Nebulized enriched heparin improves respiratory parameters in patients with COVID-19: a phase I/II randomized and triple-blind clinical trial.

To evaluate the safety and the potential antiviral treatment of inhaled enriched heparin in patients with COVID-19. The specific objectives were to investigate the anticoagulation profile, antiviral and anti-inflammatory effects, and respiratory evolution of inhaled enriched heparin. We conducted a randomized, triple-blind, placebo-controlled Phase I/II clinical trial in hospitalized adults with COVID-19 receiving inhalation of enriched heparin or saline (placebo) every 4 h for 7 days. Among the 27 patients who completed the study, no changes in blood coagulation parameters were observed, indicating the safety of inhaled enriched heparin. The group receiving enriched heparin showed a significant reduction in the need for supplemental oxygen and improvement in respiratory parameters, such as the PaO2/FiO2 ratio. Inhalation of enriched heparin is shown to be safe and has also demonstrated potential therapeutic benefits for patients with COVID-19. These promising results justify the continuation of the study to the next phase, Phase II/III, to further evaluate the therapeutic efficacy of inhaled enriched heparin in the treatment of COVID-19-associated viral pneumonia.Trial registration: ClinicalTrials.gov. 08/02/2021. Identifier: NCT04743011.

HLA-DRB1 Polymorphisms and Rheumatologic Manifestations in Chronic Hepatitis C.

BACKGROUND/AIMS: Hepatitis C has been associated with rheumatologic manifestations (HCV-related RM). Clinically, HCV-related RM may be indistinguishable from the symptoms that occur in diffuse connective tissue diseases (DCTD-related RM), making the differential diagnosis difficult. Host genetic factors, such as the Human Leukocyte Antigens (HLA) polymorphisms were associated with HCV infection, however, there are no studies that discriminate between HCVrelated RM and DCTD-related RM. This study focused on verifying associations between HLADRB1 and RM in patients with chronic hepatitis C, aiming to distinguish between DCTD-related RM and HCV-related RM. METHODS: The participants were 152 individuals, of both sexes, aged between 18 and 80 years, and affected by chronic hepatitis C. The patients underwent rheumatologic physical examination and HLA-class II (HLA-DRB1) typing was performed by PCR-SSO (Polymerase Chain Reactionsequence Specific Oligonucleotides). RESULTS: A significant number of patients with rheumatologic complaints (73%) not attributed to other causes was observed. DRB1*08 allele seems to confer protection against RM in chronic hepatitis C. There is no susceptibility association between HLA-DRB1 alleles and RM. CONCLUSION: The absence of association between HLA-DRB1 and the rheumatologic manifestations studied suggests that the pathophysiological pathways of DCTD-related RM and HCV-related RM are distinct.

A novel molecular mechanism to explain mutations of the HCV protease associated with resistance against covalently bound inhibitors.

NS3 is an important therapeutic target for direct-acting antiviral (DAA) drugs. However, many patients treated with DAAs have unsustained virologic response (UVR) due to the high mutation rate of HCV. The aim of this work was to shed some light on the puzzling molecular mechanisms of the virus's of patients who showed high viral loads even under treatment with DAA. Bioinformatics tools, molecular modelling analyses were employed to identify mutations associated with HCV resistance to boceprevir and possible structural features related to this phenomenon. We identified two mutations of NS3 that may be associated with HCV resistance: D168N and L153I. The substitution D168N was previously reported in the literature as related with drug failure. Additionally, we identified that its molecular resistance mechanism can be explained by the destabilization of receptor-ligand hydrogen bonds. For the L153I mutation, the resistance mechanism is different from previous models reported in the literature. The L153I substitution decreases the S139 deprotonation susceptibility, and consequently, this mutation impairs the covalent binding between the residue S139 from NS3 and the electrophilic trap on boceprevir, which can induce drug failure. These results were supported by the time course analysis of the mutations of the NS3 protease, which showed that boceprevir was designed for enzymes with an L residue at position 153; however, the sequences with I153 are predominant nowadays. The results presented here could be used to infer about resistance in others DAA, mainly protease inhibitors.