Skip to main content
Erschienen in:

Open Access 09.09.2021 | Original Article

Chronic Diclofenac Exposure Increases Mitochondrial Oxidative Stress, Inflammatory Mediators, and Cardiac Dysfunction

verfasst von: Phung N. Thai, Lu Ren, Wilson Xu, James Overton, Valeriy Timofeyev, Carol E. Nader, Michael Haddad, Jun Yang, Aldrin V Gomes, Bruce D. Hammock, Nipavan Chiamvimonvat, Padmini Sirish

Erschienen in: Cardiovascular Drugs and Therapy | Ausgabe 1/2023

Abstract

Purpose

Nonsteroidal anti-inflammatory drugs (NSAIDs) are among one of the most commonly prescribed medications for pain and inflammation. Diclofenac (DIC) is a commonly prescribed NSAID that is known to increase the risk of cardiovascular diseases. However, the mechanisms underlying its cardiotoxic effects remain largely unknown. In this study, we tested the hypothesis that chronic exposure to DIC increases oxidative stress, which ultimately impairs cardiovascular function.

Methods and Results

Mice were treated with DIC for 4 weeks and subsequently subjected to in vivo and in vitro functional assessments. Chronic DIC exposure resulted in not only systolic but also diastolic dysfunction. DIC treatment, however, did not alter blood pressure or electrocardiographic recordings. Importantly, treatment with DIC significantly increased inflammatory cytokines and chemokines as well as cardiac fibroblast activation and proliferation. There was increased reactive oxygen species (ROS) production in cardiomyocytes from DIC-treated mice, which may contribute to the more depolarized mitochondrial membrane potential and reduced energy production, leading to a significant decrease in sarcoplasmic reticulum (SR) Ca2+ load, Ca2+ transients, and sarcomere shortening. Using unbiased metabolomic analyses, we demonstrated significant alterations in oxylipin profiles towards inflammatory features in chronic DIC treatment.

Conclusions

Together, chronic treatment with DIC resulted in severe cardiotoxicity, which was mediated, in part, by an increase in mitochondrial oxidative stress.
Hinweise

Supplementary Information

The online version contains supplementary material available at https://​doi.​org/​10.​1007/​s10557-021-07253-4.

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Introduction

Nonsteroidal anti-inflammatory drugs (NSAIDs) are widely available over the counter and commonly prescribed in the USA [1]. Although they have a relatively good safety profile, their widespread availability, uncontrolled disposal, and improper usage can be detrimental to the environment and human health. Indeed, improper disposal of these drugs leads to their accumulation in the water system [2], that are harmful to human health [3]. Additionally, since NSAIDs are so common and exist in many varieties that are often prescribed with other drugs, it is easy to unknowingly exceed the recommended dosage [4]. One of the known adverse effects of taking NSAIDs is elevated risks for cardiovascular complications, such as elevated blood pressure and myocardial infarction [5]. However, the exact mechanism underlying the increased susceptibility to these cardiovascular events is not completely understood.
One of the critical signaling pathways activated during inflammation is the arachidonic acid (ARA) pathway. NSAIDs exert their inflammatory actions by targeting the enzymes cyclooxygenase (COX)-1 and COX-2 in the ARA metabolic pathway. Although NSAIDs predominantly induce their effects on these enzymes, they do so with varying degrees [6]. The actions of COX-1 and COX-2 on ARAs result in the production of prostaglandins and thromboxane including prostaglandin E2 (PGE2), prostaglandin D2 (PGD2), prostaglandin F (PGF), prostacyclin (PGI2), thromboxane (TXA2), and related compounds that contribute to the inflammatory response [7]. Indeed, the differential level of inhibition as well as differential inhibition of COX-1 and COX-2 may produce varying toxicity [8]. Additionally, with the widespread availability of NSAIDs, their common usage, and improper disposal, the cumulative, inhibitory effects of the COX enzymes can result in profound cardiovascular consequences.
Recent emerging evidence has suggested that inhibition of the COX enzymes induces oxidative stress [9]. The mitochondria are the primary site for reactive oxygen species (ROS) production through their role in energy generation. This energy generation, although efficient, is prone to produce ROS, which normally are scavenged and detoxified by the cellular antioxidant system [10]. Under conditions of increased chronic oxidative stress, however, ROS generation can be overwhelming and detrimental to cellular function and may induce apoptosis [11]. Previous studies have demonstrated that ROS can directly increase the production of extracellular matrix as well as mitochondrial structural and membrane potential damage, leading to cardiac fibrosis [12]. Since the heart is an energetically demanding organ, it is comprised of a dense network of mitochondria. It is estimated that about 25–30% of the cardiomyocytes volume is occupied by mitochondria [13] and the heart is particularly susceptible to damage through oxidative stress, which can result in a plethora of cardiovascular complications including cardiac fibrosis and dysfunction [14]. It is well documented that the risk for cardiovascular events increases with the usage of NSAIDs [15]; however, it remains unclear what are the underlying mechanisms.
A recent in vitro study involving exposure of immortalized human cardiomyocytes to diclofenac (DIC) demonstrated an increase in ROS production, a decrease in mitochondrial membrane potential, and cardiotoxicity leading to cell death [16]. In our study, we tested the hypothesis that chronic treatment with a commonly prescribed NSAID, DIC, increases oxidative stress, which ultimately impairs cardiac function in vivo. Chronic treatment with DIC results in significant systolic and diastolic dysfunction as assessed by in vivo echocardiography with a marked decrease in single-cell shortening and Ca2+ transients. Metabolomic profiling, single-cell flow cytometric analyses, and mitochondrial function were performed to determine the underlying mechanisms of cardiac dysfunction.

Materials and Methods

Echocardiography

Eight to 12-week-old male and female C57BL/6 mice were treated with DIC (15 mg/kg/day) or vehicle alone in drinking water for 4 weeks based on our previous studies and subsequently monitored in accordance with approved protocols of the IACUC Committee at the University of California, Davis. Systolic function (M-mode images) was measured in conscious mice and diastolic function (pulse-wave Doppler and tissue Doppler) was measured in the presence of 0.5–1% isoflurane.

Blood Pressure Recordings

Mice were acclimated to the non-invasive, tail vein blood pressure recording system (Kent Scientific Corporation) for 5 days before actual measurements were taken.

Mitochondrial Membrane Potential

Mitochondrial membrane potential was assessed in freshly isolated control and DIC-treated cardiomyocytes using tetramethylrodamine ester (TMRM) [17]. Cardiomyocytes were incubated with TMRM and the recordings analyzed using ImageJ FIJI Software.

Mitochondrial Ca2+ Uptake

Mitochondrial Ca2+ uptake was monitored in freshly isolated control and DIC-treated cardiomyocytes using X-Rhod-1 AM (ThermoFisher Scientific) [17]. Cells were loaded with X-Rhod-1 AM for 40 min at 37 °C. Mitochondrial Ca2+ uptake was monitored by the change in fluorescence intensity, normalized to the baseline fluorescence intensity, after the addition of 5 μM Ca2+ and 10 μM Ca2+.

ROS Production

Superoxide generation was monitored in freshly isolated control and DIC-treated cardiomyocytes using MitoSox Red (ThermoFisher Scientific) [17]. Intact cells were loaded with MitoSox Red for 30 min at 37 °C. ROS generation was monitored after field stimulation (0.5 Hz and 4 Hz) and application of 100 nM isoproterenol in intracellular solution.

