP, negative: below 125 pg/mL); high-sensitivity cardiac troponin (hs-cTnT, negative: <14 ng/L); blood gas; chest tomography (CT); the oxygen therapy support; and mechanical ventilation (MV) requirements, all of which were reviewed and recorded by investigators. With the purpose of knowing the patient's basal hematocrit out of the course of COVID-19, we reviewed prior hematocrit, if any, defined as hematocrit previous to COVID 19 infection (hematocrit prior to admission to NEGBAL). The treatments for COVID-19 pneumonia, in our series, were based on standard recommendations. As concomitant interventions these patients received dexamethasone 6 mg/day and thromboembolic prevention with enoxaparin 40 mg/day. CTs were performed upon admission to NEGBAL and CT controls were scheduled for day 4 (+/− 1 day), day 8 (+/− 1 day), and day 12 (+/− 1 day). We also reviewed tomographies performed before admission to our center, at the emergency room or as an inpatient, if any, during the first days of the course of COVID-19 and distanced at least two days before admission to NEGBAL (CT score prior to NEGBAL) with the purpose of observing the natural evolutionary trend of COVID-19 before NEGBAL. CT was performed in every patient using a 32-slice scanner (Siemens somatom scope, Germany) or a 16-slice scanner (General Electric brivo, GE Medical System) in supine position during end-inspiration. A 1.5 mm slice thickness and 1.5 mm interval were used for the axial image. For the evaluation of CT infiltrates, the score described by Pan F et al. [33] was used as a semiquantitative measurement, measuring the sum of lung involvement-5 lobes-each lobe, on a scale from 0 (normal) to 5 (maximum infiltrate), with a maximum CT score of 25. The measurement of the superior vena cava diameter (Ø svc) in the CT was done just above the arch of the azygos veins. The cardiac axis (Ø card.) was also measured: transverse measurement across the four cavities. Cardiothoracic ratio (CTR) was defined as the greatest transverse cardiac diameter from outer to outer myocardium divided by the greatest transverse thoracic diameter from inner to inner chest wall. These determinations were calculated and reviewed by two external imaging specialists. Both radiologists were blinded to laboratory data, clinical features, and patients' diagnosis. At the tomographic detection of pulmonary edema (dilated superior vena cava, large pulmonary arteries, diffuse interstitial infiltrates with Kerley lines, and dilated right ventricle or dilated cardiac axis), we established treatment: NEGBAL approach. It consisted of oral hydric restriction and diuretics (20 mg of furosemide, intravenous bolus, followed by furosemide in endovenous continuous infusion, starting at 60 mg/d). The objective was to achieve negative fluid balance, between 600 to 1400 mL/d adjusted to body surface area, with a final target of 8-10% of body weight in 8 days. The furosemide dose was titrated considering heart rate and blood pressure, target fluid balance, hematocrit, and serum creatinine. The presence of hypotension (systolic blood pressure less than 100 mmHg for 30 min), hyponatremia, hypernatremia, or elevated serum creatinine was considered a cause of suspension of NEGBAL. All patients were followed until either death or complete recovery and discharge were reached. To analyze the relationship between the variation of the PaO2/FiO2 ratio and the NEG-BAL variables, we used a linear regression model of the form PAFIBAL~β0+β1NEGBAL. For the model, the response variable PAFIBAL was registered as the difference between the PaO2/FiO2 at admission to NEGBAL and the PaO2/FiO2 at day 7. Continuous variables were expressed as means. Categorical variables were summarized as counts. No changes (adjustments) were made for missing data. The paired sample T test was used. All statistical tests were 2-tailed. A p-value < 0.05 was considered statistically significant. The analysis has not been adjusted for multiple comparisons and, given the possibility of a type I error, the findings should be interpreted as exploratory and descriptive. All analyses were performed using R software, version 4.1.1 (R Foundation for Statistical Computing) (see Supplemental Materials: Statistics). Between 22 June and 16 August 2021, a total of 69 patients with COVID-19 were referred to our center. Forty-four patients with PaO2/FiO2 > 200 and 5 with kidney or heart failure were excluded from the analysis. Thus, data from 20 critically ill patients with laboratory-confirmed COVID-19 were analyzed. Mean age of patients was 52.9 ± 14 years old, 13 were male. The average APACHE II score at admission was 9.05 (±4.32). Among the reported population, 14 out of 20 had comorbidities and 11/20 received the first dose of vaccine. The baseline predictors of poor prognosis were 6/20 patients with obesity (IMC > 30), 4/20 patients with hypertension, 2/20 with COPD, and there were no cases of asthma or pulmonary fibrosis, 6/19 patients had elevated D-dimers on admission. (See demographic information in Table 1 and biochemical data at admission information in Table 2 ). In our series of patients, the requirement of oxygen therapy support was: 2/20 required MV, 3/20 required high flow nasal cannula, 2/20 patients required noninvasive ventilation, 10/20 required oxygen mask plus reservoir, and 3/20 standard oxygen mask. At the time of starting NEGBAL, 2/20 (cases 1 and 2) were already under MV. After the establishment of the NEGBAL approach, no patient required MV. Cases 1 and 2 improved oxygenation and CT score with NEGBAL, and successful extubation were achieved in both cases. Two patients died, case 1, six days after ending NEGBAL due to sepsis and case 17, five days after ending NEGBAL, due to acute myocardial infarction. The remaining 18 patients were discharged. The mean total accumulated negative fluid balance was −7637 mL (±2616 mL). Adjusted for total days of effective application of NEGBAL in the population, the mean negative fluid balance obtained was −1184 mL for each day. Adjusted to square meter, the mean negative fluid balance was −3952 mL/m 2 (Table S1 ). In the population studied, the heart rate stayed within normal range, with a tendency to bradycardia and they remained afebrile (Tables S2 and S3) . The safety data showed that none of the 20 cases presented electrolyte or serum creatinine alterations or hypotension during NEGBAL. For this reason, none of the patients presented criteria for suspending NEGBAL (Tables S4-S6 ). PaO2/FiO2 at admission to NEGBAL (mean 118 ± 47) was compared with PaO2/FiO2 on day 4 (mean 246 ± 111); the differences was statistically significant (p < 0.001; (95% CI, −168, −89)), on day 8 (mean 316 ± 90) (p < 0.001; (95% CI, −244, −157)), and at discharge (mean 332 ± 80) (p < 0.001; (95% CI, −256, −172)). A significant improvement in oxygenation was achieved in all cases ( Figure 1B) . The CT score was analyzed and the difference was statistically significant. CT score prior to NEGBAL (mean 7.1 ± 1.4) was compared with CT score at admission (mean 17.2 ± 1.3) (p < 0.001; (95% CI, −12.1, −8.2)), CT score at admission (mean 17.2 ± 1.3) to day 4 (mean 10.6 ± 1.6) (p < 0.001; (95% CI, 4.1, 8.9)) and CT score day 4 (mean 10.6 ± 1.6) to CT score day 8 (mean 7.7 ± 1.4) of NEGBAL (p < 0.001; (95% CI, 1.4, 4.3)) ( Figure 2A) . The hematocrit level before starting NEGBAL (mean 41.5 ± 5.6%) was compared to the hematocrit upon admission to NEGBAL (mean 37.5 ± 4.9%) (p < 0.001; (95% CI, 3.7, 7.6)) and the admission hematocrit (mean 37.5 ± 4.9%) to the hematocrit at discharge (mean 40.7 ± 5%) (p = 0.002; (95% CI, −5.1, −1.2)) ( Figure 2B ). The diameters of the superior vena cava were measured in millimeters and compared, before starting NEGBAL (mean 14.6 ± 4.4) to admission to NEGBAL (mean 17.9 ± 3.8) (p < 0.001; (95% CI, −6.6, −2.4)), admission to NEGBAL (mean 17.9 ± 3.8) to NEGBAL day 4 (mean 14.2 ± 4.5) (p < 0.001; (95% CI, 1.7, 5.5)) and admission to NEGBAL (mean 17.9 ± 3.8) to discharge (mean 13.9 ± 3) (p < 0.001; (95% CI, 2.4, 5.5)) ( Figure 2C ). The cardiac axis was measured in centimeters and compared, prior to NEGBAL (mean 12.2 ± 1.4) to admission to NEGBAL (mean 12.8 ± 1.3) (p = 0.002; (95% CI, −1.6, −0.4)), admission to NEGBAL (mean 12.8 ± 1.3) to NEGBAL day 4 (mean 11.7 ± 1.6) (p < 0.001; (95% CI, 0.6, 1.5)) ( Figure 2D ). More information: Tables 3 and S7-S10. PaO2/FiO2 at admission to NEGBAL (mean 118 ± 47) was compared with