A severe case of rhabdomyolysis after Moderna mRNA anti-COVID-19 vaccine with a literature review.

The identification of rhabdomyolysis as a potential fatal adverse reaction to recent COVID-19 vaccines is essential. As the symptoms of rhabdomyolysis are not specific, the threshold to actively search for this complication should be low.

Recent advances in ginsenosides against respiratory diseases: Therapeutic targets and potential mechanisms.

BACKGROUND: Respiratory diseases mainly include asthma, influenza, pneumonia, chronic obstructive pulmonary disease, pulmonary hypertension, lung fibrosis, and lung cancer. Given their high prevalence and poor prognosis, the prevention and treatment of respiratory diseases are increasingly essential. In particular, the development for the novel strategies of drug treatment has been a hot topic in the research field. Ginsenosides are the major component of Panax ginseng C. A. Meyer (ginseng), a food homology and well-known medicinal herb. In this review, we summarize the current therapeutic effects and molecular mechanisms of ginsenosides in respiratory diseases. METHODS: The reviewed studies were retrieved via a thorough analysis of numerous articles using electronic search tools including Sci-Finder, ScienceDirect, PubMed, and Web of Science. The following keywords were used for the online search: ginsenosides, asthma, influenza, pneumonia, chronic obstructive pulmonary disease (COPD), pulmonary hypertension (PH), lung fibrosis, lung cancer, and clinical trials. We summarized the findings and the conclusions from 176 manuscripts on ginsenosides, including research articles and reviews. RESULTS: Ginsenosides Rb1, Rg1, Rg3, Rh2, and CK, which are the most commonly reported ginsenosides for treating of respiratory diseases, and other ginsenosides such as Rh1, Rk1, Rg5, Rd and Re, all primarily reduce pneumonia, fibrosis, and inhibit tumor progression by targeting NF-κB, TGF-ß/Smad, PI3K/AKT/mTOR, and JNK pathways, thereby ameliorating respiratory diseases. CONCLUSION: This review provides novel ideas and important aspects for the future research of ginsenosides for treating respiratory diseases.

Impact of intravenous lidocaine on clinical outcomes of patients with ARDS during COVID-19 pandemia (LidoCovid): A structured summary of a study protocol for a randomised controlled trial.

OBJECTIVES: The main objective of this study is to evaluate the effect of intravenous lidocaine on gas exchange and inflammation in acute respiratory distress syndrome due or not to Covid-19 pneumonia. TRIAL DESIGN: This is a prospective monocentric, randomized, quadruple-blinded and placebo-controlled superiority trial. This phase 3 clinical study is based on two parallel groups received either intravenous lidocaine 2% or intravenous NaCl 0.9%. PARTICIPANTS: This study has been conducted at the University Hospitals of Strasbourg (medical and surgical Intensive Care Units in Hautepierre Hospital) since the 4th November 2020. The participants are 18 years-old and older, hospitalized in ICU for a moderate to severe ARDS according to the Berlin definition; they have to be intubated and sedated for mechanical protective ventilation. All participants are affiliated to the French Social security system and a dosage of beta HCG has to be negative for women of child bearing age . For the Covid-19 subgroup, the SARS-CoV2 infection is proved by RT-PCR <7 days before admission and/or another approved diagnostic technique and/or typical CT appearance pneumonia. The data are prospectively collected in e-Case Report Forms and extracted from clinical files. INTERVENTION AND COMPARATOR: The participants are randomised in two parallel groups with a 1:1 ratio. In the experimental group, patients receive intravenous lidocaine 2% (20mg/mL) (from FRESENIUS KABI France); the infusion protocol provide a bolus of 1 mg/kg (ideal weight), followed by 3 mg/kg/h for the first hour, 1.5 mg/kg/h for the second hour, 0.72 mg/kg/h for the next 22 hours and then 0.6 mg/kg/h for 14 days at most or 24 hours after extubation or ventilator-weaning. The patients in the control group receive intravenous NaCl 0.9% (9 mg/mL) (from Aguettant, France) as placebo comparator; the infusion protocol provide a bolus of 0.05 mL/kg (ideal weight), followed by 0.15 mL/kg/h for the first hour, 0.075 mL/kg/h for the second hour, 0.036 mL/kg/h for the next 22 hours, and the 0.03 mL/kg/h for up to 14 days or 24 hours after extubation or ventilator-weaning. Lidocaine level is assessed at H4, D2, D7 and D14 to prevent local anesthetics systemic toxicity. Clinical data and biological samples are collected to assess disease progression. MAIN OUTCOMES: The primary outcome is the evolution of alveolar-capillary gas exchange measured by the PaO2/FiO2 ratio after two days of treatment. The secondary endpoints of the study include the following: Evolution of PaO2/FiO2 ratio at admission and after 21 days of treatment Number of ventilator-free days Anti-inflammatory effects by dosing inflammatory markers at different timepoints (ferritin, bicarbonate, CRP, PCT, LDH, IL-6, Troponin HS, triglycerides, complete blood count, lymphocytes) Anti-thrombotic effects by dosing platelets, aPTT, fibrinogen, D-dimers, viscoelastic testing and identification of all thromboembolic events up to 4 weeks. Plasmatic concentration of lidocaine and albumin Incidence of adverse events like cardiac rhythm disorders, need of vasopressors, any modification of the QRS, QTc or PR intervals every day Ileus recovery time Consumption of hypnotics, opioids, neuromuscular blockers. Lengths of stay in the ICU, incidence of reintubation and complications due to intensive care unit care (mortality until 90 days, pneumothorax, bacterial pneumopathy, bronchospasm, cardiogenic shock, acute renal failure, need of renal dialysis, delirium, atrial fibrillation, stroke (CAM-ICU score), tetraplegia (MCR score)). Incidence of cough and sore throat at extubation or ventilator-weaning and within 24 hours. All these outcomes will be evaluated according to positivity to Sars-Cov-2. RANDOMISATION: The participants who meet the inclusion criteria and have signed written informed consent will be randomly allocated using a computer-generated random number to either intervention group or control group. The distribution ratio of the two groups will be 1:1, with a stratification according to positivity to Sars-Cov-2. BLINDING (MASKING): All participants, care providers, investigator and outcomes assessor are blinded. NUMBERS TO BE RANDOMISED (SAMPLE SIZE): We planned to randomize fifty participants in each group, 100 participants total. TRIAL STATUS: The amended protocol version 2.1 was approved by the Ethics Committee "Comité de Protection des Personnes Sud-Méditerranée II on January 8, 2021 and by the Commission Nationale de l'Informatique et des Libertés (CNIL) on November 10, 2020. The study is currently recruiting participants; the recruitment started in November 2020 and the planned recruitment period is three years. TRIAL REGISTRATION: The trial was registered on clinicaltrials.gov on October 30, 2020 and identified by number NCT04609865 . FULL PROTOCOL: The full protocol is attached as an additional file, accessible from the Trials website (Additional file 1). In the interest in expediting dissemination of this material, the familiar formatting has been eliminated; this Letter serves as a summary of the key elements of the full protocol.