Cardiomyocyte Shortening, Ca2+ Transient (CaT), and Sarcoplasmic Reticulum (SR) Load

Cell shortening, CaT, and SR load were detected using IonOptix system [18] from freshly isolated cardiomyocytes from control and DIC-treated mice. Cell contraction was measured using a high-speed video camera to record sarcomere movement. The sarcomere was used to calculate the sarcomere length using the FFT algorithm. For CaT and SR load experiments, cells were loaded with Fluo-4 and paced at 10 V at a frequency of 0.5 Hz. To induce maximum sarcoplasmic reticulum, 20 mM caffeine was applied.

Flow Cytometry Analyses of Cardiac Fibroblasts and Cardiomyocytes

Isolated cardiac cells from control and DIC-treated mice were filtered through 200-µm cell strainer, re-suspended in Ca2+ and Mg2+ free phosphate-buffered saline (PBS), fixed with 0.4% paraformaldehyde, before treating with antibodies.

Plasma Cytokine Levels

Plasma cytokine levels from samples collected 4 weeks after DIC treatment were analyzed using a Cytometric Bead Array kit and FCAP Array software following the manufacturer's protocol [19].

Metabolomic Profiling of Oxylipins

Oxylipin profiling was performed using a modification of a previously published method [19, 20].

Statistical Analysis

All data are reported as mean ± standard error, unless otherwise stated. Statistical comparisons were analyzed by Student’s t-tests or one-way ANOVA followed by Bonferroni tests for post hoc comparison using GraphPad Prism version 9 (San Diego, CA). Multivariate statistical analysis was performed using MetaboAnalyst version 5.0 to analyze the distinct clustering among groups. Oxylipins were represented on a heat map using Euclidean distance and Ward’s clustering. Unsupervised principal component analysis (PCA) was performed to identify possible trends. Partial least-squares discriminant analysis (PLS-DA) was applied to test the differences between control and DIC-treated groups. Validation of the model was performed using R2 and Q2 values derived from cross-validation algorithm. Statistical significance was considered to be achieved when P < 0.05.

Results

Chronic DIC-Treated Mice Exhibited Impaired Cardiac Function

Recent evidence has suggested that inhibition of COX induces oxidative stress [9]. Since the heart relies on a dense network of mitochondria to supply energy, elevated oxidative stress is especially detrimental to the constantly beating heart. To investigate whether chronic DIC treatment affects cardiovascular function, mice were treated with (15 mg/kg/day) DIC for 4 weeks and subsequently monitored. The dosage was selected based on prior studies [21, 22]. Whole heart images showed no evidence of cardiac hypertrophy or chamber dilatation with no significant differences in the heart weight/body weight ratios between chronic exposure group and control (Figures S1A-D). However, there was a significant increase in mortality in the DIC-treated group (Figure S1E). Of those mice that survived, echocardiographic measurements revealed severely depressed cardiac function. Representative M-mode tracing at the parasternal short axis is shown for the two groups (Fig. 1a). Recordings were performed in conscious mice to eliminate the effects of volatile anesthetic [23]. There were no significant changes in heart rate in the chronic exposure group (Fig. 1b); however, left ventricular mass was significantly higher in DIC-treated mice, with a concomitant decrease in fractional shortening and ejection fraction (Fig. 1c–e). Diastolic function was also assessed by monitoring blood flow velocity through the mitral valve (MV) during early (E wave) and late diastole (A wave) as shown in the representative images in Fig. 1f. With treatment, there was a decline in the MV E/A ratio (Fig. 1g) with a prolongation of the E-wave deceleration time (Fig. 1h) and isovolumetric relaxation time (Fig. 1i). Together, these data suggest that chronic DIC treatment impaired both systolic and diastolic function.
Additionally, NSAIDs have been shown to elevate blood pressure [24] and increase the risk of cardiac arrhythmias [3, 25]. We measured systolic and diastolic blood pressure using tail cuffs. Mice were acclimated with the procedure 5 days prior to blood pressure recordings. Training was done using positive reinforcement. Under our treatment regimen, chronic treatment did not affect systolic and diastolic blood pressure (Fig. 1j). In addition, we recorded ECGs in anesthetized mice after 4 weeks of treatment. Representative ECG traces are shown in Fig. 1k. There were no significant differences in RR, PR, and QTc intervals (Fig. 1l). Taken together, our data suggest that chronic exposure to DIC depressed cardiac contractile function, but did not affect systemic blood pressure or heart rate or rhythm.

Mechanistic Underpinnings of the Observed Systolic and Diastolic Dysfunction in Chronic DIC Exposure Mice, Revealed Using Single-Cell Shortening and Ca2+ Transients Analyses

To determine the mechanisms underlying the observed systolic and diastolic dysfunction in the chronic DIC-treated group, we took advantage of single-cell analyses to quantify sarcomere shortening and Ca2+ dynamics using IonOptix system. In corroboration with our echocardiography data, cardiomyocytes isolated from DIC-treated mice exhibited reduced cell shortening as shown in Fig. 2a. Quantitatively, percentages of cell shortening were significantly decreased with treatment (Fig. 2b, p < 0.0001). Moreover, the time to reach 50% of the peak amplitude (Fig. 2c) and the decay time to 50%, 70%, and 90% from peak amplitude were significantly prolonged in treated cardiomyocytes (Fig. 2d).
Since Ca2+ plays a pivotal role in mediating cellular contractility, we examined Ca2+ transients and the sarcoplasmic reticulum (SR) Ca2+ load. Representative traces of Ca2+ transient recordings are shown in Fig. 2e. There was a significant decrease in the peak amplitude of the Ca2+ transients in DIC-treated cardiomyocytes (Fig. 2f). Although there were no changes in the time-to-peak amplitude in treated cardiomyocytes (Fig. 2g), the decay time was significantly prolonged in the treated cardiomyocytes (Fig. 2h). To acquire the SR Ca2+ load, we applied caffeine to induce maximal release of Ca2+ from the SR, as shown by the representative traces in Fig. 2i–j. Chronic DIC treatment significantly decreased the SR Ca2+ load (Fig. 2j). However, there were no changes in the kinetics in the presence of caffeine (Fig. 2k-l), suggesting no significant changes in the Na+-Ca2+ exchange activities. Therefore, the significant decrease in SR Ca2+ load is likely a result of a decrease in SR Ca2+-ATPase (SERCA) activities, a well-described remodeling of Ca2+ cycling proteins in cardiac hypertrophy and failure [26]. Together, our data demonstrate that chronic DIC treatment significantly reduced SR Ca2+ load, leading to a reduction in Ca2+ transients and single-cell shortening as well as prolongation of the decay kinetics of both sarcomere shortening and Ca2+ transients (Fig. 2c and h). The net effects are systolic and diastolic dysfunction as we have demonstrated at the in vivo level.

Chronic DIC Treatment Increased Cardiac Fibroblast Proliferation

Since DIC has been associated with increase cardiovascular risk [3, 27], and we found that DIC treatment resulted in impaired systolic and diastolic cardiac function, we investigated structural changes in the heart. Cardiac fibroblasts are the most important contributors of the collagen matrix deposition. To evaluate structural changes, cardiac sections from control and DIC-treated mice were stained with Masson’s Trichrome (Figure S1F). Since collagen staining was not evident in the cardiac sections, increase in cardiac fibroblasts was quantified using flow cytometry from isolated cardiac cells. We have previously characterized cardiac fibroblasts as cells expressing Thy1.2+/Lin/CD45/CD31 using flow cytometry [19]. When digested single cells from control and DIC-treated mice were analyzed by flow cytometry, we saw a significant increase in percentages of fibroblasts in the DIC-treated group compared to the control (Control 36 ± 1%, DIC 42 ± 1%, Fig. 3a–b). We further utilized Ki67 to analyze the proliferative capacity among cardiac fibroblasts with DIC treatment. There was a significant increase in the percentage of Ki67 in the DIC-treated fibroblasts compared to control (Control 2 ± 0.5%, DIC 6 ± 1%, Fig. 3c–d).

