Your search keyword '"Hamade, Ali"' showing total 4 results

1. Age-related changes in cardiac and respiratory adaptation to acute ozone and carbon black exposures: interstrain variation in mice.

Author

Hamade AK, Misra V, Rabold R, and Tankersley CG

Subjects

Adaptation, Physiological, Age Factors, Air Pollution, Animals, Heart Rate, Male, Mice, Mice, Inbred C3H, Mice, Inbred C57BL, Air Pollutants toxicity, Heart physiopathology, Ozone toxicity, Respiratory System physiopathology, Soot toxicity

Abstract

Context: Epidemiological studies show positive associations between increased ambient air pollutant levels and adverse cardiopulmonary effects. These studies suggest that the elderly and those with certain genetic polymorphisms are susceptible to adverse air pollution-associated health events., Hypothesis/objective: We hypothesize that physiological responses to air pollutants vary with age and are genetically influenced., Materials and Methods: To test this hypothesis, we exposed mice from three inbred strains (C57BL/6J, B6; C3H/HeJ, HeJ; C3H/HeOuJ, OuJ) to ozone (O(3)) and carbon black (CB) at two ages, (5 months, 12 months), for 3 consecutive days, to either filtered air (FA), CB particles, or O(3) and CB sequentially (O(3)CB) (CB, 550 µg/m(3); O(3), 600 ppb). Heart rate (HR), HR variability (HRV), breathing, and core temperature (Tco) responses were analyzed., Results: We observed time-dependent physiological changes in response to O(3)CB exposure in each strain, relative to FA exposure for both age groups. Each mouse strain showed distinct adaptation profiles to repeated acute exposures to O(3). In younger mice, several time-dependent effects (decreased HR and increased HRV) were prominent in HeJ and OuJ mice but not B6 mice. We also observed variability in adaptation in older mice. However, responses in older mice were generally attenuated when compared to the younger mice. In addition, cardiac-respiratory interactions were affected with CB and O(3)CB exposures albeit with patterns differing by age or exposure., Discussion/conclusion: Our results suggest that age considerably attenuates physiological responses to O(3) and O(3)CB exposures. Age-related physiological changes such as increased oxidative stress in mouse tissue may be involved in this attenuation.

Published

2010

2. Interstrain variation in cardiac and respiratory adaptation to repeated ozone and particulate matter exposures.

Author

Hamade AK and Tankersley CG

Subjects

Adaptation, Physiological, Animals, Atmosphere Exposure Chambers, Body Temperature drug effects, Body Weight drug effects, Circadian Rhythm drug effects, Echocardiography, Electrocardiography, Heart Rate genetics, Male, Mice, Mice, Inbred C3H, Mice, Inbred C57BL, Plethysmography, Respiratory Mechanics genetics, Species Specificity, Telemetry, Toll-Like Receptor 4 metabolism, Air Pollutants toxicity, Heart Rate drug effects, Inhalation Exposure, Ozone toxicity, Respiratory Mechanics drug effects, Soot toxicity

Abstract

Increased ambient particulate matter (PM) is associated with adverse cardiovascular and respiratory outcomes, as demonstrated by epidemiology studies. Several studies have investigated the role of copollutants, such as ozone (O(3)), in this association. It is accepted that physiological adaptation involving the respiratory system occurs with repeated exposures to O(3). We hypothesize that adaptation to PM and O(3) varies among different inbred mouse strains, and cardiopulmonary adaptation to O(3) is a synchronized response between the cardiac and respiratory systems. Heart rate (HR), HR variability (HRV), and the magnitude and pattern of breathing were simultaneously measured by implanted telemeters and by plethysmography in three inbred mouse strains: C57Bl/6J (B6), C3H/HeJ (HeJ), and C3H/HeOuJ (OuJ). Physiological responses were assessed during dual exposures to filtered air (FA), O(3) (576 +/- 32 parts/billion), and/or carbon black (CB; 556 +/- 34 mug/m(3)). Exposures were repeated for 3 consecutive days. While each strain showed significant reductions in HR during CB with O(3) preexposure (O(3)CB) on day 1, prominent HRV responses were observed in only HeJ and OuJ mice. Each strain also differed in their adaptation profile in response to repeated O(3)CB exposures. Whereas B6 mice showed rapid adaptation in HR after day 1, HeJ mice generally showed more moderate HR and HRV adaptation after day 2 of exposure. Unlike either B6 or HeJ strains, OuJ mice showed little evidence of HR or HRV adaptation to repeated O(3)CB exposure. Adaptation profiles between HR regulation and breathing characteristics were strongly correlated, but these associations also varied significantly among strains. These findings suggest that genetic factors determine the responsivity and adaptation of the cardiac and respiratory systems to repeated copollutant exposures. During O(3)CB exposure, adaptation of cardiac and respiratory systems is markedly synchronized, which may explain a potential mechanism for adverse effects of PM on heart function.

