Effects of in vivo manganese administration on calcium exchange and contractile force of rat ventricular myocardium

Dudek, H.J.; Pytkowski, B

doi:10.1007/bf02190701

Cited by 9 publications

(12 citation statements)

References 28 publications

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“…Fourteen days following Mn exposure, the exchangeable Ca in the Mntreated group was increased by 52% as compared with controls. By recording the leftventricular pressure (dP/dt) via a balloon catheter inserted into the left ventricle, the authors also observed that the maximal ventricular developed pressure (P max ) and the maximal leftventricular pressure (dP/dt max ) were increased by 35% and 228%, respectively, in comparison with control rats, following 14 d of Mn administration (27).…”

Section: Mn Exposure and Cardiac Ca Statusmentioning

confidence: 94%

Cardiovascular Toxicities Upon Manganese Exposure

Jiang

Zheng

2005

116

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Manganese (Mn)-induced Parkinsonism has been well documented; however, little attention has been devoted to Mn-induced cardiovascular dysfunction. This review summarizes literature data from both animal and human studies on Mn's effect on cardiovascular function. Clinical and epidemiological evidence suggests that the incidence of abnormal electrocardiogram (ECG) is significantly higher in Mn-exposed workers than that in the control subjects. The main types of abnormal ECG include sinus tachycardia, sinus bradycardia, sinus arrhythmia, sinister megacardia, and ST-T changes. The accelerated heartbeat and shortened P-R interval appear to be more prominent in female exposed workers than in their male counterparts. Mn-exposed workers display a mean diastolic blood pressure that is significantly lower than that of the control subjects, especially in the young and female exposed workers. Animal studies indicate that Mn is capable of quickly accumulating in heart tissue, resulting in acute or sub-acute cardiovascular disorders, such as acute cardiodepression and hypotension. These toxic outcomes appear to be associated with Mn-induced mitochondrial damage and interaction with the calcium channel in the cardiovascular system.

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Section: Mn Exposure and Cardiac Ca Statusmentioning

confidence: 94%

Cardiovascular Toxicities Upon Manganese Exposure

Jiang

Zheng

2005

116

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“…The effects of long-lasting exposures are however less clear. A Mn++, intragastric ratfeeding study over 14 days (0.25 mmollkg daily) resulted in increased myocardial contractility (4). Work exposure to manganese was estimated from 339 personal samples of total dust and total manganese during 1979-1991 in the largest of the FeMnISiMn plants; the results showed decreasing values during this period ( figure I).…”

Section: Discussionmentioning

confidence: 99%

“…possible with exposure to manganese alloys, as animal studies have shown that the divalent manganese ion (Mn++) may influence cardiac function (3,4).…”

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confidence: 99%

Mortality from cardiovascular diseases and sudden death in ferroalloy plants

Hobbesland

Kjuus²,

Thelle³

1997

Scand J Work Environ Health

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Mortality from cardiovascular diseases and sudden death in ferroalloy plants by Hobbesland Objectives The aim of this study was to examine mortality from circulatory diseases and sudden death among workers in 12 Norwegian ferroalloy plants. Methods The cohort comprised 14 730 men employed for the first time during and for at least 6 months. Deaths observed during 1962-1990 were compared with expected figures calculated from national mortality rates. Internal cornparisoils of rates were performed by Poisson regression analysis. Results The overall mortality from cardiovascular diseases was not increased [standardized mortality ratio (SMR) 1.011, but a significantly increased mortality from sudden death (SMR 1.55) and hypertensive disease (SMR 1.37) was observed. Among the ferromanganeselsilicomanganese (FeMnISiMn) furnace worl

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“…41,47 It is known as an intracellular agent, rapidly up-taken (within minutes 8,29,54 ) by L-type Ca 2+ channels, 26 and released extremely slowly [within time intervals ‡5-10 min] (with reported excretion half-times of a fast and a slow component of 4 and 39 days, respectively 29 ) from the intracellular space via the Na + -Ca 2+ exchanger. 14,28,34 In fact, Mn 2+ accumulation in rat myocardium has been associated with the Na + -Ca 2+ exchanger, based on its MRI T 2 * effects under experimentally induced hyperkalemic hypoxia conditions. 35 In support of such action by the exchanger for Mn 2+ transport kinetics, were also sodium-potassium ATPase blockade studies in bullfrog ventricles by Brommundt et al, 5 as well as evidence for bidirectional activity of the Na + -Ca 2+ exchanger, mediating cellular Mn 2+ influx, and efflux.…”

Section: Abbreviationsmentioning

confidence: 99%

“…To date its exact mechanism of action is still not completely comprehended, but it is suggested to act as a Ca 2+ analogue. 14,26,56 Its effects on mouse cardiac function have not been addressed extensively, with its molecular mechanisms on intracellular targets being largely unknown and unproved. Based on experimental results from a series of invasive catheterizations, this study examines the temporal stability of hemodynamic indices of systolic and diastolic function in C57BL/6 mice under isoflurane (ISO) anesthesia conditions (employing the same protocol widely used in MRI/microCT studies), and the effects of Mn 2+ on the mouse hemodynamic response as a potential modulator of myocardial force generation.…”

Section: Abbreviationsmentioning

confidence: 99%

Murine Cardiac Hemodynamics Following Manganese Administration Under Isoflurane Anesthesia

2011

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This study examines (a) the temporal stability of hemodynamic indices of systolic and diastolic function in C57BL/6 mice under 1.5% isoflurane (ISO) (v/v) anesthesia conditions in 50:50 O(2)/N(2)O (v/v) within 90 min post-induction, and (b) the effects of Mn(2+) on the mouse hemodynamic response in male C57BL/6 mice (n = 16). Left ventricular catheterizations allowed estimation of the hemodynamic indices. Hypertonic saline infusion (10%) allowed absolute volume quantification in conjunction with a separate series of aortic flow experiments (n = 3). In a separate cohort of mice (n = 6), MnCl(2) (190 nmoles/g/bw) was infused via the left jugular for 29-39 min, following 11 min of baseline recording, to assess temporal responses. Stable temporal hemodynamic responses were achieved in control mice under ISO anesthesia. Hemodynamic indices during control, time-matched-control, baseline-Mn, and Mn-infused periods, were within normal expected ranges. No chronotropic changes were observed. Significant differences in systolic and diastolic cardiac indices of function (HR, EF, ESP, dP/dt (max), dP/dt (min), PAMP, τ(glantz), and τ(weiss)) resulted between baseline-Mn and Mn-infused time periods in Mn-treated mice at the 1% significance (p < 0.001). Transient positive, or negative, or positive followed by negative evoked pressure-volume loop shifts were observed (exemplified through changes in the end-systolic pressure-volume relationship and dP/dt (max)) in Mn-infusion studies. It is concluded that Mn(2+) can be used safely for prolonged mouse imaging studies, however, the significant variations elicited in cardiovascular hemodynamics post-manganese infusion, necessitate further investigations for its suitability and appropriateness for quantification of global cardiac function in image-based phenotyping.

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Effects of in vivo manganese administration on calcium exchange and contractile force of rat ventricular myocardium

Cited by 9 publications

References 28 publications

Cardiovascular Toxicities Upon Manganese Exposure

Cardiovascular Toxicities Upon Manganese Exposure

Mortality from cardiovascular diseases and sudden death in ferroalloy plants

Murine Cardiac Hemodynamics Following Manganese Administration Under Isoflurane Anesthesia

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