1. Introduction

Reactive oxygen species (ROS) are molecules that contain one or more unpaired electrons, which contribute to their high reactivity. ROS can be classified as free radicals and nonradical molecules [1]. Examples of free radicals include superoxide (O₂^•−), hydroxyl (HO^•), and peroxyl (RO₂^•−) radicals, and nonradical molecules include hydrogen peroxide (H₂O₂) and organic peroxides (ROOH). Physiologically, ROS are produced as byproducts of metabolic reactions, namely electron leakage during oxidative phosphorylation in the mitochondria, through the activity of NADPH oxidases, and via the iron-dependent Fenton reaction [2,3]. In normal cells, intracellular ROS levels are regulated by antioxidants and maintained at levels that regulate various signaling pathways, including cell proliferation, metabolism, and differentiation, among others. At levels beyond the physiological threshold, ROS cause oxidative damage to various cellular components, namely nucleic acids, proteins, and lipids, which in turn can induce cell death [4].

In cancer cells, the redox balance is disrupted due to several factors, including activation of oncogenes, aerobic glycolysis, and hypoxia. This can result in the accumulation of ROS, which can be lethal to cancer cells [3,5]. Therefore, to combat this issue and prevent oxidative stress-induced cell death, cancer cells employ several mechanisms, such as enhanced expression and activity of components of the antioxidant defense system, for example, peroxide scavenging systems that reduce H₂O₂ to H₂O. Additionally, the availability of O₂, mitochondrial localization in the cell, and the rates and concentrations of electrons and their carriers in the electron transport chain further regulate the production of ROS, specifically mitochondrial ROS [6]. Collectively, this maintains ROS at levels that facilitate activation of protumorigenic signaling pathways, thereby driving tumor progression, without inducing oxidative stress-induced cell death. For example, ROS can affect mRNA regulation and increase the expression of G1/S cyclins, thereby promoting cell cycle progression in breast cancer through the ERK1/2 MAPK pathway [7]. Similarly, ROS were found to be integral for anchorage-independent growth induced by the protooncogene KRAS [8]. In addition, mitochondrial ROS are known to act as a stabilizer of hypoxia-inducible transcription factor-1α, which regulates the expression of vascular endothelial growth factor, which in turn activates pathways that lead to the proliferation of endothelial cells, ultimately promoting angiogenesis [9]. Similarly, other signaling pathways can also be activated by ROS in cancer cells to drive their progression, given their role as intracellular messengers.

However, despite the survival advantage, the altered redox homeostasis increases the susceptibility of cancer cells to further changes in ROS levels, and therefore increases their susceptibility to oxidative stress-induced cell death. Hence, pro-oxidative drugs which skew this altered redox balance to further increase ROS levels have been proposed and investigated as a therapeutic strategy for cancers [2,3,5,10] (Figure 1). Induction of ROS by pro-oxidative drugs can be modulated through different mechanisms. It can be attributed to: (1) direct ROS induction as a consequence of drug metabolism (e.g., doxorubicin, which is metabolized to its unstable semiquinone radical); (2) upregulation of pro-oxidative enzymes, such as NADPH oxidase, which produce superoxide; or (3) targeted inhibition of cellular antioxidant mechanisms, such as superoxide dismutase (SOD) 1, which catalyzes the conversion of oxide ion (O₂⁻) produced by the electron transport chain or as byproducts of other enzymatic reactions into H₂O₂ [11].

Indeed, many chemotherapeutic drugs exhibit their anticancer effects through direct or indirect induction of oxidative stress. This review aims to highlight anticancer drugs that attribute their anticancer activity primarily to ROS induction, such that the use of ROS inhibitors/scavengers abrogates their anticancer effects. In addition to the above-mentioned rationale, we further narrowed down the drugs highlighted in this review to meet the following criteria: (1) they exhibit their anticancer activity in two or more cancer types; (2) the pathways that modulate their anticancer effects are induced downstream of ROS. Moreover, given the growing interest in phytochemical compounds as anticancer therapeutics, we specifically focused on pro-oxidative phytochemicals and further classified them based on whether the mechanism of ROS induction has been elucidated.

2. Pro-Oxidative Drugs in Preclinical Study

This section discusses pro-oxidative anticancer drugs, with special emphasis on phytochemicals, which are currently being investigated in preclinical studies.

2.1. Phytochemicals with a Characterized Mechanism of of ROS Induction

An overwhelming proportion of anticancer drugs that have been approved in the past decades are derivatives of natural products. For example, paclitaxel, a taxane diterpene that is widely used for the treatment of various cancers, including breast, endometrial, and ovarian cancers, was originally derived from the Pacific yew (Taxus brevifolia) [12].

This section highlights selected pro-oxidative phytochemical compounds that attribute their anticancer activity to ROS-mediated mechanisms, and whose mechanism of ROS induction has been characterized.

2.1.1. Piperlongumine

Piperlongumine (PPL) is an alkaloid/amide that was identified in root extracts of long pepper (Piper longum) and has been investigated for its anticancer activity in various cancer types, including hematological cancers, colorectal, gastric, lung, breast, prostate, and oral cancers, melanoma, and glioma [13,14]. Its in vitro anticancer activity can be attributed to induction of ROS through increased glutathione disulfide levels, decreased glutathione levels, and inhibition of thioredoxin reductase (TrxR), an enzyme which reduces thioredoxin, a redox protein that protects against oxidative stress [13,14]. PPL-mediated ROS accumulation further leads to ROS-mediated apoptosis [15], G1 or G2/M cell cycle arrest [16,17], ER stress [15], and oxidative DNA damage [17]. PPL was also found to modulate various signaling pathways involved in tumor progression, including the JAK/STAT3, ERK, NF-κB, and PI3K/AKT/mTOR pathways [13,14]. Consistent with the regulation of these important pathways, which are also involved in chemoresistance, PPL was reported to sensitize head and neck, gastric, and liver cancers to cisplatin [18], oxaliplatin [19], and sorafenib [20], respectively, through induction of ROS both in vitro and in vivo. However, despite the promising potential of PPL as both an anticancer therapeutic and a chemosensitizing agent, its pharmacokinetics have not been clarified. Additionally, its poor aqueous solubility and bioavailability limit its therapeutic potential [13,14]; however, efforts have been made on this front in relation to drug delivery systems, especially with nanoparticles and nanoemulsions, which have shown promising results [14,21,22].

2.1.2. Resveratrol

Resveratrol (3,5,4′-trihydroxy-trans-stilbene) is a stilbenoid that is found in various plant species, including common grape vine (Vitis vinifera) and berries of the genus Vaccinium, and has been investigated for its biological activities including anticancer, anti-inflammatory, and antimicrobial properties, among others. The anticancer activity of resveratrol is well characterized both in vitro and in vivo in various cancer types [23]. Several molecular mechanisms have been proposed for the anticancer activity of resveratrol, including ROS induction. However, with respect to ROS, the effect of resveratrol appears to be concentration dependent; at low concentrations, it exerts antioxidant effects, whereas at high concentrations (50–100 µM), resveratrol induces ROS production [24,25], which can be attributed to increased NADPH oxidase activity [25]. Resveratrol-induced ROS accumulation modulates autophagy and apoptosis in colon [25,26], pancreatic [27], and bladder cancer [28] cells. Cheng et al. [27] reported that resveratrol-induced ROS activate the Nrf2 signaling pathway, which subsequently suppresses NAF1 and induces apoptosis in pancreatic cancer cells. This also increased their sensitivity to gemcitabine. Additionally, resveratrol induces ROS-mediated DNA damage [24,29], which has been reported to mediate senescence through the DLC1–DYRK1A–EGFR axis in breast and liver cancer in vitro and in vivo [29]. Despite the promising potential of resveratrol, its unstable pharmacokinetics due to its high metabolism and poor bioavailability limit its clinical application. Consistently, resveratrol analogues, such as 3,4,4′-trihydroxy-trans-stilbene (a synthetic analogue) [30] and piceatannol (a natural analogue) [31], have been investigated to overcome the same and are more potent, bypassing the high dosage issue, and were also found to exert their anticancer activity through ROS induction. Moreover, various nanocarriers have been investigated to optimize drug delivery and improve bioavailability; although many have been studied in vitro, in vivo studies are lacking for the same and are hence warranted [32].

2.1.3. Oleanolic Acid

Oleanolic acid (OA, 3β-hydroxyolean-12-en-28-oic acid), a pentacyclic triterpenoid, is found in various plant extracts and is one of the bioactive components of ginseng (Panax spp.) and olive (Olea europaea). OA and its derivatives have been studied extensively for their various biological activities, including anticancer activity, which has been characterized in vitro and in vivo in various cancers including hepatocellular, breast, colon, prostate, melanoma, and hematological cancers [33]. ROS induction and accumulation by OA has been reported in lung, pancreatic, osteosarcoma, and prostate cancer cells [34,35]. Consistently, its derivatives SZC017 [36], per-O-methylated-β-cyclodextrin-conjugated oleanolic acid [37], methyl-2-cyano-3,12-dioxooleana-1,9(11)-dien-28-oate [38], diclofenac-oleanolic acid oxime derivative conjugates [39], and olean-28,13b-olide 2, and a gold(I) complex containing an oleanolic acid derivative (4 b) [40], also increase ROS levels; the latter three induce ROS by downregulating the expression of glutamine transporter SLC1A5, antioxidant enzymes SOD1 and NAD(P)H dehydrogenase [quinone] 1, and TrxR, respectively. OA-mediated ROS accumulation induces cell cycle arrest (G0/G1 and G2/M) [34,36,41], autophagy [36], ER stress [40], mitochondrial membrane depolarization [37,42], and mitochondria-dependent apoptosis [37,42] through modulation of various signaling pathways. The following signaling pathways were reported to be modulated by OA and/or its derivatives in an ROS-dependent manner: activation of p38/MAPK pathway in lung, pancreatic, and osteosarcoma cells [35]; inhibition of PI3K/AKT pathway in gastric, prostate, and lung adenocarcinoma cancer cells [34,36,43]; and inhibition of NFkB pathway in lung adenocarcinoma and hepatoma cells [41,43]. Moreover, OA and its derivatives also function as chemosensitizers and have been reported to increase the sensitivity of hepatocellular cancer cells to sorafenib [42,44] and lung adenocarcinoma cells to cisplatin [43]. Collectively, these studies highlight the promising potential of OA and its derivatives as anticancer agents. However, like other phytochemical compounds, its clinical use is limited by poor bioavailability, and although several derivatives have improved its bioavailability, further research is still needed on this front.

2.1.4. Plumbagin

Plumbagin (5-hydroxy-2-methyl-1,4-napthoquinone) is a naphthoquinone found in the roots of Leadwort (Plumbago zeylanica L.), and its anticancer activity has been well characterized against various cancers, including breast cancer, melanoma, glioma, hepatocellular cancer, oral squamous cell cancer, and T-cell lymphoma, among others [45]. Various studies have shown that plumbagin is a potent inducer of ROS. The mechanism underlying ROS induction by plumbagin has predominantly been attributed to inhibition of the antioxidant enzymes TrxR [46,47] and glutathione reductase [46]. In addition to TrxR inhibition, Hwang et al. clarified that plumbagin is a substrate of TrxR; it is reduced by TrxR, which inhibits the interaction of active TrxR with its substrate oxidized thioredoxin [46]. Downstream of ROS induction, plumbagin induces mitochondria-dependent apoptosis in hepatocellular cancer [46], lung cancer [46,48], and cervical cancer [46,49,50], leukemia [47], pancreatic cancer [51], oral squamous cell cancer [52,53], and osteosarcoma [54] among others. It also mediates its anticancer effect by inducing ER stress-mediated apoptosis [52,54,55], S/G2 and G2/M cell cycle arrest [48,49,56] and mitochondrial membrane depolarization in an ROS-dependent manner [45]. With respect to signaling pathways, plumbagin was found to inhibit the NF-κB [57], PI3K/AKT/mTOR [58] and MKP1/2 [59] pathways in non-small cell lung cancer, bladder cancer, and lymphoma, respectively. Additionally, plumbagin has been studied as an adjuvant drug to improve the efficacy of existing chemotherapeutic strategies. Namely, plumbagin was reported to improve the efficacy of chemical-based androgen deprivation therapy for prostate cancer in vivo [60] and a synthetic version of plumbagin, PCUR-101, is presently being explored for the same in a Phase I clinical trial (NCT04677855) with patients with metastatic castration-resistant prostate cancer. It was also reported to improve the efficacy of cisplatin in oral squamous cell carcinoma [53]. Collectively, these findings highlight the potential of plumbagin as a pro-oxidative anticancer agent that warrants further research.

2.1.5. Capsaicin

Capsaicin (trans-8-methyl-N-vanillyl-6-nonenamide) is an alkaloid that is found naturally in plants of the genus Capsicum (chili peppers) and contributes to the burning sensation attributed to spice. Various biological properties have been attributed to capsaicin, including anti-inflammatory and analgesic activities. Intriguingly, although a link between chili pepper consumption and oral and gastrointestinal cancers has long been suggested, capsaicin has been reported as both a chemopreventive and as an anticancer agent [61,62]. Capsaicin has been reported to induce ROS-dependent cell death in various cancers, including colorectal [63], prostate [64,65], bladder [66,67,68], and pancreatic [69,70] cancers. It has also been reported to inhibit tumor growth in vivo in mouse xenograft models of prostate [64] and bladder [66] cancers. Mechanistically, capsaicin-mediated ROS accumulation leads to mitochondrial membrane depolarization [63,64,66], which further triggers mitochondria-dependent apoptosis, as well as G0/G1 cell cycle arrest [68]. Additionally, Sánchez et al. reported that in bladder cancer cells, capsaicin induces JNK activation in an ROS-dependent manner, which results in ceramide accumulation and contributes to apoptosis [65]. Several mechanisms underlying capsaicin-mediated ROS accumulation have been reported, including: (1) inhibition of the activity of antioxidant enzymes SOD, catalase (CAT), and glutathione peroxidase [70]; (2) inhibition of the activity of mitochondrial complex-I and complex-III in the electron transport chain [70]; (3) downregulation of the expression of sirtuin-1, a NAD-dependent deacetylase that regulates the expression of various antioxidant enzymes [69]; (4) upregulation of the expression of NADPH oxidase 4, which generates superoxide [69]; (5) increased expression of FOXO3a, which is a transcription factor that regulates the oxidative stress response [68].

