Clinical Drug Experience Knowledgebase

Open Clinical Trial of the Use of Antioxidants and Pentoxifylline as Adjuvant Therapy to Standard Therapy in Patients With and Without Septic Shock Secondary to COVID-19 Severe Pneumonia

I. Background

The SARS-CoV-2 virus has a positive-sense RNA, with a genome of approximately 27-32 kb in length. COVID-2019 infection causes severe pneumonia that turns into a pulmonary alveolar collapse within a few hours and leads to the cessation of oxygen exchange. The incubation period for the virus is 2 to 10 days, and the clinical spectrum of the disease ranges from asymptomatic infection to severe respiratory failure. There is elevated lymphopenia, lactate, creatinine, and kinase dehydrogenase, and higher concentrations of interleukins such as IL-1β, IL-5, IL-7, IL-8, IL-9, IL-10, IL-15, IL-12p70, FGF, GCSF, GMCSF, IFNγ, IP10, MCP1, MIP1A, MIP1B, PDGF, TNF-α and VEGF.

There is no treatment for the definitive cure of COVID-19, and there is no vaccine that allows prevention. Considering that the best management choice is to reestablish hemodynamic status, stop organ failure, improve anti-inflammatory conditions, and improve redox status, management strategies could not be randomized since individual conditions change, and patients may have comorbidities at first. The studies that support antioxidant therapy in septic management range from those carried out in vitro, in vivo in an animal model and humans, so the evidence makes it necessary that patients treated with specific antiviral drugs, or antibiotics, receive at the same time nutritional supplement and antioxidants.

The data that support each of the antioxidants as therapy in septic shock are mentioned below.

N-ACETYL CYSTEINE.

The administration of N-acetylcysteine (NAC), a glutathione (GSH) precursor, as a strategy to limit oxidative lung injury has been proposed since it increases the intracellular content of GSH. Alterations in GSH metabolism, in alveoli and lung tissue, are a central feature in many lung diseases. NAC increases the synthesis of GSH, increases glutathione-S-transferase (GST) activity, and has a direct action on free radicals (ROS). The application of NAC reduces levels of IL-8, IL-6, ICAM. NAC in patients with septic shock is associated with a shorter time on mechanical ventilation and fewer days of stay in the ICU.

The application of NAC reduces levels of IL-8, IL-6, ICAM. NAC in patients with septic shock is associated with a shorter time on mechanical ventilation and fewer days of stay in the ICU. NAC uptake and intracellular concentration can be increased through the use of liposomes (L-NAC). NAC supplementation in animals exposed to lipopolysaccharides (LPS) reduced lung edema, lipoperoxidation (OLP), ACE damage, chloramine concentration, and concentrations of the eicosanoids thromboxane and leukotrienes (LTB2 and LTB4) in the lung. In clinical trials, supplementation with a bolus of 150 mg/kg NAC followed by 50 mg/kg/day of NAC for four days in patients with acute lung injury ALI or ARDS improved the oxygenation rate from day 1 to 4 and reduced mortality.

MELATONIN

Melatonin (MT) has been shown to possess ROS-sequestering properties, protects lipids in cell membranes, cytosol proteins, and nuclear and mitochondrial DNA.

Furthermore, in another study, MT demonstrated anti-apoptotic, antioxidant, and pleiotropic anti-inflammatory effects in vitro and in vivo as direct elimination activity against ROS and stimulation of antioxidant enzymes, such as CAT, SOD, GPx, GR, and gamma-glutamylcysteine synthase, MT can accumulate within the mitochondria and thus reduce the local excess production of ROS, which is typical in dysfunctional mitochondria during sepsis. Based on these favorable preliminary data, randomized control trials are warranted to assess TM's efficacy and safety as an add-on treatment in COVID-19 sepsis. The previously mentioned studies have recommended its use in sepsis, which should be considered in COVID-19 since it is also accessible, and its cost is low, making it possible to weigh the risk/benefit in the event of a pandemic.

VITAMIN C

Ascorbic acid, or vitamin C, is a water-soluble antioxidant that functions as a cofactor for multiple enzymes. It is absorbed at the intestinal level through the sodium-dependent transporter of vitamin C, filtered freely in the glomerulus, and reabsorbed at the proximal tubule level through the same transporter. Ascorbic acid inhibits the production of superoxide (O2-) and peroxynitrite (OONO-) by inhibiting superoxide-producing NADPH oxidase (O2-) and inducible nitric oxide (iNOS) mRNA expression, which prevents the abundant production of nitric oxide (NO) that generates peroxynitrite (OONO-) in the presence of O2-.

PENTOXIFILINA.

Pentoxifylline is a xanthine drug indicated in some severe alcoholic hepatitis; it also acts on the plasma membrane of red blood cells and makes it more malleable, thus improving blood perfusion. Pentoxifylline exerts several antioxidant and anti-inflammatory activities, such as reducing the restoration of GSH levels, maintaining mitochondrial viability, inhibiting the production of TNF-α, preserving vascular endothelial functions, and also supplementation with antioxidants has been reported better oxygenation rates, higher GSH, and more robust immune response. Also, there was a reduction in hospital stay length, the time of mechanical ventilation, the length of the ICU stays, the multiple organ dysfunction rate, and the mortality rate in patients with ALI / ARDS.