Chronic DIC Treatment Increased Oxidative Stress in Fibroblasts and Cardiomyocytes

Exposure to DIC has been shown to increase oxidative stress. Increased levels of ROS lead to dysfunction of multiple biological signaling pathways[16, 21]. Therefore, we quantified the level of ROS in cardiac cells, specifically cardiomyocytes and fibroblasts. Analysis of cardiomyocytes from the DIC-treated and control groups revealed a significant increase in ROS in DIC-treated cardiomyocytes compared to control cardiomyocytes (Fig. 3e–f). We also demonstrate a significant increase in ROS in DIC-treated fibroblasts compared to control fibroblasts (Fig. 3g–h).
Increase in ROS has been shown to activate members of the mitogen-activated protein kinase (MAPK) signaling cascade [21]. Therefore, we investigated the activation of downstream members of the MAPK cascade, the extracellular signal-regulated kinase 1 and 2 (ERK1/2) in fibroblasts and cardiomyocytes. Here, there was a significant increase in pERK1/2 in DIC-treated cardiomyocytes (Fig. 3i–j). Similarly, there was a significant elevation in the levels of phosphorylated ERK1/2 (pERK1/2) in fibroblasts (Control 5 ± 0.5% vs. DIC 10 ± 1%, Fig. 3k–l).

Chronic DIC Treatment Impaired Mitochondrial Function

As an energetically demanding organ, the heart is densely packed with mitochondria. Proper communication with these mitochondria is crucial for sufficient energy production on a beat-to-beat basis [28]. To determine the effects of DIC treatment on mitochondrial function, we examined mitochondrial membrane potential, Ca2+ uptake, ROS production, and ATP level. We demonstrate that with DIC treatment, mitochondrial membrane potential was significantly depolarized (Fig. 4a). Additionally, permeabilized DIC-treated cardiomoycytes exhibited reduced mitochondrial Ca2+ uptake when challenged with 5 and 10 μM of Ca2+, as shown in the representative traces and quantitatively (Fig. 4b–c). Since ROS is known to increase after β-adrenergic receptor stimulation and cellular stress, [29] we subjected cardiomyocytes to both isoproterenol (ISO) and field stimulation (FS). With 100 nM ISO and 0.5 Hz FS, we observed a significant increase in ROS in chronic DIC-treated cardiomyocytes relative to control, as depicted in Fig. 4d. Even with an increase in FS to 2 Hz, treated cardiomoycytes still exhibited higher ROS generation relative to control (Fig. 4e). Since reduced mitochondrial Ca2+ uptake and elevated ROS generation can impair energy production, [30] we directly monitored the ATP level after Complex I (5 mM pyruvate/5 mM malate) and Complex II (5 mM succinate) mediated respiration. With Complex I substrates, the ATP generation was significantly lower in the treated cardiomyocytes (Fig. 4f). This was also seen after using Complex II substrate. Together, these data suggest that mitochondrial function was significantly impaired, at least in part, due to a significant increase in ROS generation, that may further contribute to an increase in mitochondrial oxidative stress.

Chronic DIC Treatment Alters the Oxylipin Profile and Increases Inflammatory Cytokines

Polyunsaturated fatty acids including ARA, eicosapentaenoic acid (EPA), docosahexaenoic acid (DHA), linoleic acid (LA), and α-linolenic acid (ALA) can be metabolized via three pathways by the COX, LOX, and CYP450 enzymes. Since these three enzymatic pathways share the same substrates, to determine the underlying mechanism of the cardiotoxicity with chronic exposure to DIC, we analyzed the oxylipin metabolites from ARA, EPA, DHA, LA, and ALA, many of which are targeted by DIC. Sixty oxylipins were analyzed by ultrahigh-pressure LC/MS/MS from chronic DIC-treated and control plasma samples [19]. DIC-treated mice showed a significant decrease in prostanoids (PGD2, PGE2, PGF, TXB2, 6-keto-PGF, and 8-iso-PGF), consistent with the COX enzymes targeting effects of DIC (Fig. 5a). Unsupervised PCA revealed a separation of samples based on DIC treatment and control groups (Fig. 5b).
Indeed, a hierarchical cluster analysis using Ward’s algorithm showed clustering of metabolites from the DIC-treated group, that was separated from clustering of metabolites from the control group (Fig. 5c, green-DIC and red-control). To further explore these differences, a PLS-DA was performed. This resulted in a four-component model with a goodness of prediction Q2 of 0.28 and a goodness of fit R2 of 0.71 (Fig. 5d).
Of interest in cardioprotection is the metabolism of ARA by CYP450 enzymes to epoxyeicosatrienoic acidsepoxyeicosatrienoic acids (EETs), that are known to anti-inflammatory metabolites. However, EETs are further metabolized into dihydroxyeicosareinoic acid (DHETs) with diminished cardioprotective activities. Therefore, to understand the effect of DIC treatment on ARA and CYP450 pathway, we analyzed the EETs/DHETs ratio. Our analysis demonstrated a significant decrease in the 14,15-EET/DHET ratio in the DIC-treated groups compared with control group (Figure S2A). Moreover, metabolites of the LOX pathways demonstrated a modest difference between the two groups (Figure S2B).
While DIC suppresses inflammation, chronic DIC treatment is associated with increased levels of inflammatory cytokines including TNF-α [22]. Our data demonstrate a significant increase in proinflammatory cytokine and chemokine levels including interleukin 6 (IL-6), interferon-γ (IFN-γ), TNF-α, and monocyte chemoattractant protein-1 (MCP-1) in the DIC-treated mice compared to controls (Fig. 5e–h).

Discussion

The widespread availability, usage, and improper disposal of NSAIDs are not only detrimental to the environment [2], but also harmful to humans [24]. The cardiotoxic effects of NSAIDs vary among individual drug and also is dose-dependent. In the current study, we demonstrate that 4 weeks of chronic exposure to DIC, a commonly prescribed NSAID, and in terms of tonnage, one of world’s major medication, result in impaired cardiac systolic and diastolic function (Fig. 1), as well as increased cardiac fibroblast proliferation (Fig. 3). Although the risk of cardiovascular complications such as blood pressure elevation [24] and arrhythmias [3, 25] is higher in patients who take NSAIDs, we did not observe any differences in blood pressure or any arrhythmias in the mice that were treated relative to control mice. This is likely attributed to the regimen chosen. However, the 4-week treatment plan was chosen to investigate DIC-induced cardiotoxicity, since we observed an increase in mortality of mice with this schedule (Figure S1B). Further investigation demonstrated that chronic DIC treatment severely affected the digestive system, manifested by ischemic colitis in treated mice that did not survive the 4-week treatment regimen. The effect of NSAIDs on the gastrointestinal tract (GI) is due to the unique local environment, the pharmacokinetics of the drugs, and mitochondrial dysfunction. The effects in the GI tract may result in high mortality in mice treated with DIC and not cardiac dysfunction alone. The decreased levels of prostanoids, in particular PGE2 with COX inhibition, lead to removal of the protection in the GI, leading to gastric ulcers and erosion of gastric cells [31]. The accumulation of NSAIDs in the GI lining independently causes mitochondrial dysfunction, leading to GI damage [32].