2.1.6. Celastrol

Celastrol (24,25,26-trinoroleana-1(10),3,5,7-tetraen-29-oic acid) is a pentacyclic triterpenoid that was isolated from Tripterygium wilfordii (thunder duke vine), a plant that is commonly used in traditional Chinese medicine [71]. It has been widely studied as chemopreventive and anticancer drug, and its anticancer activity has been characterized in preclinical models against non-small cell lung [72], breast [73,74], colon [75,76], ovarian [77], gastric [78], and bladder [79] cancers. ROS induction has been attributed as the primary mode through which celastrol mediates its anticancer effects. Downstream of ROS, celastrol has been reported to inhibit HSP90 function [80], induce suppressor of specificity protein (Sp) repressors [79], activate the PKCzeta–AMPK-p53–PLK 2 signaling axis [73], and activate the JNK pathway [80,81] to induce apoptosis. With respect to other ROS-mediated anticancer effects, celastrol induces ER stress [78], mitochondrial dysfunction, specifically disruption of mitochondrial membrane potential [72,78,82], and cell cycle arrest at G2/M phase [76,77] and S phase [75]. Interestingly, at low concentrations (i.e., below the cytotoxic threshold) celastrol was found to induce autophagy in gastric cancer cells through ROS-mediated accumulation of hypoxia-inducible factor 1-α via the transient activation of AKT. However, at cytotoxic concentrations, autophagic flux was inhibited and celastrol mediated p53-independent apoptosis through the JNK pathway [81]. As a pro-oxidative phytochemical, two mechanisms have been reported for ROS induction by celastrol: (1) inhibition of mitochondrial respiratory chain complex I activity [80]; and (2) inhibition of peroxiredoxins, namely peroxiredoxin-1 [76] and peroxiredoxin-2 [78]. The latter is thought to be the main mechanism of action, given that peroxiredoxins are upregulated in many cancer types and are involved in tumorigenesis and chemoresistance [83,84,85]. Consequently, celastrol derivatives are currently in development to improve their potency and specificity against peroxiredoxins [76]. Celastrol has been consistently reported to enhance the sensitivity of triple-negative breast cancer cells to tamoxifen [74] and non-small cell lung cancer cells to erastin [72] and induce ROS-mediated apoptosis in doxorubicin-resistant colorectal cancer cells [75]. These findings highlight the potential of celastrol as an anticancer drug, and its safety is consistently being investigated in an open-label safety study (NCT05494112). However, the clinical translation of celastrol is hindered by poor aqueous solubility, poor bioavailability, as well as potential side effects [71]. Hence, more studies are needed on this front to overcome these limitations to advance the clinical translation of this promising pro-oxidative phytochemical.

2.2. Pro-Oxidative Phytochemicals with Uncharacterized Mechanism of ROS Induction

In addition to the above-mentioned phytochemicals, various other phytochemicals have also been investigated for their pro-oxidative capacity with respect to their anticancer activity. However, the mechanism of ROS induction is not well characterized for many of these phytochemicals.

For example, carnosol, a polyphenol, is one such pro-oxidative phytochemical whose mechanism of ROS induction has not been characterized. It was previously identified as an active constituent of sage (Salvia carnosa) and rosemary (Rosmarinus officinalis) extracts, and its anticancer activity was first characterized in the 1900s [86]. Carnosol was reported to induce ROS-dependent autophagy and/or apoptosis in colon cancer [87], triple-negative breast cancer [88], and osteosarcoma [89] cells. Our lab further clarified the underlying mechanisms of its activity: carnosol was found to target STAT3 [90] and p300 [91] to proteasomal degradation in an ROS-dependent manner and to function as a specific inhibitor of p300 in breast cancer [91]. Additionally, we found that carnosol induced p38-mediated endoplasmic reticulum (ER) stress in an ROS-dependent manner [92], which contributed to carnosol-induced autophagy and apoptosis in triple-negative breast cancer cells. Carnosol was also reported to modulate oxidative stress through depletion of the antioxidant glutathione, which induced apoptosis in adult T-cell leukemia/lymphoma cells [93]. However, the pro-oxidative activity of carnosol appears to be cancer specific, as carnosol has been reported to reduce ROS levels in non-melanoma skin cancer cells [94]. Additionally, very few studies have assessed the anticancer activity of carnosol in vivo, and this is limited to one or two studies each for breast, prostate, and skin cancers [95]. Future research with this promising phytochemical compound should focus on other cancer types and as well as in vivo studies to assess its safety/toxicity and pharmacokinetics.

Similarly, allicin, a sulfenic acid thioester, which is a major bioactive component of garlic (Allium sativum), has been reported to induce cell cycle arrest and apoptosis in an ROS-dependent manner in various cancer cells [96], but the mechanism underlying the observed ROS induction has not been elucidated, to the best of our knowledge. A select few of such pro-oxidative phytochemicals, including allicin, with anticancer activity whose mechanism of ROS induction is not well characterized are listed in Table 1 alongside the anticancer effects induced downstream of ROS induction.

2.3. Small Molecules

2.3.1. LCS-1

Lung cancer screen 1 (LCS-1; 4,5-dichloro-2-m-tolylpyridazin-3(2H)-one) was first identified in 2009 from a small molecule screen for lung adenocarcinoma cell lines. It inhibited the growth of EGFR or KRAS mutant lung adenocarcinoma cell lines by impairing the activation of MAPK and AKT signaling pathways, which regulate cell growth [102]. The same group later identified SOD1 as a protein target for LCS-1 [103]. Consistent with this finding, LCS-1 has been reported to induce its anticancer effect through induction of mitochondrial superoxide and ROS in other cancers, including breast cancer [104], colorectal cancer [105,106], multiple myeloma [107], and glioma [108], which could be attributed to inhibition of SOD1. Downstream of ROS generation, oxidative DNA damage-induced apoptosis [105], ER stress [107], loss of mitochondrial integrity [104], and loss of proteosome function [107] have been reported as anticancer effects of LCS-1. Recently, Ling et al. reported that the anticancer activity of LCS-1 was independent of p53 function and that LCS-1 induced degradation of PARP and BRCA1 [108], suggesting that it inhibited DNA repair pathways. In contrast with numerous in vitro studies, only two studies [107,108] have assessed the in vivo activity of LCS-1 owing to its poor aqueous solubility and, hence, bioavailability. However, LCS-1-loaded triple-polymer-coated magnetite nanocarrier exhibit enhanced efficacy, which could overcome this limitation [109]. Additionally, LCS-1 seems to be a potential therapeutic candidate for bortezomib-resistant multiple myeloma [107] and tamoxifen-resistant breast cancer [110]. Further preclinical research is needed on this SOD1 inhibitor to investigate its anticancer activity in other cancer types, improve its efficacy and pharmacokinetics, and understand the molecular mechanisms underlying its effects.

2.3.2. 15-Deoxy-Δ12,14-prostaglandin J2

15-deoxy-Δ12,14-prostaglandin J2 (15d-PGJ2) is a cyclopentenone prostaglandin, which is a class of biologically active arachidonic-acid derived lipids. 15d-PGJ2 is a well characterized endogenous inhibitor of peroxisome proliferator-activated receptor gamma (PPAR-γ), which regulates inflammation, cell differentiation and glucose mechanism. With respect to its anticancer activity, both PPAR-γ-dependent and -independent mechanisms have been proposed, and ROS induction is one PPAR-γ-independent mechanism of its anticancer activity [111,112]. ROS accumulation-mediated induction of apoptosis by 15d-PGJ2 was first reported in papillary thyroid cancer cells in 2002 [111], and has since been reported in other cancers including glioma [113], prostate cancer [114], colorectal cancer [114,115,116], leukemia [115], non-small cell lung cancer [117], osteosarcoma [118], and breast cancer [119,120]. The following mechanisms have been implicated in the same: activation of JNK in osteosarcoma [118], inactivation of AKT in osteosarcoma and colorectal cancer [115,118], inactivation of the PKA–PLK1 pathway in colorectal cancer [118], and inactivation of the IKKβ–ΝF-κB pathway in prostate cancer [121], and upregulation of DR5 through ROS-mediated induction of CHOP in colorectal cancer [114]. Additionally, 15d-PGJ2 can induce the expression of 15-hydroxyprostaglandin dehydrogenase, which is involved in the inactivation of oncogenic prostaglandin 2, through ROS-mediated activation of ERK1/2 and, subsequently, Elk-1 in breast cancer cells [120]. Interestingly, Cho et al. reported that the MAPK pathway was not involved in ROS-dependent 15d-PGJ2-mediated apoptosis [113]. The induction of ROS by 15d-PGJ2 can be attributed to induction of NADPH oxidase [115] and heme oxygenase-1, which degrades heme, generating ferrous ions that can produce ROS through the Fenton reaction [119,122]. Recently, Na et al. reported that the electrophilic α,β-unsaturated carbonyl group of 15d-PGJ2 is essential for ROS induction as 9,10-dihydro-PGJ2, a non-electrophilic analogue of 15d-PGJ2, failed to induce ROS and ROS-dependent apoptosis [121]. Additionally, 15d-PGJ2 can reportedly modulate the activities of transcription factors involved in redox homeostasis, namely NF-κB, activator protein-1, and Nrf2 [123], which could further account for its ROS-mediated anticancer effects. Although 15d-PGJ2 has shown promise as a pro-oxidative anticancer drug, further research is needed to verify the context-dependent role of this PPAR-γ inhibitor. Specifically, ROS accumulation by 15d-PGJ2 has been reported to stabilize hypoxia-inducible factor-1α, which is a protumorigenic transcription factor, through direct modification of its inhibitor prolyl-4-hydroxylase 2 [119].

2.3.3. Tetraethylthiuram Disulfide

Apart from developing novel anticancer drugs, repurposing drugs that have previously been approved for other conditions can also prove beneficial for the treatment of cancers. Disulfiram (tetraethylthiuram disulfide [DSF], also known as antabuse) is one such drug that is approved by the FDA for the treatment of alcoholism. Its pharmacodynamics and pharmacokinetics are well established, and its commercial availability is widespread. Recently, DSF-Copper (Cu) complexes have been shown to act as potent ROS inducers, specifically through the MAPK/ERK and PI3K/AKT pathways [124]. Cu is known to generate ROS; however, its use in therapeutics is limited because of its tightly controlled intracellular transport. This limitation can reportedly be overcome through complex formation with the DSF derivative N,N-diethyldithiocarbamate, which induces ROS-mediated apoptosis [125]. DSF/Cu complexes have been shown to increase ROS levels and induce G0/G1 cell cycle arrest in acute myeloid leukemia [126], and specifically trigger MAPK-mediated apoptosis in gastric cancer in an ROS-dependent manner [127]. Cu dependent ROS induction through DSF has been used to target prostate cancer, breast cancer, and lymphoid malignancies in preclinical studies [128,129,130]. Apart from Cu, other metal ions have also exhibited anticancer properties and great potential as cancer therapeutics. Namely, gold (III)-dithiocarbamate complexes were shown to induce ROS in breast cancer in part by interfering with the proteosome [131], as ROS can cause cellular disruptions that lead to the inactivation of the ubiquitination–proteasome pathway.

3. Pro-Oxidative Drugs in the Clinical Setting

This section discusses pro-oxidative anticancer drugs that are being investigated in clinical trials or are already in clinical use for cancer therapy. Table 2 and Table 3 summarize clinical trials for the drugs discussed in this section.

3.1. Pro-Oxidative Drugs in Clinical Trials

3.1.1. Choline Tetrathiomolybdate (ATN-224)

Choline tetrathiomolybdate (ATN-224) is an analogue of the copper chelator tetrathiomolybdate that is used for the treatment of Wilson’s disease. ATN-224 was reported to exhibit anticancer activity via inhibition of SOD1, which resulted in increased superoxide levels and subsequent induction of ROS-dependent apoptosis in multiple myeloma cells [132]. This effect was further characterized in vitro in liver, ovarian, non-small cell lung cancer, colorectal, and pancreatic cancer [2]. Consistently, ATN-244 has been investigated in various clinical trials for solid organ tumors (including prostate, breast, esophageal, colorectal, and hepatocellular cancer) and multiple myeloma (Table 2) [2]. However, the drug has not yet entered any Phase 3 trials. Recently, ATN-224 has been increasingly promoted as an adjuvant drug that can reverse chemoresistance. Combination treatment with cisplatin was found to increase ROS levels, decrease glutathione levels, and increase Platinum–DNA adduct formation, which enhanced the anticancer activity of cisplatin both in vitro and in vivo for non-small cell lung cancer [133]. Ryumon et al. previously reported similar findings for head and neck squamous cell carcinoma [134]. Additionally, the same study reported that pretreatment with ATN-224 sensitized the cisplatin-resistant A431-CDDP-R cell line to cisplatin due to suppression of ATPase copper transporting beta, suggesting that ATN-224 can be used as a chemosensitizing agent. Further studies are needed to assess the potential clinical use or repurposing of ATN-224 as a chemosensitizing adjuvant drug for other chemotherapeutic agents and cancer types.