II. Research question

Will the administration of adjuvant therapy with specific antioxidant and pentoxifylline in patients with or without septic shock secondary to severe pneumonia due to COVID-19, will it avoid the use of mechanical ventilation, reduce the time of use of a mechanical ventilator, days of hospital stay, decrease the lipoperoxidation and will it increase the antioxidant capacity in patients admitted to intensive care?

III. Justification

In this COVID-19 pandemic, severe pneumonia and septic shock are the leading cause of morbidity and mortality in intensive care units worldwide. In this sense, and based on the discoveries of recent years in the field of oxidative stress, including those recently found in our group, it is necessary to report results on new treatments capable of reducing the deleterious inflammatory response and the redox state. In patients with pneumonia and septic shock. The situation that currently occurs in patients who progress to severity due to infection with COVID-19.

Septic shock has been presented in other viral diseases such as Middle East Respiratory Syndrome Coronavirus (MERS-CoV) detected for the first time in Saudi Arabia, in which it exhibited a wide range of presentations at the time of diagnosis, similar to SARS-COv2 from patients without symptoms, subtle signs of pneumonia or multiorgan failure, with the capacity to cause the death of which the possible therapeutic interventions with antioxidants have been proposed since then that have been proposed for the new virus through the conclusions based on systematic reviews.

Many viral diseases such as SARS-CoV, although clinical data are limited, can develop moderate and severe septic shock and increase ROS and RNS production, which is associated with overexpression of iNOS, NADP oxidases, cyclooxygenase two, and xanthine oxidase, which activates transcription factors such as NF-B resulting in an exacerbated pro-inflammatory host response. Also, O2 and ONOO participate as an essential mediator of pro-inflammatory interleukin production. These will continue to stimulate the production and release of more ROS and RNS that can interfere with mitochondrial respiration since mitochondrial dysfunction is commonly induced in an environment of septic shock. Therefore, antioxidant treatment may be a way to avoid excessive inflammation associated with a history of high oxidation in COVID-19 patients.

With this study, we intend to evaluate the effect of the use of antioxidants on outcomes in storm regulation due to dysregulation of oxidative stress, shortening of ventilator use, days of stay, and clinical repercussion through the measurement of organ dysfunction in six different systems, using the SOFA score before and after the intervention, in critically ill patients due to SARS-Cov2 infection.

IV. Hypothesis

It is hypothesized that adjuvant therapy with antioxidants and pentoxifylline reduces ventilator use in patients with or without septic shock secondary to severe COVID-19 pneumonia and decreases lipoperoxidation and corrects dysregulation of oxidative stress through the increase of antioxidant capacity.

V. Primary objective

Provide combined antioxidant therapy as an adjunct to standard therapy for patients with or without septic shock secondary to severe SARS-COV2 pneumonia to evaluate whether it is possible to avoid intubation, reduce days of assisted mechanical ventilation, and improve stress dysregulation oxidant leading to multiple organ failure.

VI. Secondary objective

Evaluate the prevalence of comorbidity in patients with or without septic shock and severe SARS-CoV2 pneumonia in the ICU.
To evaluate the effect of adjuvant antioxidant therapy in reducing days with the ventilator and days of hospital stay in patients
Analyze the effect on organ failure in five devices and systems (neurological, respiratory, hemodynamic, hepatic, hematological) of each of the therapies implemented in the different systems evaluated with the SOFA score.
Measure lipoperoxidation in basal and post-therapy samples
Measure the antioxidant capacity in basal and post-therapy samples.
Measure IL-6 in basal and post-therapy samples.
Measure procalcitonin, CRP, troponin, pro-BNP, ferritin, and D-dimer.
Determine the status of outcomes by comorbidity strata.
Document the use of ARA, ACE, SGLT2 inhibitors in patients with COVID-19.
Analyze the previous use of steroids and those who did not have it in a stratified way

VII. Methodology

Study design

It is a quasi-experimental, open analytical, prospective, and longitudinal (before-after) study.

Sample size

The sample size calculation was based on studies that currently have mortality using Vitamin C because there is no history of antioxidants in the clinical context. The sample size was calculated using X2 to compare two independent proportions.

Therefore, it will be necessary to include 11 patients in each group if desired to obtain 80% possibility (80% power) or 32 if the power is 99% to detect a mean difference of ≥3 in SOFA between the groups. On the other hand, treatment will be possible in these patients, it will be possible to measure the basal state of oxidative stress, and state three after the therapy allows the use of small samples, as the patient is his control.

Statistic analysis

Continuous variables will be expressed as mean ± standard deviation or median with minimum and maximum, depending on their distribution. Categorical variables will be expressed as frequencies and percentages. The normality of the variables will be evaluated using the Shapiro-Wilk or Shapiro-France test, depending on the sample size. Variables with normal distribution will be analyzed with parametric tests (Student's t-test for independent measurements or paired t-test for before-after measurements). While various non-parametric tests were used (Mann-Whitney test, Kruskal-Wallis or Wilcoxon signed rank test, depending on the particular case) to contrast variables without Gaussian distribution. Analysis of paired samples (before-after) will be performed with Friedman or Wilcoxon and paired t-test, depending on the distribution of the data. For multivariate analysis, a binary logistic regression analysis will be performed. Also an analysis of repeated samples and panel data testing different models (grouped model, model for longitudinal data, marginal approximation model and multilevel model).