Diclofenac and Ca2+ Handling

Ca2+ handling is tightly regulated for normal cardiac function. Since Ca2+ is an important regulator that mediates an array of cardiac signaling pathways [33], alterations in Ca2+ can result in severe cardiac consequences [34]. Indeed, one primary role of Ca2+ in the heart is to couple energy production with energy demand [35], which involves proper Ca2+ communication between the SR and the mitochondria at microdomains [36]. It has been reported that DIC inhibits L-type Ca2+ channels in cardiomyocytes [37], which likely affects Ca2+-induced Ca2+ release from the SR. Indeed, our in vitro findings showed isolated cardiomyocytes from treated mice exhibited impaired Ca2+ transient peak amplitude and kinetics, as well as depressed sarcoplasmic reticulum (SR) load (Fig. 2).
It has been shown that Ca2+ entry into the mitochondria is crucial for activating key dehydrogenases, which subsequently increases production of reduced NADH and FADH2 to further fuel oxidative phosphorylation [38]. Along with the reduced Ca2+ transient peak amplitude, we found depressed mitochondrial Ca2+ uptake when challenged with increasing concentrations of external Ca2+, which suggests impaired communication with the SR and mitochondria with chronic DIC treatment (Fig. 4). Additionally, our data demonstrate that chronic DIC treatment reduced ATP levels after Complex I and Complex II mediated respiration in isolated cardiomyocytes. Although a reduction in Ca2+ transient, SR load, and reduced ability of mitochondria to uptake Ca2+ contribute to lower energy production, ROS production can also impair mitochondrial function.

Diclofenac and Oxidative Stress

DIC has been shown to increase the production of ROS in several cell types including mouse neonatal cardiomyocytes [21]. Members of the MAPK signaling pathway induce cardiac fibrosis by activating the proliferation and collagen production of cardiac fibroblasts [39]. Specifically, an increase of ERK1/2 activity activated by increased ROS enhances cardiac fibroblast proliferation and thereby cardiac fibrosis and dysfunction [19, 20]. In response to increased ROS, fibroblasts can produce proinflammatory chemokines and chemokines, leading to exacerbation of cardiac dysfunction. Our study shows a significant increase in ROS and a concomitant increase of activated ERK1/2 in cardiomyocytes and fibroblasts from mice treated with DIC (Fig. 3). The elevated ROS levels and the activation on ERK1/2 in our study suggest that increase in cardiac fibroblast proliferation was partly due to the activation of the MAPK signaling cascade initiated by ROS.
Furthermore, we found that mitochondrial membrane potential (ΔΨm) from DIC-treated mice was severely more depolarized than control mitochondria (Fig. 4), which suggests impaired mitochondrial function. A previous study has found that elevated levels in PGE2 can dissipate membrane potential, [40] which may partly explain our depolarized mitochondrial membrane potential. Similarly, a recent study by Barndolini et al., evaluating the effects of ketoprofen and DIC in immortalized human cardiomyocytes, demonstrates a decrease in mitochondrial potential. One possible underlying mechanism may be due to the opening of the mitochondrial permeability transition pores promoted by the Ca2+ accumulation in mitochondria. [16]
Indeed, mitochondria from DIC-treated mice were more susceptible to ROS generation under basal conditions and after β-AR stimulation and field stimulation. Mitochondrial permeability transition pores are stimulated by mitochondrial Ca2+ accumulation to facilitate the free passage of low molecular weight compounds between the inner mitochondrial matrix and the cytosol [16]. The underlying mechanism of DIC-dependent depolarization may in part be due to inefficient opening of the mitochondrial permeability transition pores, which is exacerbated by impaired mitochondrial Ca2+ uptake shown in our study.
It has been reported that DIC toxicity was evident in the ultrastructure of livers from chicks fed a DIC diet [41]. In addition to multiple structural alterations in the organelles, the authors noted the prevalence of diminished mitochondrial membrane integrity. These structural alterations due to DIC toxicity can lead to impaired mitochondrial function, as supported in our study. Furthermore, another study found that glutathione (GSH), a necessary component in the cellular antioxidant machinery, is able to mitigate some of DIC-induced inhibitory effects of ATP production in rat liver mitochondria [42]. In alignment with our study, we found that in addition to decreased ATP levels with DIC treatment, there was also a significant increase in ROS generation. Our data therefore strongly suggest that mitochondrial function was overall impaired due to chronic DIC treatment, in part, by an increase in oxidative stress.

Important Insights into the Mechanisms Underlying Mitochondrial Dysfunction from Chronic DIC Exposure Using Metabolomic Analyses

Polyunsaturated fatty acids including ARA, EPA, DHA, LA, and ALA can be metabolized via three broad pathways governed by COX, LOX, and CYP450 enzymes to yield prostaglandins, leukotrienes, EETs, and hydroxyeicosatetraenoic acid (HETE) [43]. The imbalance arising due to COX inhibition between prostaglandins (anti-thrombogenic) and thromboxanes (thrombogenic) is one of the main causes of thrombotic events, which increases the cardiovascular risk with COX inhibition [44]. However, DIC not only inhibits the COX-1 and COX-2 enzymes, but also affects other pathways including LOX and CYP450 leading to a decrease in the cardioprotective anti-inflammatory metabolites [44]. We have extensively shown that EETs, the CYP450 metabolites, are anti-inflammatory and cardioprotective in preventing ventricular hypertrophy, electrical remodeling, and cardiac fibrosis and reducing both atrial and ventricular arrhythmia inducibility in cardiac hypertrophy and MI models [19, 20, 45]. Our results in this study demonstrate a decrease in EETs isomers with DIC treatment (Figure S3A) suggesting a reduction in cardioprotection with DIC treatment.
HETEs (12-HETE and 15-HETE), which are metabolized through the LOX pathway, cause mitochondrial dysfunction by decreasing mitochondrial respiration and transmembrane potential [46]. An increase in HETEs (8-, 9-, 12- and 15-HETEs, Figure S3B) and a more depolarized mitochondrial potential with DIC treatment in our study suggest that DIC increases mitochondrial ROS through modifications in oxylipin levels. It has been shown that mitochondrial ROS not only activates PGE synthase, which provides substrate for COX-1 and COX-2, but also increases COX-2 gene expression [47, 48]. Thus, paradoxically, DIC induces the production of COX in multiple ways; the same enzyme that DIC is used to inhibit.

Mitochondrial Oxidative Stress, Inflammatory Mediators, and Cardiac Fibrosis

Mitochondrial oxidative stress and inflammation have both been implicated in the development of cardiac dysfunction leading to chronic heart failure[49]. The mitochondrial electron transport chain is a predominant source of intracellular ROS. Mitochondrial ROS activate the release of molecules known as danger-associated molecular patterns (DAMPs), that directly trigger the production of proinflammatory cytokines through the activation of inflammasome, leading to cardiac dysfunction[50]. The critical roles of mitochondrial ROS in the induction of cardiac fibrosis and hypertrophy leading to heart failure have been demonstrated [12]. In our study, we demonstrate that chronic exposure of DIC increases mitochondrial ROS production and cardiac fibroblast proliferation and activation. Future studies are needed to determine a direct causal effect of increased mitochondrial ROS production on cardiac fibrosis, leading to cardiac dysfunction by chronic DIC exposure.

Conclusions

We demonstrate that chronic treatment with DIC results in impaired cardiac function. In corroboration with this finding, our in vitro data in isolated cardiomyocytes show reduced cell shortening and impaired Ca2+ dynamics at the cellular level. With DIC treatment, mitochondrial membrane potential becomes depolarized and ATP production is diminished. Moreover, cardiomyocytes exhibit increased ROS and mitochondria from DIC-treated mice show increased susceptibility to ROS generation after application of a β-AR agonist along with field stimulation. Taken together, our data suggest that chronic DIC treatment results in elevated oxidative stress and altered oxylipin profiles towards inflammatory features, which contributed to mitochondrial dysfunction and ultimately impaired cardiac function.