3.1.2. 2-Methoxyoestradiol

2-methoxyoestradiol (Panzem), an estradiol metabolite, and its formulation, 2-methoxyoestradiol nanocrystal colloidal dispersion, have been investigated in Phase 1 and 2 clinical trials for glioblastoma multiforme, ovarian cancer, multiple myeloma, prostate cancer, and renal cell carcinoma (Table 2), and have FDA orphan drug designation for the former three [135]. The anticancer activity of 2-methoxyoestradiol can be attributed to increased ROS production through a debated mechanism, resulting in a loss of mitochondrial membrane potential [136,137] and nuclear localization of nitric oxide (NO) synthase, resulting in increased NO production and subsequent NO-induced DNA damage [138,139], both of which trigger apoptosis. Ongoing research involving 2-methoxyoestradiol is aimed at combating its main limitation, which is its poor bioavailability. Consistently, sulphamoylated analogues [140,141] and nanomedicine-based approaches [142,143] have been reported to improve the pharmacokinetics of 2-methoxyoestradiol in vivo and in patient-derived xenograft models.

3.1.3. Curcumin and Its Derivatives

Curcumin is the bioactive component of Curcuma longa L. (turmeric) and has been actively studied in the past few decades for its various pharmacological properties, including anticancer activity. Over the years, various derivatives of curcumin have been developed to improve its bioavailability and stability [144]. ROS induction has been implicated as one of the mechanisms of the anticancer activity of curcumin and its derivatives in various cancers, including leukemias [145,146], prostate cancer [147,148], colorectal cancer [149,150], gastric cancer [151,152], lung cancer [149,153], glioma [154], breast cancer [149], and cholangiocarcinoma [155]. Curcumin induces ROS by inhibiting the activity of various ROS-related metabolic enzymes, such as CAT, SOD1, glyoxalase 1, and NAD(P)H dehydrogenase [quinone] 1 [146,149]. ROS accumulation further mediates G1 or G2/M cell cycle arrest [146,147,150,154], senescence [146], and apoptosis. Many pathways have been implicated in ROS-mediated induction of apoptosis by curcumin, including downregulation of AKT phosphorylation [145], endoplasmic reticulum stress (namely through the PERK–ATF4–CHOP axis) [150,151,153], activation of the JNK pathway [151], and inhibition of STAT3 [155]. Curcumin has been studied extensively in in vivo cancer models [156] and has been investigated in Phase I and II for various cancers, including multiple myeloma, lung, breast, colorectal, and prostate cancers, with generally beneficial results (Table 2) [23]. Presently, there are two ongoing clinical trials for curcumin for invasive breast (NCT03980509) and unresectable pancreatic (NCT02336087) cancers. Additionally, the combination of curcumin and piperine, a pro-oxidative phytochemical that drastically increases the bioavailability of curcumin in humans [99], is also being investigated in clinical trials (NCT02598726 [Phase 1] and NCT04731844 [Phase 2]).

3.2. Pro-Oxidative Drugs in Clinical Use

Many of the chemotherapeutic drugs that are currently used as standard-of-care treatment for cancers are known to induce ROS. However, the induction of ROS may not necessarily be the main mechanism of action, nor a direct consequence of the drug. For example, paclitaxel, which is used for the treatment of breast, endometrial, and ovarian cancers, exerts its anticancer effect by stabilizing tubulins. This prevents the disassembly of microtubules and consequently induces mitotic arrest, which in turn induces cell death [157]. ROS induction has been suggested as a secondary/alternative mechanism of action of paclitaxel and has been reported in osteosarcoma [158], prostate cancer [159], and non-small-cell lung cancer [160] cells. However, of these studies, only one reported that the use of the ROS scavenger N-acetylcysteine abrogated paclitaxel-mediated effects [159]. Moreover, it has only recently been clarified that mitochondrial accumulation, a consequence of paclitaxel-induced mitotic arrest, causes mitochondrial oxidative stress [161]. This lack of in-depth clarification is true for other approved and clinically used drugs with proposed pro-oxidative activities, such as rituximab, used for the treatment of B-cell lymphomas [10]. Hence, it is important to clarify whether ROS induction directly plays into the anticancer effects mediated by chemotherapeutic drugs.

In this section, we have highlighted cisplatin and doxorubicin as examples of approved/standard-of-care anticancer drugs that directly induce ROS, which further contributes to their anticancer activity. Other examples include motexafin gadolinium (an electron acceptor that increases superoxide production; used in the treatment of breast cancer and malignant melanoma) [162], arsenic trioxide (inhibits SOD and TrxR; used in the treatment of relapsing acute myeloid leukemia) [135], and imexon (disrupts GSH activity, causing depletion of GSH pool; used in the treatment of ovarian cancer, multiforme glioblastoma, and multiple myeloma) [135,162].

3.2.1. Cisplatin

Cisplatin is a platinum-based chemotherapeutic drug that is widely used for the treatment of several cancers, including ovarian, bladder, and testicular cancers. The main mechanism of the anticancer activity of cisplatin can be attributed to DNA–platinum adduct formation, which induces p53-mediated cell cycle arrest and apoptosis [163]. However, oxidative stress independent of nuclear DNA damage has been implicated as one of the mechanisms underlying its cytotoxic effect [164]. Cisplatin induces generation of mitochondrial ROS, which compromise mitochondrial function and membrane potential [165], mitochondrial DNA integrity, and promote mitochondrial biogenesis [164,166], the latter of which further increases mitochondrial ROS levels. Consistently, mitochondrial content was found to correspond to cisplatin sensitivity in ovarian cancer; pharmacological increase in ROS sensitized cisplatin-resistant ovarian cancer cells to cisplatin-induced oxidative stress-mediated apoptosis [166]. Downstream of mitochondrial ROS, cisplatin induces ROS-dependent autophagy and apoptosis through the JNK [167] and Bax/Bak pathways [166], respectively. In contrast to nuclear-DNA damage-mediated cytotoxic effects, cisplatin induces oxidative stress independent of p53 status in head and neck squamous cell carcinoma [168]. The clinical use of cisplatin is often complicated by chemoresistance, as well as associated toxicities, including nephrotoxicity and hepatotoxicity. However, the use of cisplatin in combination with other therapeutic strategies can overcome these challenges. Consistently, there are numerous ongoing clinical trials that are investigating cisplatin in combination with other therapeutic strategies (Table 3).

3.2.2. Doxorubicin

Doxorubicin (Adramycin) is a widely used chemotherapeutic agent for various solid (including breast, ovarian, gastric, and thyroid cancers) and hematological cancers (including multiple myeloma, and acute lymphoblastic/myeloblastic leukemia), either alone, in combination with other drugs (such as cyclophosphamide), or as nanoformulations (such as Doxil) [169]. Although topoisomerase II inhibition is the main mechanism of action, doxorubicin also induces ROS generation through redox cycling into its unstable semiquinone, which releases ROS on conversion back to doxorubicin [170]. Additionally, doxorubicin as an iron chelator forms complexes that catalyze the conversion of H₂O₂ and superoxide into hydroxyl radicals or iron–peroxo complexes [169] and downregulates CAT and manganese superoxide dimutase activity [171,172]. Further, ROS induction by doxorubicin mediates p53-independent apoptosis in osteosarcoma cells [172]. Currently, various drug delivery approaches are being investigated to increase the bioavailability of doxorubicin as well as to decrease its side effects, namely cardiotoxicity. Consistently, liposomal and pegylated liposomal doxorubicin are in clinical use for breast cancer [173]. Additionally, pegylated liposomal doxorubicin and other drug delivery approaches for doxorubicin are being studied in clinical trials alone or in combination with other chemotherapeutic agents (Table 3). In this regard, doxorubicin-loaded nanoparticles have also shown promise in in vitro and in vivo studies [174,175,176]. Zheng et al. reported that doxorubicin loaded arginine–glycine–aspartic acid-modified solid lipid nanoparticles exhibited better cellular uptake in both breast cancer and normal cells and higher cytotoxicity against breast cancer cells than doxorubicin in vitro [176]. Additionally, they exhibited higher plasma concentrations and better biodistribution (less drug concentration in kidneys and hearts) compared to doxorubicin in vivo.

4. Concluding Remarks

The paradoxical role of ROS in cancer cells presents a unique therapeutic approach that has garnered much attention in recent years. As highlighted in this review, pro-oxidative anticancer drugs, such as cisplatin and doxorubicin, are already being used clinically to treat various cancers, and other pro-oxidative anticancer drugs, such as curcumin and its derivatives, carnosol, and 15d-PGJ2, are in various stages of research and development. The pro-oxidative drugs discussed in the present review induce ROS through diverse mechanisms (Figure 2), which further regulate various signaling pathways to induce anticancer effects (Figure 3); this has been schematically summarized in Figure 2 and Figure 3.

As presented herein, targeting the skewed redox balance of cancer cells via pro-oxidative drugs, specifically pro-oxidative phytochemicals, presents a promising therapeutic approach; however, further research is needed on this front. One of the main aspects which seems to be overlooked is the characterization of mechanisms through which anticancer drugs induce ROS, as reflected with respect to pro-oxidative phytochemicals in Table 1. This is of specific importance as it can help direct the selection of pro-oxidative anticancer drugs by clinicians. For example, drugs that inhibit SOD1 can potentially be used for the treatment of cancers in which SOD1 is overexpressed, such as non-small cell lung cancer and breast cancer [177]. Additionally, although numerous pro-oxidative phytochemicals have been reported to exhibit promising anticancer activity in vitro, there is a lack of sufficient in vivo studies. Moreover, poor bioavailability, a limitation common to many phytochemicals [178], further complicates the matter and hinders their clinical application. Consistently, nanoparticle-based approaches are being investigated to overcome this limitation; however, further research is needed on this front to circumvent the inherent challenges created by this approach, which can limit clinical translation, such as target specificity and toxicity to normal cells [179].

The context-dependent role of phytochemical compounds also needs to be investigated further, as based on the concentration used, phytochemicals, namely resveratrol, are known to function as both antioxidants and pro-oxidants. Although antioxidants have been proposed as adjuvants to counteract the side effects of chemotherapy, the rationale for the same is debatable. While ROS drive cancer cell survival and progression, the disrupted redox balance is further augmented by pro-oxidative anticancer drugs (Figure 1). Given that many of the clinically approved anticancer drugs induce ROS either directly or indirectly, the use of antioxidants for anticancer therapy as opposed to cancer prevention seems counterproductive and could potentially decrease the ROS-dependent anticancer activity of such drugs [3,180]. Hence, it is paramount that in the future, the concentration- and context-dependent roles of phytochemicals should be carefully investigated, with specific focus on the pro-oxidative effects. Moreover, investigation on this front would further facilitate the use of pro-oxidative phytochemicals as adjuvant drugs that can synergize with or sensitize resistant cells to clinically used pro-oxidative anticancer agents; for example, PPL in combination with platinum-based drugs, such as cisplatin [18] and oxaliplatin [19]. Further, it is important to clarify whether ROS induction plays directly into the anticancer effects of chemotherapeutic drugs and to elucidate the underlying mechanisms to exploit the above-mentioned synergistic effects.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Enlarge this image.

Figure 1. The paradoxical role of reactive oxygen species (ROS) in cancer. In normal cells, ROS levels are tightly regulated by a balance between pro-oxidative cellular processes and the antioxidant responses. Several factors can increase ROS production in cancer cells to levels which provide a survival advantage by activating tumorigenic pathways to drive tumor progression. This can be therapeutically exploited through ROS modulation with pro-oxidative drugs which tip the already skewed redox balance and further increase ROS production to levels that mediate oxidative stress-induced cell death. ROS—reactive oxygen species.

Enlarge this image.

Figure 2. Mechanisms of ROS modulation by pro-oxidative drugs. Anticancer drugs with pro-oxidative function modulate ROS levels through various mechanisms that influence both antioxidant and oxidant molecules involved in maintaining redox balance. The mechanisms utilized by the pro-oxidative anticancer drugs highlighted in this review are summarized in this figure. ATN-224—choline tetrathiomolybdate; LCS-1; Lung cancer screen 1—4,5-dichloro-2-m-tolylpyridazin-3(2H)-one; OA—oleanolic acid; ROS—reactive oxygen species; 15d-PGJ2—15-deoxy-Δ12,14-prostaglandin J2.

Enlarge this image.

Figure 3. Pathways through which pro-oxidative drugs mediate their anticancer effects in a ROS-dependent manner. Pro-oxidative anticancer drugs mediate their anticancer effects, such as autophagy, apoptosis, cell cycle arrest, ER stress, and senescence, downstream of ROS induction through ROS-dependent activation of various signaling pathways. The signaling pathways activated by the pro-oxidative anticancer drugs highlighted in this review are summarized in this figure. ATN-224—choline tetrathiomolybdate; DSF—disulfiram; ER—endoplasmic reticulum; LCS-1; Lung cancer screen 1—4,5-dichloro-2-m-tolylpyridazin-3(2H)-one; OA—oleanolic acid; PPL—piperlongumine; ROS—reactive oxygen species; 15d-PGJ2—15-deoxy-Δ12,14-prostaglandin J2.