PaO2/FiO2 on day 4 (mean 246 ± 111); the differences was statistically significant (p < 0.001; (95% CI, −168, −89)), on day 8 (mean 316 ± 90) (p < 0.001; (95% CI, −244, −157)), and at discharge (mean 332 ± 80) (p < 0.001; (95% CI, −256, −172)). A significant improvement in oxygenation was achieved in all cases ( Figure 1B) . The CT score was analyzed and the difference was statistically significant. CT score prior to NEGBAL (mean 7.1 ± 1.4) was compared with CT score at admission (mean 17.2 ± 1.3) (p < 0.001; (95% CI, −12.1, −8.2)), CT score at admission (mean 17.2 ± 1.3) to day 4 (mean 10.6 ± 1.6) (p < 0.001; (95% CI, 4.1, 8.9)) and CT score day 4 (mean 10.6 ± 1.6) to CT score day 8 (mean 7.7 ± 1.4) of NEGBAL (p < 0.001; (95% CI, 1.4, 4.3)) ( Figure 2A) . The hematocrit level before starting NEGBAL (mean 41.5 ± 5.6%) was compared to the hematocrit upon admission to NEGBAL (mean 37.5 ± 4.9%) (p < 0.001; (95% CI, 3.7, 7.6)) and the admission hematocrit (mean 37.5 ± 4.9%) to the hematocrit at discharge (mean 40.7 ± 5%) (p = 0.002; (95% CI, −5.1, −1.2)) ( Figure 2B ). The diameters of the superior vena cava were measured in millimeters and compared, before starting NEGBAL (mean 14.6 ± 4.4) to admission to NEGBAL (mean 17.9 ± 3.8) (p < 0.001; (95% CI, −6.6, −2.4)), admission to NEGBAL (mean 17.9 ± 3.8) to NEGBAL day 4 (mean 14.2 ± 4.5) (p < 0.001; (95% CI, 1.7, 5.5)) and admission to NEGBAL (mean 17.9 ± 3.8) to discharge (mean 13.9 ± 3) (p < 0.001; (95% CI, 2.4, 5.5)) ( Figure 2C ). The cardiac axis was measured in centimeters and compared, prior to NEGBAL (mean 12.2 ± 1.4) to admission to NEGBAL (mean 12.8 ± 1.3) (p = 0.002; (95% CI, −1.6, −0.4)), admission to NEGBAL (mean 12.8 ± 1.3) to NEGBAL day 4 (mean 11.7 ± 1.6) (p < 0.001; (95% CI, 0.6, 1.5)) ( Figure 2D ). More information: Table 3 and Tables S7-S10. The average dose of intravenous infused furosemide in milligrams per hour was: day 1, 3.5 (±2); day 2, 4.2 (±2); day 3, 4.5 (±3); day 4, 4.5 (±3); day 5, 4.8 (±3); day 6, 4.8 (±4); and day 7, 5.5 (±4) (Table S11). The present study has several limitations. It is retrospective, observational, and the number of patients quite limited. Added to the absence of a control group, it is that these limitations could affect the interpretation of some result. We observed in our series an incidence of obesity and hypertension similar to that published by Bonifazi et al. [34] , although with a lower incidence of smokers and no cases of asthma. Furthermore, in the biomedical published literature, unfortunately, we did not find a similar approach for pulmonary edema in COVID-19. However, there are numerous reports of pulmonary edema [4] [5] [6] [7] 16, 17] together with evidence of volume overload [26] [27] [28] [29] in COVID-19. This evidence, added to the promising clinical response to NEGBAL, support this approach to pulmonary edema in COVID-19 as a biological plausibility. It is encouraging that the population in this report obtained a significant improvement in oxygenation between PaO2/FiO2 at the beginning of NEGBAL and PaO2/FiO2 at day 4 (p < 0.001). An encouraging point is that no patient with moderate and severe COVID-19 required MV while implementing this NEGBAL approach. We were able to observe COVID-19 progression as the hematocrit level decreased and increases in the CT score in the period elapsed between an evaluation for COVID-19 days before and admission to NEGBAL. This deterioration shows how COVID-19 progresses gradually with volume overload and worsening of pulmonary edema evidenced in a higher CT score and a dilutional decrease in hematocrit. Interestingly, when NEGBAL was started, the decrease in hematocrit and tomographic deterioration was reversed. We looked for indirect evidence that could reflect the existence of volume overload, probably generated by RAAS deregulation in COVID-19, and provide the following observations: First, the variability of the diameter of the superior vena cava, which increased as COVID-19 worsened (p < 0.001), could be a sign of an increase of fluid in the vascular compartment. Furthermore, when NEGBAL started, we detected a progressive and significant (p < 0.001) decrease in this diameter. The dilation of the cavities and the vena cava