key: cord-0754005-nd2cnwp7
authors: Siswanto; Gani, Munawar; Fauzi, Aditya Rifqi; Yuliyanti, Ririn Enggy; Inggriani, Maria Patricia; Nugroho, Bagus; Agustiningsih, Denny; Gunadi
title: Possible silent hypoxemia in a COVID-19 patient: A case report
date: 2020-11-24
journal: Ann Med Surg (Lond)
DOI: 10.1016/j.amsu.2020.11.053
sha: fffa2f145172929f5c0e3f0b0258775ce69b4ba6
doc_id: 754005
cord_uid: nd2cnwp7

INTRODUCTION: It has been hypothesized that silent hypoxemia is the cause of rapid progressive respiratory failure with severe hypoxia that occurs in some COVID-19 patients without warning. PRESENTATION OF CASE: A 60-year-old male presented cough without any breathing difficulty. Vital signs showed blood pressure 130/75 mmHg, pulse 84x/minute, respiratory rate (RR) 21x/minute, body temperature 36.5C, and oxygen saturation (SpO2) 75% on room air. RT-PCR for COVID-19 were positive. On third day, he complained of worsening of breath shortness, but his RR was still normal (22x/minute) with SpO2 of 98% on 3 L/minute oxygen via nasal cannula. On fifth day, he experienced severe shortness of breath with RR 38x/minute. He was then intubated using a synchronized intermittent mandatory ventilation. Blood gas analysis showed pH 7.54, PaO2 58.9 mmHg, PaCO2 31.1 mmHg, HCO3 26.9mEq/L, SaO2 94.7%, FiO2 30%, and P/F ratio 196 mmHg. On eighth day, his condition deteriorated with blood pressure 80/40 mmHg with norepinephrine support, pulse 109x/minute, and SpO2 72% with ventilator. He experienced cardiac arrest and underwent basic life support, then resumed strained breathing with return of spontaneous circulation. Blood gas analysis showed pH 7.07, PaO2 58.1 mmHg, PaCO2 108.9 mmHg, HCO3 32.1mEq/L, SaO2 78.7%, FiO2 90%, and P/F ratio 65 mmHg. Three hours later, he suffered cardiac arrest again and eventually died. DISCUSSION: Possible mechanisms of silent hypoxemia are V/Q mismatch, intrapulmonary shunting, and intravascular microthrombi. CONCLUSIONS: Silent hypoxemia might be considered as an early sign of deterioration of COVID-19 patients, thus, physician may be able to intervene early and decrease its morbidity and mortality.

The SARS-CoV-2 virus that causes Coronavirus Disease 2019 (COVID- 19) was declared a pandemic since the World Health Organization (WHO) decree on March 11, 2020 , and has infected more than 54 million people and caused more than 1.3 million deaths as of November 14, 2020 [1,2] .

The early sign of severe disease of SARS-CoV-2 infection is pneumonia with respiratory failure, similar to Acute Respiratory Distress Syndrome (ARDS). Although hypoxic acute respiratory failure causes an increase in respiratory rate (RR), in some patients, a persistent normal RR was found and inconsistent with the severity of hypoxia. Some patients with reported experiencing rapid deterioration without warning. This reaction might be caused by 'silent hypoxemia'. Research has shown that failure of pulmonary oxygen diffusion causes a gradual decrease in oxygen saturation [3, 4] . Here, we reported one COVID-19 case with the possibility of silent hypoxemia.

A 60-year-old Javanese male came to outpatient clinic in our hospital with complaints of cough that was felt for two weeks before admission without any breathing difficulty. Complaints were accompanied by fever, runny nose and sore throat. He had a comorbid condition of uncontrolled diabetes mellitus (DM). He was not a smoker and had no history of chronic pulmonary disease. (Fig. 2) . Three hours later, he suffered cardiac arrest again, but was unable to be resuscitated. The patient eventually died.

Here, we discuss a case with COVID-19 with the possibility of silent hypoxemia.