References

1. Liou, G.-Y.; Storz, P. Reactive oxygen species in cancer. Free Radic. Res.; 2010; 44, pp. 479-496. [DOI: https://dx.doi.org/10.3109/10715761003667554]

2. Reczek, C.R.; Chandel, N.S. The Two Faces of Reactive Oxygen Species in Cancer. Annu. Rev. Cancer Biol.; 2017; 1, pp. 79-98. [DOI: https://dx.doi.org/10.1146/annurev-cancerbio-041916-065808]

3. Yang, H.; Villani, R.M.; Wang, H.; Simpson, M.J.; Roberts, M.S.; Tang, M.; Liang, X. The role of cellular reactive oxygen species in cancer chemotherapy. J. Exp. Clin. Cancer Res.; 2018; 37, 266. [DOI: https://dx.doi.org/10.1186/s13046-018-0909-x]

4. Sies, H.; Jones, D.P. Reactive oxygen species (ROS) as pleiotropic physiological signalling agents. Nat. Rev. Mol. Cell Biol.; 2020; 21, pp. 363-383. [DOI: https://dx.doi.org/10.1038/s41580-020-0230-3]

5. Wang, Y.; Qi, H.; Liu, Y.; Duan, C.; Liu, X.; Xia, T.; Chen, D.; Piao, H.; Liu, H.-X. The double-edged roles of ROS in cancer prevention and therapy. Theranostics; 2021; 11, pp. 4839-4857. [DOI: https://dx.doi.org/10.7150/thno.56747] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33754031]

6. Weinberg, F.; Ramnath, N.; Nagrath, D. Reactive Oxygen Species in the Tumor Microenvironment: An Overview. Cancers; 2019; 11, 1191. [DOI: https://dx.doi.org/10.3390/cancers11081191] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31426364]

7. Felty, Q.; Singh, K.P.; Roy, D. Estrogen-induced G1/S transition of G0-arrested estrogen-dependent breast cancer cells is regulated by mitochondrial oxidant signaling. Oncogene; 2005; 24, pp. 4883-4893. [DOI: https://dx.doi.org/10.1038/sj.onc.1208667]

8. Weinberg, F.; Hamanaka, R.; Wheaton, W.W.; Weinberg, S.; Joseph, J.; Lopez, M.; Kalyanaraman, B.; Mutlu, G.M.; Budinger, G.R.S.; Chandel, N.S. Mitochondrial metabolism and ROS generation are essential for Kras-mediated tumorigenicity. Proc. Natl. Acad. Sci. USA; 2010; 107, pp. 8788-8793. [DOI: https://dx.doi.org/10.1073/pnas.1003428107]

9. Ferrara, N. VEGF-A: A critical regulator of blood vessel growth. Eur. Cytokine Netw.; 2009; 20, pp. 158-163. [DOI: https://dx.doi.org/10.1684/ecn.2009.0170]

10. Perillo, B.; Di Donato, M.; Pezone, A.; Di Zazzo, E.; Giovannelli, P.; Galasso, G.; Castoria, G.; Migliaccio, A. ROS in cancer therapy: The bright side of the moon. Exp. Mol. Med.; 2020; 52, pp. 192-203. [DOI: https://dx.doi.org/10.1038/s12276-020-0384-2] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32060354]

11. Che, M.; Wang, R.; Li, X.; Wang, H.-Y.; Zheng, X.F.S. Expanding roles of superoxide dismutases in cell regulation and cancer. Drug Discov. Today; 2016; 21, pp. 143-149. [DOI: https://dx.doi.org/10.1016/j.drudis.2015.10.001] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/26475962]

12. Choudhari, A.S.; Mandave, P.C.; Deshpande, M.; Ranjekar, P.; Prakash, O. Phytochemicals in Cancer Treatment: From Preclinical Studies to Clinical Practice. Front. Pharmacol.; 2020; 10, 1614. [DOI: https://dx.doi.org/10.3389/fphar.2019.01614] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32116665]

13. Parama, D.; Rana, V.; Girisa, S.; Verma, E.; Daimary, U.D.; Thakur, K.K.; Kumar, A.; Kunnumakkara, A.B. The promising potential of piperlongumine as an emerging therapeutics for cancer. Explor. Target. Anti-Tumor Ther.; 2021; 2, pp. 323-354. [DOI: https://dx.doi.org/10.37349/etat.2021.00049]

14. Tripathi, S.K.; Biswal, B.K. Piperlongumine, a potent anticancer phytotherapeutic: Perspectives on contemporary status and future possibilities as an anticancer agent. Pharmacol. Res.; 2020; 156, 104772. [DOI: https://dx.doi.org/10.1016/j.phrs.2020.104772]

15. Zhang, Q.; Chen, W.; Lv, X.; Weng, Q.; Chen, M.; Cui, R.; Liang, G.; Ji, J. Piperlongumine, a Novel TrxR1 Inhibitor, Induces Apoptosis in Hepatocellular Carcinoma Cells by ROS-Mediated ER Stress. Front. Pharmacol.; 2019; 10, 1180. [DOI: https://dx.doi.org/10.3389/fphar.2019.01180]

16. Seok, J.S.; Jeong, C.H.; Petriello, M.C.; Seo, H.G.; Yoo, H.; Hong, K.; Han, S.G. Piperlongumine decreases cell proliferation and the expression of cell cycle-associated proteins by inhibiting Akt pathway in human lung cancer cells. Food Chem. Toxicol.; 2018; 111, pp. 9-18. [DOI: https://dx.doi.org/10.1016/j.fct.2017.10.058]

17. Wang, H.; Jiang, H.; Corbet, C.; de Mey, S.; Law, K.; Gevaert, T.; Feron, O.; De Ridder, M. Piperlongumine increases sensitivity of colorectal cancer cells to radiation: Involvement of ROS production via dual inhibition of glutathione and thioredoxin systems. Cancer Lett.; 2019; 450, pp. 42-52. [DOI: https://dx.doi.org/10.1016/j.canlet.2019.02.034]

18. Roh, J.-L.; Kim, E.H.; Park, J.Y.; Kim, J.W.; Kwon, M.; Lee, B.-H. Piperlongumine selectively kills cancer cells and increases cisplatin antitumor activity in head and neck cancer. Oncotarget; 2014; 5, pp. 9227-9238. [DOI: https://dx.doi.org/10.18632/oncotarget.2402]

19. Zhang, P.; Shi, L.; Zhang, T.; Hong, L.; He, W.; Cao, P.; Shen, X.; Zheng, P.; Xia, Y.; Zou, P. Piperlongumine potentiates the antitumor efficacy of oxaliplatin through ROS induction in gastric cancer cells. Cell. Oncol.; 2019; 42, pp. 847-860. [DOI: https://dx.doi.org/10.1007/s13402-019-00471-x] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31493144]

20. Zheng, L.; Fang, S.; Chen, A.; Chen, W.; Qiao, E.; Chen, M.; Shu, G.; Zhang, D.; Kong, C.; Weng, Q. et al. Piperlongumine synergistically enhances the antitumour activity of sorafenib by mediating ROS-AMPK activation and targeting CPSF7 in liver cancer. Pharmacol. Res.; 2022; 177, 106140. [DOI: https://dx.doi.org/10.1016/j.phrs.2022.106140]

21. Li, P.; Guo, X.; Liu, T.; Liu, Q.; Yang, J.; Liu, G. Evaluation of Hepatoprotective Effects of Piperlongumine Derivative PL 1–3-Loaded Albumin Nanoparticles on Lipopolysaccharide/d-Galactosamine-Induced Acute Liver Injury in Mice. Mol. Pharm.; 2022; 19, pp. 4576-4587. [DOI: https://dx.doi.org/10.1021/acs.molpharmaceut.2c00215] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35971845]

22. Choi, D.G.; Venkatesan, J.; Shim, M.S. Selective Anticancer Therapy Using Pro-Oxidant Drug-Loaded Chitosan–Fucoidan Nanoparticles. Int. J. Mol. Sci.; 2019; 20, 3220. [DOI: https://dx.doi.org/10.3390/ijms20133220] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31262038]

23. Salehi, B.; Mishra, A.; Nigam, M.; Sener, B.; Kilic, M.; Sharifi-Rad, M.; Fokou, P.; Martins, N.; Sharifi-Rad, J. Resveratrol: A Double-Edged Sword in Health Benefits. Biomedicines; 2018; 6, 91. [DOI: https://dx.doi.org/10.3390/biomedicines6030091]

24. Martins, L.A.M.; Coelho, B.P.; Behr, G.; Pettenuzzo, L.F.; Souza, I.C.C.; Moreira, J.C.F.; Borojevic, R.; Gottfried, C.; Guma, F.C.R. Resveratrol Induces Pro-oxidant Effects and Time-Dependent Resistance to Cytotoxicity in Activated Hepatic Stellate Cells. Cell Biochem. Biophys.; 2014; 68, pp. 247-257. [DOI: https://dx.doi.org/10.1007/s12013-013-9703-8]

25. San Hipólito-Luengo, Á.; Alcaide, A.; Ramos-González, M.; Cercas, E.; Vallejo, S.; Romero, A.; Talero, E.; Sánchez-Ferrer, C.F.; Motilva, V.; Peiró, C. Dual Effects of Resveratrol on Cell Death and Proliferation of Colon Cancer Cells. Nutr. Cancer; 2017; 69, pp. 1019-1027. [DOI: https://dx.doi.org/10.1080/01635581.2017.1359309]

26. Miki, H.; Uehara, N.; Kimura, A.; Sasaki, T.; Yuri, T.; Yoshizawa, K.; Tsubura, A. Resveratrol induces apoptosis via ROS-triggered autophagy in human colon cancer cells. Int. J. Oncol.; 2012; 40, pp. 1020-1028. [DOI: https://dx.doi.org/10.3892/ijo.2012.1325]

27. Cheng, L.; Yan, B.; Chen, K.; Jiang, Z.; Zhou, C.; Cao, J.; Qian, W.; Li, J.; Sun, L.; Ma, J. et al. Resveratrol-Induced Downregulation of NAF-1 Enhances the Sensitivity of Pancreatic Cancer Cells to Gemcitabine via the ROS/Nrf2 Signaling Pathways. Oxid. Med. Cell. Longev.; 2018; 2018, 9482018. [DOI: https://dx.doi.org/10.1155/2018/9482018] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29765509]

28. Almeida, T.C.; Melo, A.S.; Lima, A.P.B.; Branquinho, R.T.; da Silva, G.N. Resveratrol induces the production of reactive oxygen species, interferes with the cell cycle, and inhibits the cell migration of bladder tumour cells with different TP53 status. Nat. Prod. Res.; 2022; pp. 1-6. [DOI: https://dx.doi.org/10.1080/14786419.2022.2151007]

29. Ma, F.; Ma, Y.; Liu, K.; Gao, J.; Li, S.; Sun, X.; Li, G. Resveratrol induces DNA damage-mediated cancer cell senescence through the DLC1–DYRK1A–EGFR axis. Food Funct.; 2023; 14, pp. 1484-1497. [DOI: https://dx.doi.org/10.1039/D2FO01188C]

30. Zhang, L.; Dai, F.; Sheng, P.; Chen, Z.; Xu, Q.; Guo, Y. Resveratrol analogue 3,4,4′-trihydroxy-trans-stilbene induces apoptosis and autophagy in human non-small-cell lung cancer cells in vitro. Acta Pharmacol. Sin.; 2015; 36, pp. 1256-1265. [DOI: https://dx.doi.org/10.1038/aps.2015.46]

31. Çınar Ayan, İ.; Güçlü, E.; Vural, H.; Dursun, H.G. Piceatannol induces apoptotic cell death through activation of caspase-dependent pathway and upregulation of ROS-mediated mitochondrial dysfunction in pancreatic cancer cells. Mol. Biol. Rep.; 2022; 49, pp. 11947-11957. [DOI: https://dx.doi.org/10.1007/s11033-022-08006-8]

32. Li, C.; Wang, Z.; Lei, H.; Zhang, D. Recent progress in nanotechnology-based drug carriers for resveratrol delivery. Drug Deliv.; 2023; 30, 2174206. [DOI: https://dx.doi.org/10.1080/10717544.2023.2174206] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36852655]

33. Shanmugam, M.K.; Dai, X.; Kumar, A.P.; Tan, B.K.H.; Sethi, G.; Bishayee, A. Oleanolic acid and its synthetic derivatives for the prevention and therapy of cancer: Preclinical and clinical evidence. Cancer Lett.; 2014; 346, pp. 206-216. [DOI: https://dx.doi.org/10.1016/j.canlet.2014.01.016] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/24486850]

34. Li, X.; Song, Y.; Zhang, P.; Zhu, H.; Chen, L.; Xiao, Y.; Xing, Y. Oleanolic acid inhibits cell survival and proliferation of prostate cancer cells in vitro and in vivo through the PI3K/Akt pathway. Tumor Biol.; 2016; 37, pp. 7599-7613. [DOI: https://dx.doi.org/10.1007/s13277-015-4655-9]

35. Liu, J.; Wu, N.; Ma, L.-N.; Zhong, J.-T.; Liu, G.; Zheng, L.-H.; Lin, X.-K. p38 MAPK Signaling Mediates Mitochondrial Apoptosis in Cancer Cells Induced by Oleanolic Acid. Asian Pac. J. Cancer Prev.; 2014; 15, pp. 4519-4525. [DOI: https://dx.doi.org/10.7314/APJCP.2014.15.11.4519]

36. Gao, L.; Wang, Y.; Xu, Z.; Li, X.; Wu, J.; Liu, S.; Chu, P.; Sun, Z.; Sun, B.; Lin, Y. et al. SZC017, a novel oleanolic acid derivative, induces apoptosis and autophagy in human breast cancer cells. Apoptosis; 2015; 20, pp. 1636-1650. [DOI: https://dx.doi.org/10.1007/s10495-015-1179-0]