Acknowledgements

We would like to thank Chandra Reid for her continued administrative support. The MF20 monoclonal antibody developed by Donald A. Fischman was obtained from Developmental Studies Hybridoma Bank developed under the auspices of the NICHD and maintained by The University of Iowa, Department of Biology, Iowa City, IA-52242.

Declarations

Ethics Approval

All animal work was performed in accordance with approved protocols of the Institutional Animal Care and Use (IACUC) Committee at the University of California, Davis, which adheres to the guidelines published by the US National Institutes of Health (8th Edition).
Not applicable.
Not applicable.

Conflict of Interest

The authors declare no competing interests.

Research Involving Human Subjects

Not applicable.
Not applicable.
Open AccessThis article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://​creativecommons.​org/​licenses/​by/​4.​0/​.

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Unsere Produktempfehlungen

e.Med Interdisziplinär

Kombi-Abonnement

Jetzt e.Med zum Sonderpreis bestellen!

Für Ihren Erfolg in Klinik und Praxis - Die beste Hilfe in Ihrem Arbeitsalltag

Mit e.Med Interdisziplinär erhalten Sie Zugang zu allen CME-Fortbildungen und Fachzeitschriften auf SpringerMedizin.de.

e.Med Innere Medizin

Kombi-Abonnement

Mit e.Med Innere Medizin erhalten Sie Zugang zu CME-Fortbildungen des Fachgebietes Innere Medizin, den Premium-Inhalten der internistischen Fachzeitschriften, inklusive einer gedruckten internistischen Zeitschrift Ihrer Wahl.

Alle e.Meds Abos jetzt 100 € günstiger!