Exploring active ingredients and function mechanisms of Ephedra-bitter almond for prevention and treatment of Corona virus disease 2019 (COVID-19) based on network pharmacology.

BACKGROUND: COVID-19 has caused a global pandemic, and there is no wonder drug for epidemic control at present. However, many clinical practices have shown that traditional Chinese medicine has played an important role in treating the outbreak. Among them, ephedra-bitter almond is a common couplet medicine in anti-COVID-19 prescriptions. This study aims to conduct an exploration of key components and mechanisms of ephedra-bitter almond anti-COVID-19 based on network pharmacology. MATERIAL AND METHODS: We collected and screened potential active components of ephedra-bitter almond based on the TCMSP Database, and we predicted targets of the components. Meanwhile, we collected relevant targets of COVID-19 through the GeneCards and CTD databases. Then, the potential targets of ephedra-bitter almond against COVID-19 were screened out. The key components, targets, biological processes, and pathways of ephedra-bitter almond anti-COVID-19 were predicted by constructing the relationship network of herb-component-target (H-C-T), protein-protein interaction (PPI), and functional enrichment. Finally, the key components and targets were docked by AutoDock Vina to explore their binding mode. RESULTS: Ephedra-bitter almond played an overall regulatory role in anti-COVID-19 via the patterns of multi-component-target-pathway. In addition, some key components of ephedra-bitter almond, such as ß-sitosterol, estrone, and stigmasterol, had high binding activity to 3CL and ACE2 by molecular docking simulation, which provided new molecular structures for new drug development of COVID-19. CONCLUSION: Ephedra-bitter almonds were used to prevent and treat COVID-19 through directly inhibiting the virus, regulating immune responses, and promoting body repair. However, this work is a prospective study based on data mining, and the findings need to be interpreted with caution.

Exploring the Potential Mechanism of Shufeng Jiedu Capsule for Treating COVID-19 by Comprehensive Network Pharmacological Approaches and Molecular Docking Validation.

OBJECTIVE: Shufeng Jiedu capsule (SFJDC) is a well-known Chinese patent drug that is recommended as a basic prescription and applied widely in the clinical treatment of COVID-19. However, the exact molecular mechanism of SFJDC remains unclear. The present study aims to determine the potential pharmacological mechanisms of SFJDC in the treatment of COVID-19 based on network pharmacology. METHODS: The network pharmacology-based strategy includes collection and analysis of active compounds and target genes, network construction, identification of key compounds and hub target genes, KEGG and GO enrichment, recognition and analysis of main modules, as well as molecule docking. RESULTS: A total of 214 active chemical compounds and 339 target genes of SFJDC were collected. Of note, 5 key compounds (ß -sitosterol, luteolin, kaempferol, quercetin, and stigmasterol) and 10 hub target genes (TP53, AKT1, NCOA1, EGFR, PRKCA, ANXA1, CTNNB1, NCOA2, RELA and FOS) were identified based on network analysis. The hub target genes mainly enriched in pathways including MAPK signaling pathway, PI3K-Akt signaling pathway and cAMP signaling pathway, which could be the underlying pharmacological mechanisms of SFJDC for treating COVID-19. Moreover, the key compounds had high binding activity with three typical target proteins including ACE2, 2OFZ, and 1SSK. CONCLUSION: By network pharmacology analysis, SFJDC was found to effectively improve immune function and reduce inflammatory responses based on its key compounds, hub target genes, and the relevant pathways. These findings may provide valuable evidence for explaining how SFJDC exerting the therapeutic effects on COVID-19, providing a holistic view for further clinical application.