37. Cheng, B.; Chu, X.; Liu, R.; Ma, X.; Wang, M.; Zhang, J.; Jiao, P.; Gao, Q.; Ma, W.; Zhang, Y. et al. Synthesis of Novel Pentacyclic Triterpenoid Derivatives that Induce Apoptosis in Cancer Cells through a ROS-dependent, Mitochondrial-Mediated Pathway. Mol. Pharm.; 2023; 20, pp. 701-710. [DOI: https://dx.doi.org/10.1021/acs.molpharmaceut.2c00885] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36458832]

38. Akuetteh, P.D.P.; Huang, H.; Wu, S.; Zhou, H.; Jin, G.; Hong, W.; Yang, H.; Lan, L.; Shangguan, F.; Zhang, Q. Synthetic oleanane triterpenoid derivative CDDO-Me disrupts cellular bioenergetics to suppress pancreatic ductal adenocarcinoma via targeting SLC1A5. J. Biochem. Mol. Toxicol.; 2022; 36, e23192. [DOI: https://dx.doi.org/10.1002/jbt.23192]

39. Narożna, M.; Krajka-Kuźniak, V.; Bednarczyk-Cwynar, B.; Kucińska, M.; Kleszcz, R.; Kujawski, J.; Piotrowska-Kempisty, H.; Plewiński, A.; Murias, M.; Baer-Dubowska, W. Conjugation of Diclofenac with Novel Oleanolic Acid Derivatives Modulate Nrf2 and NF-κB Activity in Hepatic Cancer Cells and Normal Hepatocytes Leading to Enhancement of Its Therapeutic and Chemopreventive Potential. Pharmaceuticals; 2021; 14, 688. [DOI: https://dx.doi.org/10.3390/ph14070688]

40. Bian, M.; Sun, Y.; Liu, Y.; Xu, Z.; Fan, R.; Liu, Z.; Liu, W. A Gold(I) Complex Containing an Oleanolic Acid Derivative as a Potential Anti-Ovarian-Cancer Agent by Inhibiting TrxR and Activating ROS-Mediated ERS. Chem. Eur. J.; 2020; 26, pp. 7092-7108. [DOI: https://dx.doi.org/10.1002/chem.202000045]

41. Narożna, M.; Krajka-Kuźniak, V.; Kleszcz, R.; Bednarczyk-Cwynar, B.; Szaefer, H.; Baer-Dubowska, W. Activation of the Nrf2 response by oleanolic acid oxime morpholide (3-hydroxyiminoolean-12-en-28-oic acid morpholide) is associated with its ability to induce apoptosis and inhibit proliferation in HepG2 hepatoma cells. Eur. J. Pharmacol.; 2020; 883, 173307. [DOI: https://dx.doi.org/10.1016/j.ejphar.2020.173307]

42. Liese, J.; Hinrichs, T.M.; Lange, M.; Fulda, S. Cotreatment with sorafenib and oleanolic acid induces reactive oxygen species-dependent and mitochondrial-mediated apoptotic cell death in hepatocellular carcinoma cells. Anticancer Drugs; 2019; 30, pp. 209-217. [DOI: https://dx.doi.org/10.1097/CAD.0000000000000750]

43. Zhu, B.; Ren, C.; Du, K.; Zhu, H.; Ai, Y.; Kang, F.; Luo, Y.; Liu, W.; Wang, L.; Xu, Y. et al. Olean-28,13b-olide 2 plays a role in cisplatin-mediated apoptosis and reverses cisplatin resistance in human lung cancer through multiple signaling pathways. Biochem. Pharmacol.; 2019; 170, 113642. [DOI: https://dx.doi.org/10.1016/j.bcp.2019.113642]

44. Lange, M.; Abhari, B.A.; Hinrichs, T.M.; Fulda, S.; Liese, J. Identification of a novel oxidative stress induced cell death by Sorafenib and oleanolic acid in human hepatocellular carcinoma cells. Biochem. Pharmacol.; 2016; 118, pp. 9-17. [DOI: https://dx.doi.org/10.1016/j.bcp.2016.08.011]

45. Yin, Z.; Zhang, J.; Chen, L.; Guo, Q.; Yang, B.; Zhang, W.; Kang, W. Anticancer Effects and Mechanisms of Action of Plumbagin: Review of Research Advances. BioMed Res. Int.; 2020; 2020, 6940953. [DOI: https://dx.doi.org/10.1155/2020/6940953]

46. Hwang, G.H.; Ryu, J.M.; Jeon, Y.J.; Choi, J.; Han, H.J.; Lee, Y.-M.; Lee, S.; Bae, J.-S.; Jung, J.-W.; Chang, W. et al. The role of thioredoxin reductase and glutathione reductase in plumbagin-induced, reactive oxygen species-mediated apoptosis in cancer cell lines. Eur. J. Pharmacol.; 2015; 765, pp. 384-393. [DOI: https://dx.doi.org/10.1016/j.ejphar.2015.08.058]

47. Zhang, J.; Peng, S.; Li, X.; Liu, R.; Han, X.; Fang, J. Targeting thioredoxin reductase by plumbagin contributes to inducing apoptosis of HL-60 cells. Arch. Biochem. Biophys.; 2017; 619, pp. 16-26. [DOI: https://dx.doi.org/10.1016/j.abb.2017.02.007]

48. Tripathi, S.K.; Rengasamy, K.R.R.; Biswal, B.K. Plumbagin engenders apoptosis in lung cancer cells via caspase-9 activation and targeting mitochondrial-mediated ROS induction. Arch. Pharm. Res.; 2020; 43, pp. 242-256. [DOI: https://dx.doi.org/10.1007/s12272-020-01221-6]

49. Jaiswal, A.; Sabarwal, A.; Narayan Mishra, J.P.; Singh, R.P. Plumbagin induces ROS-mediated apoptosis and cell cycle arrest and inhibits EMT in human cervical carcinoma cells. RSC Adv.; 2018; 8, pp. 32022-32037. [DOI: https://dx.doi.org/10.1039/C8RA05339A]

50. Srinivas, P.; Gopinath, G.; Banerji, A.; Dinakar, A.; Srinivas, G. Plumbagin induces reactive oxygen species, which mediate apoptosis in human cervical cancer cells. Mol. Carcinog.; 2004; 40, pp. 201-211. [DOI: https://dx.doi.org/10.1002/mc.20031]

51. Pandey, K.; Tripathi, S.K.; Panda, M.; Biswal, B.K. Prooxidative activity of plumbagin induces apoptosis in human pancreatic ductal adenocarcinoma cells via intrinsic apoptotic pathway. Toxicol. Vitro; 2020; 65, 104788. [DOI: https://dx.doi.org/10.1016/j.tiv.2020.104788] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32027944]

52. Lin, C.-L.; Yu, C.-I.; Lee, T.-H.; Chuang, J.M.-J.; Han, K.-F.; Lin, C.-S.; Huang, W.-P.; Chen, J.Y.-F.; Chen, C.-Y.; Lin, M.-Y. et al. Plumbagin induces the apoptosis of drug-resistant oral cancer in vitro and in vivo through ROS-mediated endoplasmic reticulum stress and mitochondrial dysfunction. Phytomedicine; 2023; 111, 154655. [DOI: https://dx.doi.org/10.1016/j.phymed.2023.154655] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36689858]

53. Xue, D.; Pan, S.-T.; Zhou, X.; Ye, F.; Zhou, Q.; Shi, F.; He, F.; Yu, H.; Qiu, J. Plumbagin Enhances the Anticancer Efficacy of Cisplatin by Increasing Intracellular ROS in Human Tongue Squamous Cell Carcinoma. Oxid. Med. Cell. Longev.; 2020; 2020, 5649174. [DOI: https://dx.doi.org/10.1155/2020/5649174] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32308804]

54. Chao, C.-C.; Hou, S.-M.; Huang, C.C.; Hou, C.-H.; Chen, P.-C.; Liu, J.-F. Plumbagin induces apoptosis in human osteosarcoma through ROS generation, endoplasmic reticulum stress and mitochondrial apoptosis pathway. Mol. Med. Rep.; 2017; 16, pp. 5480-5488. [DOI: https://dx.doi.org/10.3892/mmr.2017.7222] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28849158]

55. Huang, H.; Xie, H.; Pan, Y.; Zheng, K.; Xia, Y.; Chen, W. Plumbagin Triggers ER Stress-Mediated Apoptosis in Prostate Cancer Cells via Induction of ROS. Cell. Physiol. Biochem.; 2018; 45, pp. 267-280. [DOI: https://dx.doi.org/10.1159/000486773]

56. Zhou, S.-F.; Pan, S.-T.; Qin, Y.; Zhou, Z.-W.; He, Z.; Zhang, X.; Yang, T.; Yang, Y.-X.; Wang, D.; Qiu, J. Plumbagin induces G2/M arrest, apoptosis, and autophagy via p38 MAPK- and PI3K/Akt/mTOR-mediated pathways in human tongue squamous cell carcinoma cells. Drug Des. Devel. Ther.; 2015; 9, 1601. [DOI: https://dx.doi.org/10.2147/DDDT.S76057]

57. Xu, T.-P.; Shen, H.; Liu, L.-X.; Shu, Y.-Q. Plumbagin from Plumbago Zeylanica L Induces Apoptosis in Human Non-small Cell Lung Cancer Cell Lines through NF-κB Inactivation. Asian Pac. J. Cancer Prev.; 2013; 14, pp. 2325-2331. [DOI: https://dx.doi.org/10.7314/APJCP.2013.14.4.2325]

58. Zhang, R.; Wang, Z.; You, W.; Zhou, F.; Guo, Z.; Qian, K.; Xiao, Y.; Wang, X. Suppressive effects of plumbagin on the growth of human bladder cancer cells via PI3K/AKT/mTOR signaling pathways and EMT. Cancer Cell Int.; 2020; 20, 520. [DOI: https://dx.doi.org/10.1186/s12935-020-01607-y]

59. Checker, R.; Gambhir, L.; Sharma, D.; Kumar, M.; Sandur, S.K. Plumbagin induces apoptosis in lymphoma cells via oxidative stress mediated glutathionylation and inhibition of mitogen-activated protein kinase phosphatases (MKP1/2). Cancer Lett.; 2015; 357, pp. 265-278. [DOI: https://dx.doi.org/10.1016/j.canlet.2014.11.031]

60. Abedinpour, P.; Baron, V.T.; Chrastina, A.; Rondeau, G.; Pelayo, J.; Welsh, J.; Borgström, P. Plumbagin improves the efficacy of androgen deprivation therapy in prostate cancer: A pre-clinical study. Prostate; 2017; 77, pp. 1550-1562. [DOI: https://dx.doi.org/10.1002/pros.23428]

61. Adetunji, T.L.; Olawale, F.; Olisah, C.; Adetunji, A.E.; Aremu, A.O. Capsaicin: A Two-Decade Systematic Review of Global Research Output and Recent Advances Against Human Cancer. Front. Oncol.; 2022; 12, 908487. [DOI: https://dx.doi.org/10.3389/fonc.2022.908487]

62. Zhang, S.; Wang, D.; Huang, J.; Hu, Y.; Xu, Y. Application of capsaicin as a potential new therapeutic drug in human cancers. J. Clin. Pharm. Ther.; 2020; 45, pp. 16-28. [DOI: https://dx.doi.org/10.1111/jcpt.13039]

63. Yang, K.; Pyo, J.; Kim, G.-Y.; Yu, R.; Han, I.; Ju, S.; Kim, W.; Kim, B.-S. Capsaicin induces apoptosis by generating reactive oxygen species and disrupting mitochondrial transmembrane potential in human colon cancer cell lines. Cell. Mol. Biol. Lett.; 2009; 14, 3. [DOI: https://dx.doi.org/10.2478/s11658-009-0016-2]

64. Sánchez, A.M.; Sánchez, M.G.; Malagarie-Cazenave, S.; Olea, N.; Díaz-Laviada, I. Induction of apoptosis in prostate tumor PC-3 cells and inhibition of xenograft prostate tumor growth by the vanilloid capsaicin. Apoptosis; 2006; 11, pp. 89-99. [DOI: https://dx.doi.org/10.1007/s10495-005-3275-z]

65. Sánchez, A.M.; Malagarie-Cazenave, S.; Olea, N.; Vara, D.; Chiloeches, A.; Díaz-Laviada, I. Apoptosis induced by capsaicin in prostate PC-3 cells involves ceramide accumulation, neutral sphingomyelinase, and JNK activation. Apoptosis; 2007; 12, pp. 2013-2024. [DOI: https://dx.doi.org/10.1007/s10495-007-0119-z]

66. Yang, Z.-H.; Wang, X.-H.; Wang, H.-P.; Hu, L.-Q.; Zheng, X.-M.; Li, S.-W. Capsaicin Mediates Cell Death in Bladder Cancer T24 Cells Through Reactive Oxygen Species Production and Mitochondrial Depolarization. Urology; 2010; 75, pp. 735-741. [DOI: https://dx.doi.org/10.1016/j.urology.2009.03.042]

67. Lee, J.-S.; Chang, J.-S.; Lee, J.Y.; Kim, J.-A. Capsaicin-induced apoptosis and reduced release of reactive oxygen species in MBT-2 Murine Bladder Tumor cells. Arch. Pharm. Res.; 2004; 27, pp. 1147-1153. [DOI: https://dx.doi.org/10.1007/BF02975121]

