The Roles of MicroRNAs in Asthma and Emerging Insights into the Effects of Vitamin D3 Supplementation.

Asthma is one of the most common chronic non-communicable diseases worldwide, characterized by variable airflow limitation secondary to airway narrowing, airway wall thickening, and increased mucus resulting from chronic inflammation and airway remodeling. Current epidemiological studies reported that hypovitaminosis D is frequent in patients with asthma and is associated with worsening the disease and that supplementation with vitamin D3 improves asthma symptoms. However, despite several advances in the field, the molecular mechanisms of asthma have yet to be comprehensively understood. MicroRNAs play an important role in controlling several biological processes and their deregulation is implicated in diverse diseases, including asthma. Evidence supports that the dysregulation of miR-21, miR-27b, miR-145, miR-146a, and miR-155 leads to disbalance of Th1/Th2 cells, inflammation, and airway remodeling, resulting in exacerbation of asthma. This review addresses how these molecular mechanisms explain the development of asthma and its exacerbation and how vitamin D3 may modulate these microRNAs to improve asthma symptoms.

Retinol-binding protein 4 and plasminogen activator inhibitor-1 as potential prognostic biomarkers of non-allergic asthma caused by obesity in adolescents.

BACKGROUND: Non-allergic asthma caused by obesity is a complication of the low-grade chronic inflammation inherent in obesity. Consequently, the serum concentrations of adipokines such as retinol-binding protein 4 (RBP4) and plasminogen activator inhibitor-1 (PAI-1) increase. No gold standard molecule for the prediction of non-allergic asthma among obese patients has been identified. OBJECTIVE: To evaluate RBP4 and PAI-1 as prognostic biomarkers of non-allergic asthma caused by obesity. METHODS: A cross-sectional study between four groups of adolescents: (1) healthy (n = 35), (2) allergic asthma without obesity (n = 28), (3) obesity without asthma (n = 33), and (4) non-allergic asthma with obesity (n = 18). RESULTS: RBP4 was higher in the non-allergic asthma with obesity group than in the obesity without asthma group (39.2 ng/mL [95% confidence interval (CI): 23.8-76.0] vs. 23.5 ng/mL [95% CI: 3.2-33.5], p < 0.01), and PAI-1 was higher in the non-allergic asthma with obesity group than in the obesity without asthma group (21.9 ng/mL [95% CI: 15.7-26.5] vs. 15.9 ng/mL [95% CI: 9.4-18.2], p < 0.05). Receiver operating characteristic (ROC) curve analysis demonstrated that the serum RBP4 cut-off value was >42.78 ng/mL, with an area under the ROC curve (AUC) of 0.741 (95% CI: 0.599-0.853, p = 0.001), considered acceptable. The PAI-1 cut-off value was >12.0 ng/mL, with an AUC of 0.699 (95% CI: 0.554-0.819, p = 0.008), considered fair. CONCLUSIONS: RBP4 may be useful to predict non-allergic asthma among obese adolescents in clinical practice.

Clonal dispersion of Acinetobacter baumannii in an intensive care unit designed to patients COVID-19.

INTRODUCTION: SARS-CoV2 pandemic marks the need to pay attention to bacterial pathogens that can complicate the hospital stay of patients in the intensive care unit (ICU). ESKAPE bacteria which includes Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter cloacae are considered the most important, because of their close relationship with the development of ventilator-associated pneumonia (VAP). The aim of this work was to identify and characterize ESKAPE bacteria and to detect their possible clonal spread in medical devices, patients, and medical personnel of the ICU for COVID-19 patients of the Hospital Juarez de Mexico. METHODOLOGY: Genetic identification of ESKAPE bacteria was performed by analyzing the 16S rRNA gene. Resistance assays were performed according to the CLSI guidelines. Assembly of AdeABCRS operon and inhibition assays of pumps efflux in Acinetobacter baumannii isolates were performed. Associated gene involved in biofilm formation (icaA) was performed in isolates belonging to the Staphylococcus genus. Finally, typing by ERIC-PCR and characterization of mobile genetic element SCCmec were done. RESULTS: Heterogeneous distribution of ESKAPE and non-ESKAPE bacteria was detected in various medical devices, patients, and medical personnel. Acinetobacter baumannii and Staphylococcus aureus were the predominant ESKAPE members. The analysis of intergenic regions revealed an important clonal distribution of A. baumannii (AdeABCRS+). Genotyping of SCCmec mobile genetic elements and the icaA gene showed that there is no clonal distribution of S. aureus. CONCLUSIONS: Clonal spread of A. baumannii (AdeABCRS+) highlights the importance of adopting good practices for equipment disinfection, surfaces and management of COVID-19 patients.