were mentioned by other authors and, similar to our observations, were associated with the severity of COVID-19 [29] . Lang et al. [26] also describes a pronounced dilatation of pulmonary vasculature. We interpreted that this description may be suggestive of volume overload. Second, we observed that the length of the cardiac axis showed a similar behavior. There was a progressive increase as COVID-19 worsened (p = 0.002), but as NEGBAL was implemented, we detected a gradual decrease in the cardiac axis (p < 0.001). We observed the same behavior in the cardiothoracic index. This coincides with Eslami et al. [27] , who revealed that increased cardiothoracic ratio (CTR) is a powerful predictor of mortality. However, the authors could not associate the increased cardiac index with markers of heart disease. This supports our hypothesis that the observed cardiovascular dilation is due to a state of hypervolemia and not to cardiac dysfunction. Third, anemia in COVID-19 has numerous explanations [35] [36] [37] , but none have been conclusive. In our series, the behavior of the hematocrit in COVID-19 patients manifested itself in coherence with the observations outlined earlier. We observed a progressive decrease of hematocrit as COVID-19 worsened (p = <0.001), interpreting it secondary to a dilution effect. As NEGBAL was being implemented, it was noticeable that the hematocrit showed a progressive rise (p = 0.002). Tao et al. [35] described that patients with severe anemia presented a higher proportion of hypoxia than patients with mild anemia. This is consistent with our observation that, as COVID-19 progresses, there is more anemia (for hemodilution) and more hypoxemia (for edema), and when NEGBAL was implemented, and abnormal hypervolemia corrected, hypoxemia improved and hematocrit increased. A particular pattern was repeated in all cases as COVID-19 worsened. There was a decrease in hematocrit level, coinciding with an increase in the diameter of the superior vena cava. These two simultaneous observations, we believe, can only be explained by a state of hypervolemia secondary to excess of fluids. Fourth, we observed that heart rate showed a tendency to bradycardia. Sinus bradycardia is common and paradoxical in COVID-19 [38] [39] [40] and have been related to favipiravir [41] , SIADH [42] , hydroxychloroquine [43] , remdesivir [44, 45] , lopinavir-ritonavir [46] , among other multiple explanations. It is interpreted that it may be another indirect evidence of abnormal hypervolemia, which generates an increase in preload and, by Frank Starling's law, increase in stroke volume, resulting in a cardiac adaptive response, with a decrease in heart rate. Fifth, the rapid improvement in the CT score within day 4 (p < 0.001) to day 8 (p < 0.001) after NEGBAL, allowed us to suspect that would predominate as the cause of these infiltrates is pulmonary edema (secondary to "dual hit") and not hegemonic inflammation. Sixth, we observe a correlation with statistical significance between NEGBAL and PaO2/FiO2 (p = 0.034), which supports the hypothesis that in COVID-19 there is pulmonary edema and there is no typical ARDS. However, this "dual hit", inflammation plus edema, could be part of a process that would end, at a later stage, in ARDS [47, 48] . Seventh, and finally, the mean accumulated negative fluid balance was −7637 mL, with optimal hemodynamic tolerance in all patients. We believe that adequate tolerance was only possible due to the pre-existence of volume overload. These observations could support our proposed explanation of successive pulmonary hits. The "first hit" of COVID-19 pneumonitis [49] , followed by dysregulation RAAS [17] "second hit", generating excess of intra-and extravascular fluid, causing volume overload [26, 28, 29] and pulmonary edema [4] [5] [6] [7] . With unresolved edema, appeared a "third hit" characterized by infection, fibrosis, more inflammation, and ending in ARDS [47, 50] (see Supplementary Materials: Figures S1-S6) . For the aforementioned, we believe that as volume overload increases, there are more dilated distal subpleural vessels [26] , more dilatation of the large blood vessels [27] [28] [29] . A posteriori, it ensues a dilatation of the superior