68. Qian, K.; Wang, G.; Cao, R.; Liu, T.; Qian, G.; Guan, X.; Guo, Z.; Xiao, Y.; Wang, X. Capsaicin Suppresses Cell Proliferation, Induces Cell Cycle Arrest and ROS Production in Bladder Cancer Cells through FOXO3a-Mediated Pathways. Molecules; 2016; 21, 1406. [DOI: https://dx.doi.org/10.3390/molecules21101406]

69. Hacioglu, C. Capsaicin inhibits cell proliferation by enhancing oxidative stress and apoptosis through SIRT1/NOX4 signaling pathways in HepG2 and HL-7702 cells. J. Biochem. Mol. Toxicol.; 2022; 36, e22974. [DOI: https://dx.doi.org/10.1002/jbt.22974]

70. Pramanik, K.C.; Boreddy, S.R.; Srivastava, S.K. Role of Mitochondrial Electron Transport Chain Complexes in Capsaicin Mediated Oxidative Stress Leading to Apoptosis in Pancreatic Cancer Cells. PLoS ONE; 2011; 6, e20151. [DOI: https://dx.doi.org/10.1371/journal.pone.0020151]

71. Shi, J.; Li, J.; Xu, Z.; Chen, L.; Luo, R.; Zhang, C.; Gao, F.; Zhang, J.; Fu, C. Celastrol: A Review of Useful Strategies Overcoming its Limitation in Anticancer Application. Front. Pharmacol.; 2020; 11, 558741. [DOI: https://dx.doi.org/10.3389/fphar.2020.558741] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/33364939]

72. Liu, M.; Fan, Y.; Li, D.; Han, B.; Meng, Y.; Chen, F.; Liu, T.; Song, Z.; Han, Y.; Huang, L. et al. Ferroptosis inducer erastin sensitizes NSCLC cells to celastrol through activation of the ROS–mitochondrial fission–mitophagy axis. Mol. Oncol.; 2021; 15, pp. 2084-2105. [DOI: https://dx.doi.org/10.1002/1878-0261.12936]

73. Kim, J.H.; Lee, J.O.; Lee, S.K.; Kim, N.; You, G.Y.; Moon, J.W.; Sha, J.; Kim, S.J.; Park, S.H.; Kim, H.S. Celastrol suppresses breast cancer MCF-7 cell viability via the AMP-activated protein kinase (AMPK)-induced p53–polo like kinase 2 (PLK-2) pathway. Cell. Signal.; 2013; 25, pp. 805-813. [DOI: https://dx.doi.org/10.1016/j.cellsig.2012.12.005] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/23266469]

74. Qi, B.; Qigao, Y.; Zhang, P.; Ren, Y.; Liu, H.; Liu, T.; Zhu, L.; Chen, Y. Celastrol enhances tamoxifen sensitivity in the treatment of triple negative breast cancer via mitochondria mediated apoptosis pathway. Am. J. Transl. Res.; 2023; 15, pp. 2703-2715.

75. Moreira, H.; Szyjka, A.; Paliszkiewicz, K.; Barg, E. Prooxidative Activity of Celastrol Induces Apoptosis, DNA Damage, and Cell Cycle Arrest in Drug-Resistant Human Colon Cancer Cells. Oxid. Med. Cell. Longev.; 2019; 2019, 6793957. [DOI: https://dx.doi.org/10.1155/2019/6793957] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31485297]

76. Xu, H.; Zhao, H.; Ding, C.; Jiang, D.; Zhao, Z.; Li, Y.; Ding, X.; Gao, J.; Zhou, H.; Luo, C. et al. Celastrol suppresses colorectal cancer via covalent targeting peroxiredoxin 1. Signal Transduct. Target. Ther.; 2023; 8, 51. [DOI: https://dx.doi.org/10.1038/s41392-022-01231-4]

77. Xu, L.-N.; Zhao, N.; Chen, J.-Y.; Ye, P.-P.; Nan, X.-W.; Zhou, H.-H.; Jiang, Q.-W.; Yang, Y.; Huang, J.-R.; Yuan, M.-L. et al. Celastrol Inhibits the Growth of Ovarian Cancer Cells in vitro and in vivo. Front. Oncol.; 2019; 9, 2. [DOI: https://dx.doi.org/10.3389/fonc.2019.00002]

78. Chen, X.; Zhao, Y.; Luo, W.; Chen, S.; Lin, F.; Zhang, X.; Fan, S.; Shen, X.; Wang, Y.; Liang, G. Celastrol induces ROS-mediated apoptosis via directly targeting peroxiredoxin-2 in gastric cancer cells. Theranostics; 2020; 10, pp. 10290-10308. [DOI: https://dx.doi.org/10.7150/thno.46728]

79. Chadalapaka, G.; Jutooru, I.; Safe, S. Celastrol decreases specificity proteins (Sp) and fibroblast growth factor receptor-3 (FGFR3) in bladder cancer cells. Carcinogenesis; 2012; 33, pp. 886-894. [DOI: https://dx.doi.org/10.1093/carcin/bgs102]

80. Chen, G.; Zhang, X.; Zhao, M.; Wang, Y.; Cheng, X.; Wang, D.; Xu, Y.; Du, Z.; Yu, X. Celastrol targets mitochondrial respiratory chain complex I to induce reactive oxygen species-dependent cytotoxicity in tumor cells. BMC Cancer; 2011; 11, 170. [DOI: https://dx.doi.org/10.1186/1471-2407-11-170]

81. Han, X.; Sun, S.; Zhao, M.; Cheng, X.; Chen, G.; Lin, S.; Guan, Y.; Yu, X. Celastrol Stimulates Hypoxia-Inducible Factor-1 Activity in Tumor Cells by Initiating the ROS/Akt/p70S6K Signaling Pathway and Enhancing Hypoxia-Inducible Factor-1α Protein Synthesis. PLoS ONE; 2014; 9, e112470. [DOI: https://dx.doi.org/10.1371/journal.pone.0112470]

82. Nazim, U.; Yin, H.; Park, S. Autophagy flux inhibition mediated by celastrol sensitized lung cancer cells to TRAIL-induced apoptosis via regulation of mitochondrial transmembrane potential and reactive oxygen species. Mol. Med. Rep.; 2018; 19, pp. 984-993. [DOI: https://dx.doi.org/10.3892/mmr.2018.9757]

83. Wu, M.; Deng, C.; Lo, T.-H.; Chan, K.-Y.; Li, X.; Wong, C.-M. Peroxiredoxin, Senescence, and Cancer. Cells; 2022; 11, 1772. [DOI: https://dx.doi.org/10.3390/cells11111772]

84. Thapa, P.; Jiang, H.; Ding, N.; Hao, Y.; Alshahrani, A.; Wei, Q. The Role of Peroxiredoxins in Cancer Development. Biology; 2023; 12, 666. [DOI: https://dx.doi.org/10.3390/biology12050666]

85. Kim, Y.; Jang, H.H. The Role of Peroxiredoxin Family in Cancer Signaling. J. Cancer Prev.; 2019; 24, pp. 65-71. [DOI: https://dx.doi.org/10.15430/JCP.2019.24.2.65]

86. Johnson, J.J. Carnosol: A promising anti-cancer and anti-inflammatory agent. Cancer Lett.; 2011; 305, 1. [DOI: https://dx.doi.org/10.1016/j.canlet.2011.02.005]

87. Park, K.-W.; Kundu, J.; Chae, I.-G.; Kim, D.-H.; Yu, M.-H.; Kundu, J.K.; Chun, K.-S. Carnosol induces apoptosis through generation of ROS and inactivation of STAT3 signaling in human colon cancer HCT116 cells. Int. J. Oncol.; 2014; 44, pp. 1309-1315. [DOI: https://dx.doi.org/10.3892/ijo.2014.2281]

88. Al Dhaheri, Y.; Attoub, S.; Ramadan, G.; Arafat, K.; Bajbouj, K.; Karuvantevida, N.; AbuQamar, S.; Eid, A.; Iratni, R. Carnosol Induces ROS-Mediated Beclin1-Independent Autophagy and Apoptosis in Triple Negative Breast Cancer. PLoS ONE; 2014; 9, e109630. [DOI: https://dx.doi.org/10.1371/journal.pone.0109630]

89. Lo, Y.-C.; Lin, Y.-C.; Huang, Y.-F.; Hsieh, C.-P.; Wu, C.-C.; Chang, I.-L.; Chen, C.-L.; Cheng, C.-H.; Chen, H.-Y. Carnosol-Induced ROS Inhibits Cell Viability of Human Osteosarcoma by Apoptosis and Autophagy. Am. J. Chin. Med.; 2017; 45, pp. 1761-1772. [DOI: https://dx.doi.org/10.1142/S0192415X17500951]

90. Alsamri, H.; El Hasasna, H.; Al Dhaheri, Y.; Eid, A.H.; Attoub, S.; Iratni, R. Carnosol, a Natural Polyphenol, Inhibits Migration, Metastasis, and Tumor Growth of Breast Cancer via a ROS-Dependent Proteasome Degradation of STAT3. Front. Oncol.; 2019; 9, 743. [DOI: https://dx.doi.org/10.3389/fonc.2019.00743]

91. Alsamri, H.; Hasasna, H.E.; Baby, B.; Alneyadi, A.; Dhaheri, Y.A.; Ayoub, M.A.; Eid, A.H.; Vijayan, R.; Iratni, R. Carnosol Is a Novel Inhibitor of p300 Acetyltransferase in Breast Cancer. Front. Oncol.; 2021; 11, 664403. [DOI: https://dx.doi.org/10.3389/fonc.2021.664403] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34055630]

92. Alsamri, H.; Alneyadi, A.; Muhammad, K.; Ayoub, M.A.; Eid, A.; Iratni, R. Carnosol Induces p38-Mediated ER Stress Response and Autophagy in Human Breast Cancer Cells. Front. Oncol.; 2022; 12, 911615. [DOI: https://dx.doi.org/10.3389/fonc.2022.911615] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35712465]

93. Ishida, Y.; Yamasaki, M.; Yukizaki, C.; Nishiyama, K.; Tsubouchi, H.; Okayama, A.; Kataoka, H. Carnosol, rosemary ingredient, induces apoptosis in adult T-cell leukemia/lymphoma cells via glutathione depletion: Proteomic approach using fluorescent two-dimensional differential gel electrophoresis. Hum. Cell; 2014; 27, pp. 68-77. [DOI: https://dx.doi.org/10.1007/s13577-013-0083-6] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/24323765]

94. Tong, L.; Wu, S. The Mechanisms of Carnosol in Chemoprevention of Ultraviolet B-Light-Induced Non-Melanoma Skin Cancer Formation. Sci. Rep.; 2018; 8, 3574. [DOI: https://dx.doi.org/10.1038/s41598-018-22029-x] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29476131]

95. O’Neill, E.J.; Den Hartogh, D.J.; Azizi, K.; Tsiani, E. Anticancer Properties of Carnosol: A Summary of In Vitro and In Vivo Evidence. Antioxidants; 2020; 9, 961. [DOI: https://dx.doi.org/10.3390/antiox9100961]

96. Catanzaro, E.; Canistro, D.; Pellicioni, V.; Vivarelli, F.; Fimognari, C. Anticancer potential of allicin: A review. Pharmacol. Res.; 2022; 177, 106118. [DOI: https://dx.doi.org/10.1016/j.phrs.2022.106118]

97. Akkol, E.K.; Tatlı, I.I.; Karatoprak, G.Ş.; Ağar, O.T.; Yücel, Ç.; Sobarzo-Sánchez, E.; Capasso, R. Is Emodin with Anticancer Effects Completely Innocent? Two Sides of the Coin. Cancers; 2021; 13, 2733. [DOI: https://dx.doi.org/10.3390/cancers13112733]

98. Dey, D.; Hasan, M.M.; Biswas, P.; Papadakos, S.P.; Rayan, R.A.; Tasnim, S.; Bilal, M.; Islam, M.J.; Arshe, F.A.; Arshad, E.M. et al. Investigating the Anticancer Potential of Salvicine as a Modulator of Topoisomerase II and ROS Signaling Cascade. Front. Oncol.; 2022; 12, 899009. [DOI: https://dx.doi.org/10.3389/fonc.2022.899009]

99. Tiwari, A.; Mahadik, K.R.; Gabhe, S.Y. Piperine: A comprehensive review of methods of isolation, purification, and biological properties. Med. Drug Discov.; 2020; 7, 100027. [DOI: https://dx.doi.org/10.1016/j.medidd.2020.100027]

100. Mitra, S.; Anand, U.; Jha, N.K.; Shekhawat, M.S.; Saha, S.C.; Nongdam, P.; Rengasamy, K.R.R.; Proćków, J.; Dey, A. Anticancer Applications and Pharmacological Properties of Piperidine and Piperine: A Comprehensive Review on Molecular Mechanisms and Therapeutic Perspectives. Front. Pharmacol.; 2022; 12, 772418. [DOI: https://dx.doi.org/10.3389/fphar.2021.772418]

101. Wu, Y.-H.; Wu, Y.-R.; Li, B.; Yan, Z.-Y. Cryptotanshinone: A review of its pharmacology activities and molecular mechanisms. Fitoterapia; 2020; 145, 104633. [DOI: https://dx.doi.org/10.1016/j.fitote.2020.104633]

102. Somwar, R.; Shum, D.; Djaballah, H.; Varmus, H. Identification and Preliminary Characterization of Novel Small Molecules That Inhibit Growth of Human Lung Adenocarcinoma Cells. SLAS Discov.; 2009; 14, pp. 1176-1184. [DOI: https://dx.doi.org/10.1177/1087057109350919]