Published

2009

3. Adverse cardiovascular effects with acute particulate matter and ozone exposures: interstrain variation in mice.

Author

Hamade AK, Rabold R, and Tankersley CG

Subjects

Animals, Circadian Rhythm, Male, Mice, Mice, Inbred C3H, Mice, Inbred C57BL, Mice, Inbred Strains, Telemetry, Environmental Exposure, Heart Rate drug effects, Ozone toxicity, Particulate Matter toxicity, Soot toxicity

Abstract

Objectives: Increased ambient particulate matter (PM) levels are associated with cardiovascular morbidity and mortality, as shown by numerous epidemiology studies. Few studies have investigated the role of copollutants, such as ozone, in this association. Furthermore, the mechanisms by which PM affects cardiac function remain uncertain. We hypothesized that PM and O(3) induce adverse cardiovascular effects in mice and that these effects are strain dependent., Study Design: After implanting radiotelemeters to measure heart rate (HR) and HR variability (HRV) parameters, we exposed C57Bl/6J (B6), C3H/HeJ (HeJ), and C3H/HeOuJ (OuJ) inbred mouse strains to three different daily exposures of filtered air (FA), carbon black particles (CB), or O(3) and CB sequentially [O(3)CB; for CB, 536 +/- 24 microg/m(3); for O(3), 584 +/- 35 ppb (mean +/- SE)]., Results: We observed significant changes in HR and HRV in all strains due to O(3)CB exposure, but not due to sequential FA and CB exposure (FACB). The data suggest that primarily acute HR and HRV effects occur during O(3)CB exposure, especially in HeJ and OuJ mice. For example, HeJ and OuJ mice demonstrated dramatic increases in HRV parameters associated with marked brady-cardia during O(3)CB exposure. In contrast, depressed HR responses occurred in B6 mice without detectable changes in HRV parameters., Conclusions: These findings demonstrate that important interstrain differences exist with respect to PM- and O(3)-induced cardiac effects. This interstrain variation suggests that genetic factors may modulate HR regulation in response to and recuperation from acute copollutant exposures.

Published

2008

4. Heart Rate (HR) and Oxygen Consumption (VO2) Changes After Inhaled Ozone (O3) and Particulate Matter (PM) in Two Mouse Strains.

Author

Hamade, Ali K., Abston, Eric, Rabold, Richard, Rule, Ana, and Tankersley, Clarke

Subjects

*HEART beat, *OXYGEN, *OZONE, *AEROSOLS, *MICE

Abstract

O3 is a principal pollutant that coexists with PM in urban ambient air. Studies associate O3 and PM exposure with adverse health effects; however the mechanisms of action remain unclear. We implanted radiometers to measure HR, and then exposed two mouse strains (i.e. C3H/HeJ, C3 and C57Bl/6J, B6 [n=3/ strain]) to three different protocols for 3 consecutive days as follows: 1) 2 hr-filtered air (FA) + 3 hr-FA; 2) 2 hr-FA + 3 hr-carbon black (CB); and 3) 2 hr-ozone (O3, 550 ppb) + 3 hr-CB HR and VO2 were collected simultaneously on the mornings before and after exposure. We observed relative increases in O2-pulse,(VO2/HR) with FACB (4.9%±2.4), and O3CB (7.5%±6) independent of HR changes in the B6 mice. Correlations between HR and VO2 were also examined. The C3 mice did not exhibit obvious coupling of HR and VO2 (r²=0.16±0.06) at baseline or with treatment. The B6 animals, however, appear to inherently possess a high association between HR and VO2 (r²= 0.40±0.08) and this association changed dramatically with exposure: i.e., FACB (r²=0.13±0.06) and O3CB (r²=0.60±0.01) exposures. Thus, these results suggest that HR and VO2 coupling varies between inbred strains and among different pollutants. In terms of hemodynamic control, HR regulation is altered by air pollutant exposures such that a greater O2 delivery is required with each stroke of the heart. Future studies will aim to elucidate genetic factors that may modify individual responses and susceptibility to these air pollutants. [ABSTRACT FROM AUTHOR]

Published

2007