vena cava, progressively, also the cardiac index [27] is added, and the cardiac axis is expanded, increasing the dilatation of the right ventricle [28, 29] . This causes an increase of the hydrostatic pressure [25, 30] and the consequent pulmonary edema [4] [5] [6] [7] 16, 17] . Once the negative fluid balance approach was established, this harmful sequence was reverted. We believe that dosing angiotensin II, angiotensin 1-7, vasopressin and aldosterone daily from the beginning of the COVID-19 infection could detect a dysregulation of the RAAS [51] [52] [53] [54] . To detect and quantify fluid overload in COVID-19 is challenging, and consequently interesting that Mei et al. [55] apply the remote dielectric sensing (ReDS) technique, which is a noninvasive electromagnetic wave technology that provides an accurate reading of lung fluid content, and they detected fluid overload in the lung parenchyma in COVID-19. Similarly, Rasch et al. [6] used an invasive technique of transpulmonary thermodilution that provides bedside measurement of extravascular lung water index, which is a marker of pulmonary edema. They reported that COVID-19 pneumonia has up to five times more extravascular lung water index (2600 mL) than normal lungs (500 mL). We consider that both studies support our hypothesis. Finally, in our series, we observed the absence of clinical signs of systemic inflammatory response syndrome and discrete alterations in leukocyte count and c-reactive protein. This supports the Sinha et al. [14] hypothesis that the cytokine storm would be just a discrete drizzle. Although it is a study with several limitations, this pathophysiological approach of pulmonary edema and volume overload due to downregulation ACE2 and pneumonitis plus edema, "dual hit" shows a promising perspective. We are hopeful that these findings will encourage research towards this pathophysiological and therapeutic approach in COVID-19. Prospective, randomized, and multicenter case-control studies are necessary to determine whether this different pathophysiological perspective has a real basis or if it is a mere coincidence for an attractive but failed hypothesis. Supplementary Materials: The following are available online at https://www.mdpi.com/article/ 10.3390/jcm10235599/s1, Table S1 : Daily negative fluid balance in milliliters per day. Accumulate in milliliters total days of Negative Fluid Balance (NEGBAL), Table S2 : Heart rate daily evolution, Table S3 : Temperature ( • C) daily evolution, Table S4 : Serum creatinine levels at ICU admission and discharge, Table S5 : Serum sodium levels at ICU admission and day 7, Table S6 : Serum potassium at ICU admission and day 7, Table S7 : Computed Tomography (CT) score, Table S8 : Superior vena cava diameter (mm) in Computed Tomography (CT), Table S9 : Cardiac axis (cm) in Computed Tomography (CT), Table S10 : Cardiothoracic Ratio (CTR) in Computed Tomography (CT), Table S11 : Furosemide in milligrams per hour data daily evolution, Figure S1 : What is hidden behind this evolution COVID-19?, Figure S2 : Emerging hypothesis: First HIT, Figure S3 : Emerging hypothesis: Second HIT, Figure S4 : Emerging hypothesis: Third HIT, Figure Informed Consent Statement: Patient consent was waived since it is a retrospective observational study in which data were obtained from routine diagnostic studies and standard conventional therapeutic for pulmonary edema. The data presented in this study are available on request from the corresponding author. More data are contained within the Supplementary Materials. The visualization of the tomographies is available in an online website. World Health Organization. Pneumonia of Unknown Cause-China statement-on-the-second-meeting-of-the-international-health-regulations-(2005)-emergency-committeeregarding-the-outbreak Director-General's Opening Remarks at the Media Briefing on COVID-19-11 Pulmonary Edema in COVID-19 Patients: Mechanisms and Treatment Potential Pathological findings of COVID-19 associated with acute respiratory distress syndrome Increased extravascular lung water index (EVLWI) reflects rapid non-cardiogenic oedema and mortality in COVID-19 associated ARDS Urgent reconsideration of lung edema as a preventable outcome