103. Somwar, R.; Erdjument-Bromage, H.; Larsson, E.; Shum, D.; Lockwood, W.W.; Yang, G.; Sander, C.; Ouerfelli, O.; Tempst, P.J.; Djaballah, H. et al. Superoxide dismutase 1 (SOD1) is a target for a small molecule identified in a screen for inhibitors of the growth of lung adenocarcinoma cell lines. Proc. Natl. Acad. Sci. USA; 2011; 108, pp. 16375-16380. [DOI: https://dx.doi.org/10.1073/pnas.1113554108]

104. Papa, L.; Hahn, M.; Marsh, E.L.; Evans, B.S.; Germain, D. SOD2 to SOD1 Switch in Breast Cancer. J. Biol. Chem.; 2014; 289, pp. 5412-5416. [DOI: https://dx.doi.org/10.1074/jbc.C113.526475]

105. Sajesh, B.V.; McManus, K.J. Targeting SOD1 induces synthetic lethal killing in BLM- and CHEK2-deficient colorectal cancer cells. Oncotarget; 2015; 6, pp. 27907-27922. [DOI: https://dx.doi.org/10.18632/oncotarget.4875]

106. McAndrew, E.N.; Lepage, C.C.; McManus, K.J. The synthetic lethal killing of RAD54B-deficient colorectal cancer cells by PARP1 inhibition is enhanced with SOD1 inhibition. Oncotarget; 2016; 7, pp. 87417-87430. [DOI: https://dx.doi.org/10.18632/oncotarget.13654]

107. Du, T.; Song, Y.; Ray, A.; Chauhan, D.; Anderson, K.C. Proteomic analysis identifies mechanism(s) of overcoming bortezomib resistance via targeting ubiquitin receptor Rpn13. Leukemia; 2021; 35, pp. 550-561. [DOI: https://dx.doi.org/10.1038/s41375-020-0865-2]

108. Ling, M.; Liu, Q.; Wang, Y.; Liu, X.; Jiang, M.; Hu, J. LCS-1 inhibition of superoxide dismutase 1 induces ROS-dependent death of glioma cells and degradates PARP and BRCA1. Front. Oncol.; 2022; 12, 937444. [DOI: https://dx.doi.org/10.3389/fonc.2022.937444]

109. Gupta, A.; Ahmad, A.; Singh, H.; Kaur, S.; Neethu, K.M.; Ansari, M.M.; Jayamurugan, G.; Khan, R. Nanocarrier Composed of Magnetite Core Coated with Three Polymeric Shells Mediates LCS-1 Delivery for Synthetic Lethal Therapy of BLM-Defective Colorectal Cancer Cells. Biomacromolecules; 2018; 19, pp. 803-815. [DOI: https://dx.doi.org/10.1021/acs.biomac.7b01607]

110. Hultsch, S.; Kankainen, M.; Paavolainen, L.; Kovanen, R.-M.; Ikonen, E.; Kangaspeska, S.; Pietiäinen, V.; Kallioniemi, O. Association of tamoxifen resistance and lipid reprogramming in breast cancer. BMC Cancer; 2018; 18, 850. [DOI: https://dx.doi.org/10.1186/s12885-018-4757-z]

111. Bie, Q.; Dong, H.; Jin, C.; Zhang, H.; Zhang, B. 15d-PGJ2 is a new hope for controlling tumor growth. Am. J. Transl. Res.; 2018; 10, pp. 648-658. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29636856]

112. Li, J.; Guo, C.; Wu, J. 15-Deoxy-∆-^12,14-Prostaglandin J₂ (15d-PGJ2), an Endogenous Ligand of PPAR-γ: Function and Mechanism. PPAR Res.; 2019; 2019, 7242030. [DOI: https://dx.doi.org/10.1155/2019/7242030] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31467514]

113. Cho, W.H.; Choi, C.H.; Park, J.Y.; Kang, S.K.; Kim, Y.K. 15-Deoxy-Δ^12,14-prostaglandin J2 (15d-PGJ2) Induces Cell Death Through Caspase-independent Mechanism in A172 Human Glioma Cells. Neurochem. Res.; 2006; 31, pp. 1247-1254. [DOI: https://dx.doi.org/10.1007/s11064-006-9157-0] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/17006759]

114. Su, R.-Y.; Chi, K.-H.; Huang, D.-Y.; Tai, M.-H.; Lin, W.-W. 15-deoxy-Δ^12,14-prostaglandin J₂ up-regulates death receptor 5 gene expression in HCT116 cells: Involvement of reactive oxygen species and C/EBP homologous transcription factor gene transcription. Mol. Cancer Ther.; 2008; 7, pp. 3429-3440. [DOI: https://dx.doi.org/10.1158/1535-7163.MCT-08-0498] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18852146]

115. Shin, S.-W.; Seo, C.-Y.; Han, H.; Han, J.-Y.; Jeong, J.-S.; Kwak, J.-Y.; Park, J.-I. 15d-PGJ2 Induces Apoptosis by Reactive Oxygen Species–mediated Inactivation of Akt in Leukemia and Colorectal Cancer Cells and Shows In vivo Antitumor Activity. Clin. Cancer Res.; 2009; 15, pp. 5414-5425. [DOI: https://dx.doi.org/10.1158/1078-0432.CCR-08-3101]

116. Dionne, S.; Levy, E.; Levesque, D.; Seidman, E.G. PPARgamma ligand 15-deoxy-delta 12,14-prostaglandin J₂ sensitizes human colon carcinoma cells to TWEAK-induced apoptosis. Anticancer Res.; 2010; 30, pp. 157-166.

117. Wang, J.-J.; Mak, O.-T. Induction of apoptosis by 15d-PGJ2 via ROS formation: An alternative pathway without PPARγ activation in non-small cell lung carcinoma A549 cells. Prostaglandins Other Lipid Mediat.; 2011; 94, pp. 104-111. [DOI: https://dx.doi.org/10.1016/j.prostaglandins.2011.01.004]

118. Yen, C.-C.; Hsiao, C.-D.; Chen, W.-M.; Wen, Y.-S.; Lin, Y.-C.; Chang, T.-W.; Yao, F.-Y.; Hung, S.-C.; Wang, J.-Y.; Chiu, J.-H. et al. Cytotoxic effects of 15d-PGJ2 against osteosarcoma through ROS-mediated AKT and cell cycle inhibition. Oncotarget; 2014; 5, pp. 716-725. [DOI: https://dx.doi.org/10.18632/oncotarget.1704]

119. Choi, J.-E.; Kim, J.-H.; Song, N.-Y.; Suh, J.; Kim, D.-H.; Kim, S.-J.; Na, H.-K.; Nadas, J.; Dong, Z.; Cha, Y.-N. et al. 15-Deoxy-Δ^12,14-prostaglandin J ₂ stabilizes hypoxia inducible factor-1α through induction of heme oxygenase-1 and direct modification ofprolyl-4-hydroxylase 2. Free Radic. Res.; 2016; 50, pp. 1140-1152. [DOI: https://dx.doi.org/10.1080/10715762.2016.1219352]

120. Kim, H.-R.; Lee, H.-N.; Lim, K.; Surh, Y.-J.; Na, H.-K. 15-Deoxy-Δ^12,14-prostaglandin J2 induces expression of 15-hydroxyprostaglandin dehydrogenase through Elk-1 activation in human breast cancer MDA-MB-231 cells. Mutat. Res. Mol. Mech. Mutagen.; 2014; 768, pp. 6-15. [DOI: https://dx.doi.org/10.1016/j.mrfmmm.2014.06.005]

121. Na, H.-K.; Yang, H.; Surh, Y.-J. 15-Deoxy-Δ^12,14 -prostaglandin J ₂ Induces Apoptosis in Ha-ras-transformed Human Breast Epithelial Cells by Targeting IκB kinase–NF-κB Signaling. J. Cancer Prev.; 2020; 25, pp. 100-110. [DOI: https://dx.doi.org/10.15430/JCP.2020.25.2.100]

122. Kim, D.-H.; Kim, J.-H.; Kim, E.-H.; Na, H.-K.; Cha, Y.-N.; Chung, J.H.; Surh, Y.-J. 15-Deoxy-Δ^12,14-prostaglandin J₂ upregulates the expression of heme oxygenase-1 and subsequently matrix metalloproteinase-1 in human breast cancer cells: Possible roles of iron and ROS. Carcinogenesis; 2009; 30, pp. 645-654. [DOI: https://dx.doi.org/10.1093/carcin/bgp012]

123. Kim, E.-H.; Surh, Y.-J. 15-Deoxy-Δ^12,14-prostaglandin J₂ as a potential endogenous regulator of redox-sensitive transcription factors. Biochem. Pharmacol.; 2006; 72, pp. 1516-1528. [DOI: https://dx.doi.org/10.1016/j.bcp.2006.07.030]

124. Xie, J.; Liu, J.; Zhao, M.; Li, X.; Wang, Y.; Zhao, Y.; Cao, H.; Ji, M.; Chen, M.; Hou, P. Disulfiram/Cu Kills and Sensitizes BRAF-Mutant Thyroid Cancer Cells to BRAF Kinase Inhibitor by ROS-Dependently Relieving Feedback Activation of MAPK/ERK and PI3K/AKT Pathways. Int. J. Mol. Sci.; 2023; 24, 3418. [DOI: https://dx.doi.org/10.3390/ijms24043418]

125. Yip, N.C.; Fombon, I.S.; Liu, P.; Brown, S.; Kannappan, V.; Armesilla, A.L.; Xu, B.; Cassidy, J.; Darling, J.L.; Wang, W. Disulfiram modulated ROS–MAPK and NFκB pathways and targeted breast cancer cells with cancer stem cell-like properties. Br. J. Cancer; 2011; 104, pp. 1564-1574. [DOI: https://dx.doi.org/10.1038/bjc.2011.126]

126. Hassani, S.; Ghaffari, P.; Chahardouli, B.; Alimoghaddam, K.; Ghavamzadeh, A.; Alizadeh, S.; Ghaffari, S.H. Disulfiram/copper causes ROS levels alteration, cell cycle inhibition, and apoptosis in acute myeloid leukaemia cell lines with modulation in the expression of related genes. Biomed. Pharmacother. Biomedecine Pharmacother.; 2018; 99, pp. 561-569. [DOI: https://dx.doi.org/10.1016/j.biopha.2018.01.109]

127. Liu, Y.; Guan, X.; Wang, M.; Wang, N.; Chen, Y.; Li, B.; Xu, Z.; Fu, F.; Du, C.; Zheng, Z. Disulfiram/Copper induces antitumor activity against gastric cancer via the ROS/MAPK and NPL4 pathways. Bioengineered; 2022; 13, pp. 6579-6589. [DOI: https://dx.doi.org/10.1080/21655979.2022.2038434]

128. Iljin, K.; Ketola, K.; Vainio, P.; Halonen, P.; Kohonen, P.; Fey, V.; Grafström, R.C.; Perälä, M.; Kallioniemi, O. High-throughput cell-based screening of 4910 known drugs and drug-like small molecules identifies disulfiram as an inhibitor of prostate cancer cell growth. Clin. Cancer Res. Off. J. Am. Assoc. Cancer Res.; 2009; 15, pp. 6070-6078. [DOI: https://dx.doi.org/10.1158/1078-0432.CCR-09-1035]

129. Chen, D.; Cui, Q.C.; Yang, H.; Dou, Q.P. Disulfiram, a clinically used anti-alcoholism drug and copper-binding agent, induces apoptotic cell death in breast cancer cultures and xenografts via inhibition of the proteasome activity. Cancer Res.; 2006; 66, pp. 10425-10433. [DOI: https://dx.doi.org/10.1158/0008-5472.CAN-06-2126]

130. Zha, J.; Chen, F.; Dong, H.; Shi, P.; Yao, Y.; Zhang, Y.; Li, R.; Wang, S.; Li, P.; Wang, W. et al. Disulfiram targeting lymphoid malignant cell lines via ROS-JNK activation as well as Nrf2 and NF-kB pathway inhibition. J. Transl. Med.; 2014; 12, 163. [DOI: https://dx.doi.org/10.1186/1479-5876-12-163]

131. Zhang, X.; Frezza, M.; Milacic, V.; Ronconi, L.; Fan, Y.; Bi, C.; Fregona, D.; Dou, Q.P. Inhibition of tumor proteasome activity by gold-dithiocarbamato complexes via both redox-dependent and -independent processes. J. Cell. Biochem.; 2010; 109, pp. 162-172. [DOI: https://dx.doi.org/10.1002/jcb.22394] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/19911377]

132. Juarez, J.C.; Betancourt, O.; Pirie-Shepherd, S.R.; Guan, X.; Price, M.L.; Shaw, D.E.; Mazar, A.P.; Doñate, F. Copper Binding by Tetrathiomolybdate Attenuates Angiogenesis and Tumor Cell Proliferation through the Inhibition of Superoxide Dismutase 1. Clin. Cancer Res.; 2006; 12, pp. 4974-4982. [DOI: https://dx.doi.org/10.1158/1078-0432.CCR-06-0171] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/16914587]

133. Li, Y.; Fang, M.; Xu, Z.; Li, X. Tetrathiomolybdate as an old drug in a new use: As a chemotherapeutic sensitizer for non-small cell lung cancer. J. Inorg. Biochem.; 2022; 233, 111865. [DOI: https://dx.doi.org/10.1016/j.jinorgbio.2022.111865] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35623139]