Hypoxemia itself is defined as a potential life-threatening condition characterized by a decrease in arterial PO2 below the normal value. Hypoxemia documentation can be done by checking pulse oximetry and arterial blood gas analysis. Hypoxemia occurs when PaO2 is less than 80 mmHg, and severe hypoxemia is when it is less than 60 mmHg. There are four main factors that can impair pulmonary gas exchange and cause hypoxemia when breathing room water is at sea level: hypoventilation, diffusion limitation, shunt, and ventilation-perfusion mismatch [7] [8] [9] .

This unusual 'silent hypoxemia' phenomenon showed it is possible that the virus has an idiosyncratic effect on the respiratory control system.

Angiotensin-converting-enzyme 2 (ACE2) receptors are highly expressed in the carotid bodies, which are also the same sites where chemoreceptors sense oxygen. ACE2 receptors are also widely expressed in the nasal mucosa.

Symptoms of anosmia-hyposmia are experienced by a third of patients with COVID-19, and the olfactory bulb can be the entrance of the virus to the brain and may also play a role in depressed dyspnea response [10, 11] .

Moreover, ACE2 counteracts the physiological functions of ACE and results in the activation of the renin-angiotensin-aldosterone system (RAAS) related to blood pressure regulation through the conversion of Angiotensin I to Angiotensin II and the electrolyte homeostasis. During the hypoxia condition, Angiotensin II induces vasoconstriction to improve the ventilation-perfusion mismatch, however, at the same time, it also stimulates the pro-fibrotic effect, and both effects are aggravated by the concomitant upregulation of ACE2 [10] [11] [12] .

Gattinoni et al. [13] suggested two primary phenotypes of hypoxemia in patients with COVID-19: type L and type H. Type L is caused by loss of respiratory regulation and loss of hypoxic vasoconstriction. The condition of hypoxemia is due to an increase in minute ventilation, mainly by increasing the tidal volume (up to 15-20 ml/kg). Meanwhile, type H is a transition from type L, which is associated with a more negative intrathoracic inspiratory pressure.

Diffuse pulmonary microvascular thrombosis is also believed to be the cause of hypoxemia in patients with COVID-19 [14] .

Pneumonia analysis of COVID-19 shows that the air sacs in the lungs of patients are not filled with fluid or pus as in pneumonia infections in general but instead the virus causes the water sacs to collapse, thereby reducing the J o u r n a l P r e -p r o o f oxygen level and causing hypoxia in the patient, but the reaction still enhances the normal lung ability to expel carbon dioxide. Since carbon dioxide removal is still effective, patients do not feel shortness of breath [15] . Another mechanism proposed is intrapulmonary shunting. Infection causes interstitial edema, loss of surfactant and superimposed pressure, which induces alveolar collapse and substantial fraction of cardiac output perfusing non-aerated lung tissue. Over time, increased edema will increase lung weight, alveolar collapse, and dependent atelectasis, leading to increased shunting [16] .

is thought to also play a role in the mechanism of silent hypoxemia. SARS-CoV-2 can directly infect lung capillary endothelial cells expressing ACE2.

Endothelial injury and acute inflammation provoke the formation of intravascular microthrombi. Lung autopsies in patients after severe disease have shown diffuse alveolar damage, thickening of the vascular walls, and formation of microthrombi that clog capillaries. Hypercoagulable conditions accelerate the worsening of V/Q mismatch and lung tissue damage [16] .

Risk factors for silent hypoxemia are old age and having diabetes [9] and these factors are known to blunt the body's regulatory response to hypoxia [17] , as in our case: a 60-year-old-male with comorbidity of diabetes mellitus. Therefore, early detection of silent hypoxemia such as by using prehospital pulse oximetry [5] , or radiology imaging [18, 19] might provide some red flag signs of impending danger of eminent cardiac arrest or sudden respiratory failure.

Silent hypoxemia might be considered as an early clinical sign of deterioration of patients with COVID-19, thus, the physician may be able to intervene early and decrease its morbidity and mortality.

SARS-CoV-2: Severe Acute Respiratory Syndrome Coronavirus 2; COVID-19:

Coronavirus Disease 2019, RR: Respiratory rate; ACE2: Angiotensinconverting-enzyme 2; RAAS: renin-angiotensin-aldosterone system.

Written informed consent was obtained from the patient for publication of this case report and accompanying images. A copy of the written consent is available for review by the Editor-in-Chief of this journal on request.

Not commissioned, externally peer reviewed. 

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