in COVID-19: Inhibition of TRPV4 represents a promising and feasible approach Cytokine storm intervention in the early stages of COVID-19 pneumonia Cytokine Storms: Understanding COVID-19 Early identification of COVID-19 cytokine storm and treatment with anakinra or tocilizumab The cytokine storm and COVID-19 Cytokine storm and COVID-19: A chronicle of pro-inflammatory cytokines Management of COVID-19 Respiratory Distress Is a "Cytokine Storm" Relevant to COVID-19? COVID-19 does not lead to a "typical" acute respiratory distress syndrome A crucial role of angiotensin converting enzyme 2 (ACE2) in SARS coronavirus-induced lung injury Angiotensin-converting enzyme 2 protects from severe acute lung failure Clinical and biochemical indexes from 2019-nCoV infected patients linked to viral loads and lung injury Simoes e Silva, A.C. Recent advances in the angiotensin-converting enzyme 2-angiotensin(1-7)-Mas axis Assessment of Hypokalemia and Clinical Characteristics in Patients with Coronavirus Disease The new biology of aldosterone El acertijo a resolver. Hipertens Riesgo Vasc. 2020 Renin-Angiotensin-Aldosterone System Inhibitors in Patients with COVID-19 Angiotensin receptor blockers as tentative SARS-CoV-2 therapeutics Clinical practice: Acute Pulmonary Edema Pulmonary Vascular Manifestations of COVID-19 Pneumonia The Association of CT-measured Cardiac Indices with Lung Involvement and Clinical Outcome in Patients with COVID-19 Right Ventricular Dilation in Hospitalized Patients With COVID-19 Infection Acute right ventricular dysfunction in severe COVID-19 pneumonia Fluid Overload and Acute Kidney Injury Clinical and Radiologic Features of Pulmonary Edema The Pathogenesis of Acute Pulmonary Edema Associated with Hypertension Time Course of Lung Changes at Chest CT during Recovery from Coronavirus Disease 2019 (COVID-19) Predictors of Worse Prognosis in Young and Middle-Aged Adults Hospitalized with COVID-19 Pneumonia: A Multi-Center Italian Study (COVID-UNDER50) Anemia is associated with severe illness in COVID-19: A retrospective cohort study Anemia and iron metabolism in COVID-19: A systematic review and meta-analysis Anemia is associated with severe coronavirus disease 2019 (COVID-19) infection Clinical analysis of sinus bradycardia in patients with severe COVID-19 pneumonia Bradycardia in Patients With COVID-19: A Calm Before the Storm? Cureus 2020, 12, e8599 Relative bradycardia in patients with COVID-19 Severe sinus bradycardia associated with favipiravir in a COVID-19 patient Symptomatic sinus bradycardia due to electrolyte imbalances in syndrome of inappropriate antidiuretic hormone (SIADH) related COVID-19: A case report Suspected Hydroxychloroquine-Induced Sinus Bradycardia and QTc Prolongation in a Patient with COVID-19 Serious bradycardia and remdesivir for coronavirus 2019 (COVID-19): A new safety concerns Remdesivir-Induced Bradycardia in COVID-19: A Single Center Prospective Study. Circ Lopinavir-Ritonavir Treatment for COVID-19 Infection in Intensive Care Unit Autopsy findings in COVID-19-related deaths: A literature review COVID-19 acute respiratory distress syndrome (ARDS): Clinical features and differences from typical pre-COVID-19 ARDS Thoughts on the alveolar phase of COVID-19 COVID-19 Deaths: Are We Sure It Is Pneumonia? Please, Autopsy, Autopsy, Autopsy! Physiology and regulation of the renin-Angiotensin-Aldosterone system Vasopressin regulates the renin-angiotensin-aldosterone system via V1a receptors in macula densa cells Raised venous pressure: A direct cause of renal sodium retention in oedema? Hypervolemia increases release of atrial natriuretic peptide and shedding of the endothelial glycocalyx Validation of Remote Dielectric Sensing (ReDS) in Monitoring Adult Patients Affected by COVID-19 Pneumonia The research team wants to thank Jorge Guzman, Graciela Tivani, and Ignacio Mackinnon for their collaboration and Hernan Vivas and Natalia Torres for providing statistical analysis, the Ethics Committee, the Internal Medical Staff of Clinica Colón, Mariana Eguren for article translation, Ramiro Santos for figures design, and Jeronimo Santos for Nietzsche perspectivism and to the memory of Raul Dzienisik. The authors declare no conflict of interest.