Nanodispositivos para la prevención y tratamiento de enfermedades cardiovasculares.

Actualmente las enfermedades cardiovasculares representan la principal causa de morbimortalidad en el mundo; la aplicación de la nanotecnología es una gran promesa en su prevención y tratamiento. Se están desarrollando nanodispositivos para la liberación dirigida y controlada de medicamentos en sitios específicos en el organismo, por ejemplo, en células, tejidos, vasos sanguíneos y el corazón, así como para el diagnóstico, detección temprana de enfermedades cardiovasculares y tratamiento individualizado de pacientes. Otra posible aplicación de los nanodispositivos es la liberación de fármacos para corregir el mal acoplamiento de proteínas defectuosas. Con potentes superefectos, las nanopartículas deberán ser capaces de provocar efectos terapéuticos a bajas dosis en periodos prolongados. La fabricación de nanodispositivos y nanoacarreadores deberá llevarse a cabo con un enfoque integral que tome en cuenta las propiedades generales, con la finalidad de evaluar la biocompatibilidad y, en consecuencia, evitar efectos adversos y tóxicos. La investigación intensificada en este campo ayudará a reducir significativamente la morbimortalidad provocada por las enfermedades cardiovasculares.Currently, cardiovascular disease represents the main cause of morbidity and mortality worldwide; the application of nanotechnology holds great promise for its prevention and treatment. Nanodevices ("smart drugs") are currently being developed for directed and controlled delivery of drugs to specific sites in the body, such as cells, tissues, blood vessels and the heart, as well as for diagnosis and early detection of cardiovascular conditions and patient-individualized treatment. Another application of nanodevices is the delivery of drugs to correct defective protein bad coupling or binding. With potent super-effects, nanoparticles should be able to elicit therapeutic effects at lower doses and prolonged periods. The manufacture of nanodevices and nanocarriers should be with a comprehensive approach that takes general properties into account in order to assess for biocompatibility and, therefore, avoid adverse and toxic effects. Intensified research in this field will help to significantly reduce morbidity and mortality caused by cardiovascular disease.

Nanodevices that acts as nanocarriers for controlled and directed drug delivery to select cells, organs or tissues in cardiovascular diseases.

Cardiovascular disease, which today represents the main cause of death worldwide, is a likely candidate for the application of nanotechnology in the near future. Nanocarriers are currently being developed to deliver medicine (smart drugs) to selected targets in cells and tissues of blood vessels and the heart, as well as to aid in diagnosis and screening for early detection and individualized treatment. Other applications of nanotechnology hold promise for the long run, such as using nanodevices for drug delivery or correcting the misfolding of proteins. With super-potent effects, nanoparticles should be able to evoke therapeutic effects at a lower dose and for longer periods. The development of nanodevices and nanocarriers must take an integral approach that considers many properties-physical, chemical, biological, biochemical, anatomical, morphological, physiological, pharmacological, toxicological, mechanical, electrical, magnetic, thermodynamic, and optical-in order to evaluate biocompatibility and therefore avoid toxicological and/or other adverse effects. Intensified research in relation to nanocarriers and other nanotechnology could help reduce morbidity and mortality in cardiovascular disease.