Jacob A. Grimmer scite author profile

Cigarette smoking is the most preventable risk factor related to cardiovascular morbidity and mortality. Tobacco usage has declined in recent years; however, the use of alternative nicotine delivery methods, particularly e-cigarettes, has increased exponentially despite limited data on their short- and long-term safety and efficacy. Due to their unique properties, the impact of e-cigarettes on cardiovascular physiology is not fully known. Here, we summarize both preclinical and clinical data extracted from short- and long-term studies on the cardiovascular effects of e-cigarette use. Current findings support that e-cigarettes are not a harm-free alternative to tobacco smoke. However, the data are primarily derived from acute studies. The impact of chronic e-cigarette exposure is essentially unstudied. To explore the uniqueness of e-cigarettes, we contemplate the cardiovascular effects of individual e-cigarette constituents. Overall, data suggest that exposure to e-cigarettes could be a potential cardiovascular health concern. Further preclinical research and randomized trials are needed to expand basic and clinical investigations before considering e-cigarettes safe alternatives to conventional cigarettes.

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Preconception Exposure to Fine Particulate Matter Leads to Cardiac Dysfunction in Adult Male Offspring

Tanwar

Adelstein

Grimmer

et al. 2018

JAHA

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Background Particulate matter (particles < 2.5 μm [ PM 2.5 ]) exposure during the in utero and postnatal developmental periods causes cardiac dysfunction during adulthood. Here, we investigated the potential priming effects of preconception exposure of PM 2.5 on cardiac function in adult offspring. Methods and Results Male and female friend leukemia virus b (FVB) mice were exposed to either filtered air ( FA ) or PM 2.5 at an average concentration of 38.58 μg/m 3 for 6 hours/day, 5 days/week for 3 months. Mice were then crossbred into 2 groups: (1) FA male × FA female (both parents were exposed to FA preconception) and, (2) PM 2.5male × PM 2.5female (both parents were exposed to PM 2.5 preconception). Male offspring were divided: (1) preconception FA (offspring born to FA exposed parents) and, (2) preconception PM 2.5 (offspring born to PM 2.5 exposed parents) and analyzed at 3 months of age. Echocardiography identified increased left ventricular end systolic volume and reduced posterior wall thickness, reduced %fractional shortening and %ejection fraction in preconception PM 2.5 offspring. Cardiomyocytes isolated from preconception PM 2.5 offspring showed reduced %peak shortening, −dL/dT, TPS 90 and slower calcium reuptake (tau). Gene and protein expression revealed modifications in markers of inflammation ( IL ‐6, IL ‐15, TNF α, NF қB, CRP , CD 26E, CD 26P, intercellular adhesion molecule 1, and monocyte chemoattractant protein‐1) profibrosis (collagen type III alpha 1 chain), oxidative stress ( NOS 2), antioxidants (Nrf2, SOD , catalase), Ca 2+ regulatory proteins ( SERCA 2a, p‐ PLN , NCX ), and epigenetic regulators (Dnmt1, Dnmt3a, Dnmt3b, Sirt1, and Sirt2) in preconception PM 2.5 offspring. Conclusions Preconception exposure to PM 2.5 results in global cardiac dysfunction in adult offspring, suggesting that abnormalities during development are not limit...

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PM 2.5 exposure in utero contributes to neonatal cardiac dysfunction in mice

Tanwar

Adelstein

Grimmer

et al. 2017

Environmental Pollution

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Objective Exposure of fine particulate matter (PM2.5) to pregnant dams has been shown to be strongly associated with adverse cardiovascular outcomes in offspring at adulthood, however, effects evident during neonatal periods are unclear. We designed this study to examine cardiac function of neonatal mice (14 days old) exposed to in utero PM2.5. Methods Pregnant FVB female mice were exposed either to filtered air (FA) or PM2.5 at an average concentration of 91.78 μg/m3 for 6h/day, 5 days/wk (similar to exposure in a large industrial area) throughout the gestation period (20 days). After birth, animals were analyzed at day 14 of life. Results Fourteen day old mice exposed to PM2.5 during in utero period demonstrated decreased fractional shortening (%FS, 41.1±1.2% FA, 33.7±1.2% PM2.5, p<0.01) and LVEDd (2.87±0.08 mm FA, 2.58±0.07 mm PM2.5, p<0.05) compared to FA exposed mice. Contractile kinetics and calcium transients in isolated cardiomyocytes from PM2.5 exposed mice illustrated reduced peak shortening (%PS, 16.7±0.5% FA, 14.7±0.4% PM2.5, p<0.01), negative contractile velocity (- dL/dT, -6.91±0.3 μm/s FA, -5.46±0.2 μm/s PM2.5, p<0.001), increased time to relaxation 90% (TR90, 0.07±0.003 s FA, 0.08±0.004 s PM2.5, p<0.05), decreased calcium transient amplitude (Δ340/380, 33.8±3.4 FA, 29.5±2.8 PM2.5) and slower fluorescence decay rate (τ, 0.72±0.1 s FA, 1.16±0.15 s PM2.5, p<0.05). Immunoblotting studies demonstrated alterations in expression of Ca2+ handling proteins- SERCA-2A, p-PLN, NCX and CaV1.2 in hearts of 14 day old in utero PM2.5 exposed mice compared to FA exposed hearts. Conclusion PM2.5 exposure during the critical in utero period adversely affects the developing mouse fetus leading to functional cardiac changes that were evident during the very early (14 days) stages of adolescence. These data demonstrated that exposure to PM2.5 during the gestation period significantly impacts cardiovascular outcomes early in life.

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Exercise does not ameliorate cardiac dysfunction in obese mice exposed to fine particulate matter

et al. 2019

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Jacob A. Grimmer

Cardiovascular risk of electronic cigarettes: a review of preclinical and clinical studies

Preconception Exposure to Fine Particulate Matter Leads to Cardiac Dysfunction in Adult Male Offspring

PM 2.5 exposure in utero contributes to neonatal cardiac dysfunction in mice

Exercise does not ameliorate cardiac dysfunction in obese mice exposed to fine particulate matter

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