Anhänge

Supplementary Information

Below is the link to the electronic supplementary material.
Literatur
1.
Zurück zum Zitat Wongrakpanich S, Wongrakpanich A, Melhado K, Rangaswami J. A comprehensive review of non-steroidal anti-inflammatory drug use in the elderly. Aging Dis. 2018;9(1):143–50.CrossRef Wongrakpanich S, Wongrakpanich A, Melhado K, Rangaswami J. A comprehensive review of non-steroidal anti-inflammatory drug use in the elderly. Aging Dis. 2018;9(1):143–50.CrossRef
2.
Zurück zum Zitat Gonzalez-Rey M, Bebianno MJ. Effects of non-steroidal anti-inflammatory drug (NSAID) diclofenac exposure in mussel Mytilus galloprovincialis. Aquat Toxicol. 2014;148:221–30.CrossRef Gonzalez-Rey M, Bebianno MJ. Effects of non-steroidal anti-inflammatory drug (NSAID) diclofenac exposure in mussel Mytilus galloprovincialis. Aquat Toxicol. 2014;148:221–30.CrossRef
3.
Zurück zum Zitat Schmidt M, Christiansen CF, Mehnert F, Rothman KJ, Sørensen HT. Non-steroidal anti-inflammatory drug use and risk of atrial fibrillation or flutter: population based case-control study. BMJ. 2011;343:d3450.CrossRef Schmidt M, Christiansen CF, Mehnert F, Rothman KJ, Sørensen HT. Non-steroidal anti-inflammatory drug use and risk of atrial fibrillation or flutter: population based case-control study. BMJ. 2011;343:d3450.CrossRef
4.
Zurück zum Zitat Kaufman DW, Kelly JP, Battista DR, Malone MK, Weinstein RB, Shiffman S. Exceeding the daily dosing limit of nonsteroidal anti-inflammatory drugs among ibuprofen users. Pharmacoepidemiol Drug Saf. 2018;27(3):322–31.CrossRef Kaufman DW, Kelly JP, Battista DR, Malone MK, Weinstein RB, Shiffman S. Exceeding the daily dosing limit of nonsteroidal anti-inflammatory drugs among ibuprofen users. Pharmacoepidemiol Drug Saf. 2018;27(3):322–31.CrossRef
5.
Zurück zum Zitat Bally M, Dendukuri N, Rich B, Nadeau L, Helin-Salmivaara A, Garbe E, et al. Risk of acute myocardial infarction with NSAIDs in real world use: bayesian meta-analysis of individual patient data. BMJ. 2017;357:j1909.CrossRef Bally M, Dendukuri N, Rich B, Nadeau L, Helin-Salmivaara A, Garbe E, et al. Risk of acute myocardial infarction with NSAIDs in real world use: bayesian meta-analysis of individual patient data. BMJ. 2017;357:j1909.CrossRef
6.
Zurück zum Zitat Vane JR, Botting RM. Mechanism of action of nonsteroidal anti-inflammatory drugs. Am J Med. 1998;104(3a):2S-8S (discussion 21S-2S).CrossRef Vane JR, Botting RM. Mechanism of action of nonsteroidal anti-inflammatory drugs. Am J Med. 1998;104(3a):2S-8S (discussion 21S-2S).CrossRef
7.
Zurück zum Zitat Hanna VS, Hafez EAA. Synopsis of arachidonic acid metabolism: a review. J Adv Res. 2018;11:23–32.CrossRef Hanna VS, Hafez EAA. Synopsis of arachidonic acid metabolism: a review. J Adv Res. 2018;11:23–32.CrossRef
8.
Zurück zum Zitat Vane SJ. Differential inhibition of cyclooxygenase isoforms: an explanation of the action of NSAIDs. J Clin Rheumatol. 1998;4(5 Suppl):s3-10.CrossRef Vane SJ. Differential inhibition of cyclooxygenase isoforms: an explanation of the action of NSAIDs. J Clin Rheumatol. 1998;4(5 Suppl):s3-10.CrossRef
9.
Zurück zum Zitat Ryan EP, Rahman I, Phipps RP. Cyclooxygenase-2 inhibition induces oxidative stress and decreases intracellular glutathione to reduce survival of human B lymphoma/leukemia cells. J Clin Oncol. 2007;25(18_suppl):18522.CrossRef Ryan EP, Rahman I, Phipps RP. Cyclooxygenase-2 inhibition induces oxidative stress and decreases intracellular glutathione to reduce survival of human B lymphoma/leukemia cells. J Clin Oncol. 2007;25(18_suppl):18522.CrossRef
10.
Zurück zum Zitat Chen Y-R, Zweier JL. Cardiac mitochondria and reactive oxygen species generation. Circ Res. 2014;114(3):524–37.CrossRef Chen Y-R, Zweier JL. Cardiac mitochondria and reactive oxygen species generation. Circ Res. 2014;114(3):524–37.CrossRef
11.
Zurück zum Zitat Panth N, Paudel KR, Parajuli K. Reactive oxygen species: a key hallmark of cardiovascular disease. Adv Med. 2016;2016:9152732.CrossRef Panth N, Paudel KR, Parajuli K. Reactive oxygen species: a key hallmark of cardiovascular disease. Adv Med. 2016;2016:9152732.CrossRef
12.
Zurück zum Zitat Dai DF, Johnson SC, Villarin JJ, Chin MT, Nieves-Cintrón M, Chen T, et al. Mitochondrial oxidative stress mediates angiotensin II-induced cardiac hypertrophy and Galphaq overexpression-induced heart failure. Circ Res. 2011;108(7):837–46.CrossRef Dai DF, Johnson SC, Villarin JJ, Chin MT, Nieves-Cintrón M, Chen T, et al. Mitochondrial oxidative stress mediates angiotensin II-induced cardiac hypertrophy and Galphaq overexpression-induced heart failure. Circ Res. 2011;108(7):837–46.CrossRef
13.
Zurück zum Zitat Brown DA, Perry JB, Allen ME, Sabbah HN, Stauffer BL, Shaikh SR, et al. Mitochondrial function as a therapeutic target in heart failure. Nat Rev Cardiol. 2017;14(4):238–50.CrossRef Brown DA, Perry JB, Allen ME, Sabbah HN, Stauffer BL, Shaikh SR, et al. Mitochondrial function as a therapeutic target in heart failure. Nat Rev Cardiol. 2017;14(4):238–50.CrossRef
14.
Zurück zum Zitat Dhalla NS, Temsah RM, Netticadan T. Role of oxidative stress in cardiovascular diseases. J Hypertens. 2000;18(6):655–73.CrossRef Dhalla NS, Temsah RM, Netticadan T. Role of oxidative stress in cardiovascular diseases. J Hypertens. 2000;18(6):655–73.CrossRef
15.
Zurück zum Zitat Varga Z, Sabzwari SRA, Vargova V. Cardiovascular risk of nonsteroidal anti-inflammatory drugs: an under-recognized public health issue. Cureus. 2017;9(4):e1144. Varga Z, Sabzwari SRA, Vargova V. Cardiovascular risk of nonsteroidal anti-inflammatory drugs: an under-recognized public health issue. Cureus. 2017;9(4):e1144.
16.
Zurück zum Zitat Brandolini L, Antonosante A, Giorgio C, Bagnasco M, d’Angelo M, Castelli V, et al. NSAIDs-dependent adaption of the mitochondria-proteasome system in immortalized human cardiomyocytes. Sci Rep. 2020;10(1):18337.CrossRef Brandolini L, Antonosante A, Giorgio C, Bagnasco M, d’Angelo M, Castelli V, et al. NSAIDs-dependent adaption of the mitochondria-proteasome system in immortalized human cardiomyocytes. Sci Rep. 2020;10(1):18337.CrossRef
17.
Zurück zum Zitat Thai PN, Daugherty DJ, Frederich BJ, Lu X, Deng W, Bers DM, et al. Cardiac-specific conditional knockout of the 18-kDa mitochondrial translocator protein protects from pressure overload induced heart failure. Sci Rep. 2018;8(1):16213.CrossRef Thai PN, Daugherty DJ, Frederich BJ, Lu X, Deng W, Bers DM, et al. Cardiac-specific conditional knockout of the 18-kDa mitochondrial translocator protein protects from pressure overload induced heart failure. Sci Rep. 2018;8(1):16213.CrossRef
18.
Zurück zum Zitat Sirish P, Ledford HA, Timofeyev V, Thai PN, Ren L, Kim HJ, et al. Action potential shortening and impairment of cardiac function by ablation of Slc26a6. Circ Arrhythm Electrophysiol. 2017;10(10):e005267.CrossRef Sirish P, Ledford HA, Timofeyev V, Thai PN, Ren L, Kim HJ, et al. Action potential shortening and impairment of cardiac function by ablation of Slc26a6. Circ Arrhythm Electrophysiol. 2017;10(10):e005267.CrossRef
19.
Zurück zum Zitat Sirish P, Li N, Liu JY, Lee KS, Hwang SH, Qiu H, et al. Unique mechanistic insights into the beneficial effects of soluble epoxide hydrolase inhibitors in the prevention of cardiac fibrosis. Proc Natl Acad Sci U S A. 2013;110(14):5618–23.CrossRef Sirish P, Li N, Liu JY, Lee KS, Hwang SH, Qiu H, et al. Unique mechanistic insights into the beneficial effects of soluble epoxide hydrolase inhibitors in the prevention of cardiac fibrosis. Proc Natl Acad Sci U S A. 2013;110(14):5618–23.CrossRef
20.
Zurück zum Zitat Sirish P, Li N, Timofeyev V, Zhang XD, Wang L, Yang J, et al. Molecular mechanisms and new treatment paradigm for atrial fibrillation. Circ Arrhythm Electrophysiol. 2016 ;9(5)CIRCEP.115.003721e003721. Sirish P, Li N, Timofeyev V, Zhang XD, Wang L, Yang J, et al. Molecular mechanisms and new treatment paradigm for atrial fibrillation. Circ Arrhythm Electrophysiol. 2016 ;9(5)CIRCEP.115.003721e003721.
21.
Zurück zum Zitat Ghosh R, Goswami SK, Feitoza L, Hammock B, Gomes AV. Diclofenac induces proteasome and mitochondrial dysfunction in murine cardiomyocytes and hearts. Int J Cardiol. 2016;223:923–35.CrossRef Ghosh R, Goswami SK, Feitoza L, Hammock B, Gomes AV. Diclofenac induces proteasome and mitochondrial dysfunction in murine cardiomyocytes and hearts. Int J Cardiol. 2016;223:923–35.CrossRef
22.
Zurück zum Zitat Goswami SK, Rand AA, Wan D, Yang J, Inceoglu B, Thomas M, et al. Pharmacological inhibition of soluble epoxide hydrolase or genetic deletion reduces diclofenac-induced gastric ulcers. Life Sci. 2017;180:114–22.CrossRef Goswami SK, Rand AA, Wan D, Yang J, Inceoglu B, Thomas M, et al. Pharmacological inhibition of soluble epoxide hydrolase or genetic deletion reduces diclofenac-induced gastric ulcers. Life Sci. 2017;180:114–22.CrossRef
23.
Zurück zum Zitat Roth DM, Swaney JS, Dalton ND, Gilpin EA, Ross J Jr. Impact of anesthesia on cardiac function during echocardiography in mice. Am J Physiol Heart Circ Physiol. 2002;282(6):H2134–40.CrossRef Roth DM, Swaney JS, Dalton ND, Gilpin EA, Ross J Jr. Impact of anesthesia on cardiac function during echocardiography in mice. Am J Physiol Heart Circ Physiol. 2002;282(6):H2134–40.CrossRef
24.
Zurück zum Zitat Johnson AG. NSAIDs and increased blood pressure. What is the clinical significance? Drug Saf. 1997;17(5):277–89.CrossRef Johnson AG. NSAIDs and increased blood pressure. What is the clinical significance? Drug Saf. 1997;17(5):277–89.CrossRef
25.
Zurück zum Zitat Granier M, Massin F, Pasquié JL. Pro- and anti-arrhythmic effects of anti-inflammatory drugs. Antiinflamm Antiallergy Agents Med Chem. 2013;12(1):83–93.CrossRef Granier M, Massin F, Pasquié JL. Pro- and anti-arrhythmic effects of anti-inflammatory drugs. Antiinflamm Antiallergy Agents Med Chem. 2013;12(1):83–93.CrossRef
26.
Zurück zum Zitat Luo M, Anderson ME. Mechanisms of altered Ca2+ handling in heart failure. Circ Res. 2013;113(6):690–708.CrossRef Luo M, Anderson ME. Mechanisms of altered Ca2+ handling in heart failure. Circ Res. 2013;113(6):690–708.CrossRef
27.
