Cardiovascular consequences of vaping.

PURPOSE OF REVIEW: Vaping activity continues to increase worldwide. Promoted as a 'healthier' alternative to traditional smoking, emerging evidence indicates 'healthier' should not be confused with 'harmless'. Direct inhalation exposure of the respiratory tract in experimental research demonstrates pulmonary consequences of vaping. However, cardiovascular consequences of vaping are poorly characterized and are a priority area of research to reveal vaping-induced pathogenesis. RECENT FINDINGS: Alterations in cardiovascular homeostasis, inflammation, and molecular changes following vaping exposure demonstrate vaping-related health concerns. SUMMARY: This review summarizes cardiovascular consequences of vaping from cumulative research findings. Strategic application of emerging technologies to understand the impact of vaping upon the cardiovascular system will be essential for defining the true risks of vaping-associated injury.

Fundamentals of vaping-associated pulmonary injury leading to severe respiratory distress.

Vaping of flavored liquids has been touted as safe alternative to traditional cigarette smoking with decreased health risks. The popularity of vaping has dramatically increased over the last decade, particularly among teenagers who incorporate vaping into their daily life as a social activity. Despite widespread and increasing adoption of vaping among young adults, there is little information on long-term consequences of vaping and potential health risks. This study demonstrates vaping-induced pulmonary injury using commercial JUUL pens with flavored vape juice using an inhalation exposure murine model. Profound pathological changes to upper airway, lung tissue architecture, and cellular structure are evident within 9 wk of exposure. Marked histologic changes include increased parenchyma tissue density, cellular infiltrates proximal to airway passages, alveolar rarefaction, increased collagen deposition, and bronchial thickening with elastin fiber disruption. Transcriptional reprogramming includes significant changes to gene families coding for xenobiotic response, glycerolipid metabolic processes, and oxidative stress. Cardiac systemic output is moderately but significantly impaired with pulmonary side ventricular chamber enlargement. This vaping-induced pulmonary injury model demonstrates mechanistic underpinnings of vaping-related pathologic injury.