Zurück zum Zitat Schmidt M, Sørensen HT, Pedersen L. Diclofenac use and cardiovascular risks: series of nationwide cohort studies. BMJ. 2018;362:k3426.CrossRef Schmidt M, Sørensen HT, Pedersen L. Diclofenac use and cardiovascular risks: series of nationwide cohort studies. BMJ. 2018;362:k3426.CrossRef
28.
Zurück zum Zitat Eisner V, Csordás G, Hajnóczky G. Interactions between sarco-endoplasmic reticulum and mitochondria in cardiac and skeletal muscle – pivotal roles in Ca<sup>2+</sup> and reactive oxygen species signaling. J Cell Sci. 2013;126(14):2965. Eisner V, Csordás G, Hajnóczky G. Interactions between sarco-endoplasmic reticulum and mitochondria in cardiac and skeletal muscle – pivotal roles in Ca<sup>2+</sup> and reactive oxygen species signaling. J Cell Sci. 2013;126(14):2965.
29.
Zurück zum Zitat Corbi G, Conti V, Russomanno G, Longobardi G, Furgi G, Filippelli A, et al. Adrenergic signaling and oxidative stress: a role for sirtuins? Front Physiol. 2013;4:324.CrossRef Corbi G, Conti V, Russomanno G, Longobardi G, Furgi G, Filippelli A, et al. Adrenergic signaling and oxidative stress: a role for sirtuins? Front Physiol. 2013;4:324.CrossRef
30.
Zurück zum Zitat Görlach A, Bertram K, Hudecova S, Krizanova O. Calcium and ROS: A mutual interplay. Redox Biol. 2015;6:260–71.CrossRef Görlach A, Bertram K, Hudecova S, Krizanova O. Calcium and ROS: A mutual interplay. Redox Biol. 2015;6:260–71.CrossRef
31.
Zurück zum Zitat Tonolini M. Acute nonsteroidal anti-inflammatory drug-induced colitis. J Emerg Trauma Shock. 2013;6(4):301–3.CrossRef Tonolini M. Acute nonsteroidal anti-inflammatory drug-induced colitis. J Emerg Trauma Shock. 2013;6(4):301–3.CrossRef
32.
Zurück zum Zitat Krause MM, Brand MD, Krauss S, Meisel C, Vergin H, Burmester GR, et al. Nonsteroidal antiinflammatory drugs and a selective cyclooxygenase 2 inhibitor uncouple mitochondria in intact cells. Arthritis Rheum. 2003;48(5):1438–44.CrossRef Krause MM, Brand MD, Krauss S, Meisel C, Vergin H, Burmester GR, et al. Nonsteroidal antiinflammatory drugs and a selective cyclooxygenase 2 inhibitor uncouple mitochondria in intact cells. Arthritis Rheum. 2003;48(5):1438–44.CrossRef
33.
Zurück zum Zitat Fearnley CJ, Roderick HL, Bootman MD. Calcium signaling in cardiac myocytes. Cold Spring Harb Perspect Biol. 2011;3(11):a004242. CrossRef Fearnley CJ, Roderick HL, Bootman MD. Calcium signaling in cardiac myocytes. Cold Spring Harb Perspect Biol. 2011;3(11):a004242. CrossRef
34.
Zurück zum Zitat Yano M, Ikeda Y, Matsuzaki M. Altered intracellular Ca2+ handling in heart failure. J Clin Investig. 2005;115(3):556–64.CrossRef Yano M, Ikeda Y, Matsuzaki M. Altered intracellular Ca2+ handling in heart failure. J Clin Investig. 2005;115(3):556–64.CrossRef
35.
Zurück zum Zitat Tarasov AI, Griffiths EJ, Rutter GA. Regulation of ATP production by mitochondrial Ca(2+). Cell Calcium. 2012;52(1):28–35.CrossRef Tarasov AI, Griffiths EJ, Rutter GA. Regulation of ATP production by mitochondrial Ca(2+). Cell Calcium. 2012;52(1):28–35.CrossRef
36.
Zurück zum Zitat de Brito OM, Scorrano L. Mitofusin 2 tethers endoplasmic reticulum to mitochondria. Nature. 2008;456(7222):605–10.CrossRef de Brito OM, Scorrano L. Mitofusin 2 tethers endoplasmic reticulum to mitochondria. Nature. 2008;456(7222):605–10.CrossRef
37.
Zurück zum Zitat Yarishkin OV, Hwang EM, Kim D, Yoo JC, Kang SS, Kim DR, et al. Diclofenac, a non-steroidal anti-inflammatory drug, inhibits L-type Ca channels in neonatal rat ventricular cardiomyocytes. Korean J Physiol Pharmacol. 2009;13(6):437–42.CrossRef Yarishkin OV, Hwang EM, Kim D, Yoo JC, Kang SS, Kim DR, et al. Diclofenac, a non-steroidal anti-inflammatory drug, inhibits L-type Ca channels in neonatal rat ventricular cardiomyocytes. Korean J Physiol Pharmacol. 2009;13(6):437–42.CrossRef
38.
Zurück zum Zitat Denton RM. Regulation of mitochondrial dehydrogenases by calcium ions. Biochim Biophys Acta. 2009;1787(11):1309–16.CrossRef Denton RM. Regulation of mitochondrial dehydrogenases by calcium ions. Biochim Biophys Acta. 2009;1787(11):1309–16.CrossRef
39.
Zurück zum Zitat Pan Z, Zhao W, Zhang X, Wang B, Wang J, Sun X, et al. Scutellarin alleviates interstitial fibrosis and cardiac dysfunction of infarct rats by inhibiting TGFbeta1 expression and activation of p38-MAPK and ERK1/2. Br J Pharmacol. 2011;162(3):688–700.CrossRef Pan Z, Zhao W, Zhang X, Wang B, Wang J, Sun X, et al. Scutellarin alleviates interstitial fibrosis and cardiac dysfunction of infarct rats by inhibiting TGFbeta1 expression and activation of p38-MAPK and ERK1/2. Br J Pharmacol. 2011;162(3):688–700.CrossRef
40.
Zurück zum Zitat Sanin DE, Matsushita M, Klein Geltink RI, Grzes KM, van Teijlingen BN, Corrado M, et al. Mitochondrial membrane potential regulates nuclear gene expression in macrophages exposed to prostaglandin E2. Immunity. 2018;49(6):1021-33.e6.CrossRef Sanin DE, Matsushita M, Klein Geltink RI, Grzes KM, van Teijlingen BN, Corrado M, et al. Mitochondrial membrane potential regulates nuclear gene expression in macrophages exposed to prostaglandin E2. Immunity. 2018;49(6):1021-33.e6.CrossRef
41.
Zurück zum Zitat Haritha C, Gopala RA, Anjaneyulu Y, Kalakumar B, Dilip RG. Oxidative stress induced by diclofenac alone and under the influence of certain variables in broilers. Toxicol Int. 2010;17(1):27–9.CrossRef Haritha C, Gopala RA, Anjaneyulu Y, Kalakumar B, Dilip RG. Oxidative stress induced by diclofenac alone and under the influence of certain variables in broilers. Toxicol Int. 2010;17(1):27–9.CrossRef
42.
Zurück zum Zitat Syed M, Skonberg C, Hansen SH. Mitochondrial toxicity of diclofenac and its metabolites via inhibition of oxidative phosphorylation (ATP synthesis) in rat liver mitochondria: possible role in drug induced liver injury (DILI). Toxicol In Vitro. 2016;31:93–102.CrossRef Syed M, Skonberg C, Hansen SH. Mitochondrial toxicity of diclofenac and its metabolites via inhibition of oxidative phosphorylation (ATP synthesis) in rat liver mitochondria: possible role in drug induced liver injury (DILI). Toxicol In Vitro. 2016;31:93–102.CrossRef
43.
Zurück zum Zitat Li N, Liu JY, Qiu H, Harris TR, Sirish P, Hammock BD, et al. Use of metabolomic profiling in the study of arachidonic acid metabolism in cardiovascular disease. Congest Heart Fail. 2011;17(1):42–6.CrossRef Li N, Liu JY, Qiu H, Harris TR, Sirish P, Hammock BD, et al. Use of metabolomic profiling in the study of arachidonic acid metabolism in cardiovascular disease. Congest Heart Fail. 2011;17(1):42–6.CrossRef
44.
Zurück zum Zitat Ahmed SA, Al-Lawati H, Jamali F. Dose-dependency of the cardiovascular risks of non-steroidal anti-inflammatory drugs. Inflammopharmacology. 2019;27(5):903–10.CrossRef Ahmed SA, Al-Lawati H, Jamali F. Dose-dependency of the cardiovascular risks of non-steroidal anti-inflammatory drugs. Inflammopharmacology. 2019;27(5):903–10.CrossRef
45.
Zurück zum Zitat Sirish P, Thai PN, Lee JH, Yang J, Zhang XD, Ren L, et al. Suppression of inflammation and fibrosis using soluble epoxide hydrolase inhibitors enhances cardiac stem cell-based therapy. Stem Cells Transl Med. 2020;9(12):1570–1584. Sirish P, Thai PN, Lee JH, Yang J, Zhang XD, Ren L, et al. Suppression of inflammation and fibrosis using soluble epoxide hydrolase inhibitors enhances cardiac stem cell-based therapy. Stem Cells Transl Med. 2020;9(12):1570–1584.
46.
Zurück zum Zitat Li Q, Mao M, Qiu Y, Liu G, Sheng T, Yu X, et al. Key role of ROS in the process of 15-lipoxygenase/15-hydroxyeicosatetraenoiccid-induced pulmonary vascular remodeling in hypoxia pulmonary hypertension. PloS One. 2016;11(2):e0149164.CrossRef Li Q, Mao M, Qiu Y, Liu G, Sheng T, Yu X, et al. Key role of ROS in the process of 15-lipoxygenase/15-hydroxyeicosatetraenoiccid-induced pulmonary vascular remodeling in hypoxia pulmonary hypertension. PloS One. 2016;11(2):e0149164.CrossRef
47.
Zurück zum Zitat Kiritoshi S, Nishikawa T, Sonoda K, Kukidome D, Senokuchi T, Matsuo T, et al. Reactive oxygen species from mitochondria induce cyclooxygenase-2 gene expression in human mesangial cells: potential role in diabetic nephropathy. Diabetes. 2003;52(10):2570–7.CrossRef Kiritoshi S, Nishikawa T, Sonoda K, Kukidome D, Senokuchi T, Matsuo T, et al. Reactive oxygen species from mitochondria induce cyclooxygenase-2 gene expression in human mesangial cells: potential role in diabetic nephropathy. Diabetes. 2003;52(10):2570–7.CrossRef
48.
Zurück zum Zitat Zhuang Y, Wang C, Wu C, Ding D, Zhao F, Hu C, et al. Mitochondrial oxidative stress activates COX-2/mPGES-1/PGE2 cascade induced by albumin in renal proximal tubular cells. Oncotarget. 2018;9(10):9235–45.CrossRef Zhuang Y, Wang C, Wu C, Ding D, Zhao F, Hu C, et al. Mitochondrial oxidative stress activates COX-2/mPGES-1/PGE2 cascade induced by albumin in renal proximal tubular cells. Oncotarget. 2018;9(10):9235–45.CrossRef
49.
Zurück zum Zitat Peoples JN, Saraf A, Ghazal N, Pham TT, Kwong JQ. Mitochondrial dysfunction and oxidative stress in heart disease. Exp Mol Med. 2019;51(12):1–13.CrossRef Peoples JN, Saraf A, Ghazal N, Pham TT, Kwong JQ. Mitochondrial dysfunction and oxidative stress in heart disease. Exp Mol Med. 2019;51(12):1–13.CrossRef
50.
Zurück zum Zitat Chen G, Chelu MG, Dobrev D, Li N. Cardiomyocyte inflammasome signaling in cardiomyopathies and atrial fibrillation: mechanisms and potential therapeutic implications. Front Physiol. 2018;9:1115.CrossRef Chen G, Chelu MG, Dobrev D, Li N. Cardiomyocyte inflammasome signaling in cardiomyopathies and atrial fibrillation: mechanisms and potential therapeutic implications. Front Physiol. 2018;9:1115.CrossRef
Metadaten
Titel
Chronic Diclofenac Exposure Increases Mitochondrial Oxidative Stress, Inflammatory Mediators, and Cardiac Dysfunction
verfasst von
Phung N. Thai
Lu Ren
Wilson Xu
James Overton
Valeriy Timofeyev
Carol E. Nader
Michael Haddad
Jun Yang
Aldrin V Gomes
Bruce D. Hammock
Nipavan Chiamvimonvat
Padmini Sirish
Publikationsdatum
09.09.2021
Verlag
Springer US
Erschienen in
Cardiovascular Drugs and Therapy / Ausgabe 1/2023
Print ISSN: 0920-3206
Elektronische ISSN: 1573-7241
DOI
https://doi.org/10.1007/s10557-021-07253-4

Weitere Artikel der Ausgabe 1/2023

Cardiovascular Drugs and Therapy 1/2023 Zur Ausgabe

Kompaktes Leitlinien-Wissen Innere Medizin

Mit medbee Pocketcards schnell und sicher entscheiden.
Leitlinien-Wissen kostenlos und immer griffbereit auf ihrem Desktop, Handy oder Tablet.

Neu im Fachgebiet Kardiologie

Schwere Aortenstenose: „Klappenersatz sollte unabhängig von Symptomen erfolgen“

12.09.2024 Aortenklappenstenose Nachrichten

Soll Menschen mit schwerer Aortenstenose und normaler linksventrikulärer Ejektionsfraktion auch dann zum Klappenersatz geraten werden, wenn sie nachweislich symptomfrei sind? Die AVATAR-Studie und die jetzt publizierten Langzeitdaten sprechen klar dafür.

Hitze lässt kardiale und pulmonale Mortalität steigen

12.09.2024 Hitzebelastung Nachrichten

Mit steigenden Temperaturen nehmen Todesfälle durch Herz- und Lungenerkrankungen zu, das belegt eine Querschnittstudie aus Deutschland. Die Daten legen offen, welche Personengruppen besonders gefährdet sind.

Neue ESC-Praxisleitlinien Vorhofflimmern: Das hat sich geändert

11.09.2024 ESC 2024 Kongressbericht

Vier Jahre nach dem letzten Update sind die europäischen Praxisleitlinien zum Management bei Vorhofflimmern wieder aktualisiert worden. Eine Neuerung ist unter anderen ein stärkerer Fokus auf die Behandlung von Begleiterkrankungen.

Von kompletter Revaskularisation profitieren auch ältere Menschen mit STEMI

09.09.2024 ESC 2024 Kongressbericht

Auch ältere Menschen mit ST-Hebungsmyokardinfarkt profitieren davon, wenn bei der Koronarintervention alle verengten Koronararterien und nicht allein die Infarktarterie revaskularisiert werden, zeigt eine neue Metaanalyse.

EKG Essentials: EKG befunden mit System

In diesem CME-Kurs können Sie Ihr Wissen zur EKG-Befundung anhand von zwölf Video-Tutorials auffrischen und 10 CME-Punkte sammeln.
Praxisnah, relevant und mit vielen Tipps & Tricks vom Profi.

Update Kardiologie

Bestellen Sie unseren Fach-Newsletter und bleiben Sie gut informiert.