134. Ryumon, S.; Okui, T.; Kunisada, Y.; Kishimoto, K.; Shimo, T.; Hasegawa, K.; Ibaragi, S.; Akiyama, K.; Thu Ha, N.; Monsur Hassan, N. et al. Ammonium tetrathiomolybdate enhances the antitumor effect of cisplatin via the suppression of ATPase copper transporting beta in head and neck squamous cell carcinoma. Oncol. Rep.; 2019; 42, pp. 2611-2621. [DOI: https://dx.doi.org/10.3892/or.2019.7367] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31638244]

135. Prieto-Bermejo, R.; Romo-González, M.; Pérez-Fernández, A.; Ijurko, C.; Hernández-Hernández, Á. Reactive oxygen species in haematopoiesis: Leukaemic cells take a walk on the wild side. J. Exp. Clin. Cancer Res.; 2018; 37, 125. [DOI: https://dx.doi.org/10.1186/s13046-018-0797-0]

136. Visagie, M.H.; Joubert, A.M. In vitro effects of 2-methoxyestradiol-bis-sulphamate on reactive oxygen species and possible apoptosis induction in a breast adenocarcinoma cell line. Cancer Cell Int.; 2011; 11, 43. [DOI: https://dx.doi.org/10.1186/1475-2867-11-43]

137. Zhang, Q.; Ma, Y.; Cheng, Y.-F.; Li, W.-J.; Zhang, Z.; Chen, S. Involvement of reactive oxygen species in 2-methoxyestradiol-induced apoptosis in human neuroblastoma cells. Cancer Lett.; 2011; 313, pp. 201-210. [DOI: https://dx.doi.org/10.1016/j.canlet.2011.09.005]

138. Gorska, M.; Kuban-Jankowska, A.; Zmijewski, M.; Gammazza, A.M.; Cappello, F.; Wnuk, M.; Gorzynik, M.; Rzeszutek, I.; Daca, A.; Lewinska, A. et al. DNA strand breaks induced by nuclear hijacking of neuronal NOS as an anti-cancer effect of 2-methoxyestradiol. Oncotarget; 2015; 6, pp. 15449-15463. [DOI: https://dx.doi.org/10.18632/oncotarget.3913]

139. Bastian, P.E.; Daca, A.; Płoska, A.; Kuban-Jankowska, A.; Kalinowski, L.; Gorska-Ponikowska, M. 2-Methoxyestradiol Damages DNA in Glioblastoma Cells by Regulating nNOS and Heat Shock Proteins. Antioxidants; 2022; 11, 2013. [DOI: https://dx.doi.org/10.3390/antiox11102013]

140. Visagie, M.H.; van den Bout, I.; Joubert, A.M. A bis-sulphamoylated estradiol derivative induces ROS-dependent cell cycle abnormalities and subsequent apoptosis. PLoS ONE; 2017; 12, e0176006. [DOI: https://dx.doi.org/10.1371/journal.pone.0176006]

141. Lebelo, M.T.; Joubert, A.M.; Visagie, M.H. Sulphamoylated Estradiol Analogue Induces Reactive Oxygen Species Generation to Exert Its Antiproliferative Activity in Breast Cancer Cell Lines. Molecules; 2020; 25, 4337. [DOI: https://dx.doi.org/10.3390/molecules25184337]

142. Borahay, M.A.; Vincent, K.L.; Motamedi, M.; Tekedereli, I.; Salama, S.A.; Ozpolat, B.; Kilic, G.S. Liposomal 2-Methoxyestradiol Nanoparticles for Treatment of Uterine Leiomyoma in a Patient-Derived Xenograft Mouse Model. Reprod. Sci.; 2021; 28, pp. 271-277. [DOI: https://dx.doi.org/10.1007/s43032-020-00248-w]

143. Al-Qahtani, S.D.; Bin-Melaih, H.H.; Atiya, E.M.; Fahmy, U.A.; Binmahfouz, L.S.; Neamatallah, T.; Al-Abbasi, F.A.; Abdel-Naim, A.B. Self-Nanoemulsifying Drug Delivery System of 2-Methoxyestradiol Exhibits Enhanced Anti-Proliferative and Pro-Apoptotic Activities in MCF-7 Breast Cancer Cells. Life; 2022; 12, 1369. [DOI: https://dx.doi.org/10.3390/life12091369]

144. Tomeh, M.; Hadianamrei, R.; Zhao, X. A Review of Curcumin and Its Derivatives as Anticancer Agents. Int. J. Mol. Sci.; 2019; 20, 1033. [DOI: https://dx.doi.org/10.3390/ijms20051033]

145. Sánchez, Y.; Simón, G.P.; Calviño, E.; de Blas, E.; Aller, P. Curcumin Stimulates Reactive Oxygen Species Production and Potentiates Apoptosis Induction by the Antitumor Drugs Arsenic Trioxide and Lonidamine in Human Myeloid Leukemia Cell Lines. J. Pharmacol. Exp. Ther.; 2010; 335, pp. 114-123. [DOI: https://dx.doi.org/10.1124/jpet.110.168344]

146. Larasati, Y.A.; Yoneda-Kato, N.; Nakamae, I.; Yokoyama, T.; Meiyanto, E.; Kato, J. Curcumin targets multiple enzymes involved in the ROS metabolic pathway to suppress tumor cell growth. Sci. Rep.; 2018; 8, 2039. [DOI: https://dx.doi.org/10.1038/s41598-018-20179-6]

147. Chen, M.; Zhou, B.; Zhong, P.; Rajamanickam, V.; Dai, X.; Karvannan, K.; Zhou, H.; Zhang, X.; Liang, G. Increased Intracellular Reactive Oxygen Species Mediates the Anti-Cancer Effects of WZ35 via Activating Mitochondrial Apoptosis Pathway in Prostate Cancer Cells: Targeting ROS Induces Cancer Cell Death. Prostate; 2017; 77, pp. 489-504. [DOI: https://dx.doi.org/10.1002/pros.23287]

148. Zhang, X.; Chen, M.; Zou, P.; Kanchana, K.; Weng, Q.; Chen, W.; Zhong, P.; Ji, J.; Zhou, H.; He, L. et al. Curcumin analog WZ35 induced cell death via ROS-dependent ER stress and G2/M cell cycle arrest in human prostate cancer cells. BMC Cancer; 2015; 15, 866. [DOI: https://dx.doi.org/10.1186/s12885-015-1851-3]

149. Gabr, S.A.; Elsaed, W.M.; Eladl, M.A.; El-Sherbiny, M.; Ebrahim, H.A.; Asseri, S.M.; Eltahir, Y.A.M.; Elsherbiny, N.; Eldesoqui, M. Curcumin Modulates Oxidative Stress, Fibrosis, and Apoptosis in Drug-Resistant Cancer Cell Lines. Life; 2022; 12, 1427. [DOI: https://dx.doi.org/10.3390/life12091427]

150. Wang, H.; Xu, Y.; Sun, J.; Sui, Z. The Novel Curcumin Derivative 1g Induces Mitochondrial and ER-Stress-Dependent Apoptosis in Colon Cancer Cells by Induction of ROS Production. Front. Oncol.; 2021; 11, 644197. [DOI: https://dx.doi.org/10.3389/fonc.2021.644197]

151. Zou, P.; Zhang, J.; Xia, Y.; Kanchana, K.; Guo, G.; Chen, W.; Huang, Y.; Wang, Z.; Yang, S.; Liang, G. ROS generation mediates the anti-cancer effects of WZ35 via activating JNK and ER stress apoptotic pathways in gastric cancer. Oncotarget; 2015; 6, pp. 5860-5876. [DOI: https://dx.doi.org/10.18632/oncotarget.3333] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25714022]

152. Lin, X.; Wang, L.; Zhao, L.; Zhu, Z.; Chen, T.; Chen, S.; Tao, Y.; Zeng, T.; Zhong, Y.; Sun, H. et al. Curcumin micelles suppress gastric tumor cell growth by upregulating ROS generation, disrupting redox equilibrium and affecting mitochondrial bioenergetics. Food Funct.; 2020; 11, pp. 4146-4159. [DOI: https://dx.doi.org/10.1039/D0FO00260G] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32347864]

153. Yang, S.-T.; Huang, A.-C.; Tang, N.-Y.; Liu, H.-C.; Liao, C.-L.; Ji, B.-C.; Chou, Y.-C.; Yang, M.-D.; Lu, H.-F.; Chung, J.-G. Bisdemethoxycurcumin-induced S phase arrest through the inhibition of cyclin A and E and induction of apoptosis via endoplasmic reticulum stress and mitochondria-dependent pathways in human lung cancer NCI H460 cells: Bisdemethoxycurcumin-induced apoptosis in nci-h460 cells. Environ. Toxicol.; 2016; 31, pp. 1899-1908. [DOI: https://dx.doi.org/10.1002/tox.22191] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/26370218]

154. Luo, S.-M.; Wu, Y.-P.; Huang, L.-C.; Huang, S.-M.; Hueng, D.-Y. The Anti-Cancer Effect of Four Curcumin Analogues on Human Glioma Cells. OncoTargets Ther.; 2021; 14, pp. 4345-4359. [DOI: https://dx.doi.org/10.2147/OTT.S313961]

155. Chen, M.; Qian, C.; Jin, B.; Hu, C.; Zhang, L.; Wang, M.; Zhou, B.; Zuo, W.; Huang, L.; Wang, Y. Curcumin analog WZ26 induces ROS and cell death via inhibition of STAT3 in cholangiocarcinoma. Cancer Biol. Ther.; 2023; 24, 2162807. [DOI: https://dx.doi.org/10.1080/15384047.2022.2162807]

156. Perrone, D.; Ardito, F.; Giannatempo, G.; Dioguardi, M.; Troiano, G.; Lo Russo, L.; De Lillo, A.; Laino, L.; Lo Muzio, L. Biological and therapeutic activities, and anticancer properties of curcumin. Exp. Ther. Med.; 2015; 10, pp. 1615-1623. [DOI: https://dx.doi.org/10.3892/etm.2015.2749]

157. Gallego-Jara, J.; Lozano-Terol, G.; Sola-Martínez, R.A.; Cánovas-Díaz, M.; De Diego Puente, T. A Compressive Review about Taxol^®: History and Future Challenges. Molecules; 2020; 25, 5986. [DOI: https://dx.doi.org/10.3390/molecules25245986]

158. Li, M.; Yin, L.; Wu, L.; Zhu, Y.; Wang, X. Paclitaxel inhibits proliferation and promotes apoptosis through regulation ROS and endoplasmic reticulum stress in osteosarcoma cell. Mol. Cell. Toxicol.; 2020; 16, pp. 377-384. [DOI: https://dx.doi.org/10.1007/s13273-020-00093-7]

159. Zhang, Y.; Tang, Y.; Tang, X.; Wang, Y.; Zhang, Z.; Yang, H. Paclitaxel Induces the Apoptosis of Prostate Cancer Cells via ROS-Mediated HIF-1α Expression. Molecules; 2022; 27, 7183. [DOI: https://dx.doi.org/10.3390/molecules27217183]

160. Mohiuddin, M.; Kasahara, K. Paclitaxel Impedes EGFR-mutated PC9 Cell Growth via Reactive Oxygen Species-mediated DNA Damage and EGFR/PI3K/AKT/mTOR Signaling Pathway Suppression. Cancer Genom. Proteom.; 2021; 18, pp. 645-659. [DOI: https://dx.doi.org/10.21873/cgp.20287]

161. Hao, X.; Bu, W.; Lv, G.; Xu, L.; Hou, D.; Wang, J.; Liu, X.; Yang, T.; Zhang, X.; Liu, Q. et al. Disrupted mitochondrial homeostasis coupled with mitotic arrest generates antineoplastic oxidative stress. Oncogene; 2022; 41, pp. 427-443. [DOI: https://dx.doi.org/10.1038/s41388-021-02105-9]

162. Kim, S.J.; Kim, H.S.; Seo, Y.R. Understanding of ROS-Inducing Strategy in Anticancer Therapy. Oxid. Med. Cell. Longev.; 2019; 2019, 5381692. [DOI: https://dx.doi.org/10.1155/2019/5381692]

163. Mirzaei, S.; Hushmandi, K.; Zabolian, A.; Saleki, H.; Torabi, S.M.R.; Ranjbar, A.; SeyedSaleh, S.; Sharifzadeh, S.O.; Khan, H.; Ashrafizadeh, M. et al. Elucidating Role of Reactive Oxygen Species (ROS) in Cisplatin Chemotherapy: A Focus on Molecular Pathways and Possible Therapeutic Strategies. Molecules; 2021; 26, 2382. [DOI: https://dx.doi.org/10.3390/molecules26082382]

164. Marullo, R.; Werner, E.; Degtyareva, N.; Moore, B.; Altavilla, G.; Ramalingam, S.S.; Doetsch, P.W. Cisplatin Induces a Mitochondrial-ROS Response That Contributes to Cytotoxicity Depending on Mitochondrial Redox Status and Bioenergetic Functions. PLoS ONE; 2013; 8, e81162. [DOI: https://dx.doi.org/10.1371/journal.pone.0081162]

165. Choi, Y.-M.; Kim, H.-K.; Shim, W.; Anwar, M.A.; Kwon, J.-W.; Kwon, H.-K.; Kim, H.J.; Jeong, H.; Kim, H.M.; Hwang, D. et al. Mechanism of Cisplatin-Induced Cytotoxicity Is Correlated to Impaired Metabolism Due to Mitochondrial ROS Generation. PLoS ONE; 2015; 10, e0135083. [DOI: https://dx.doi.org/10.1371/journal.pone.0135083]

166. Kleih, M.; Böpple, K.; Dong, M.; Gaißler, A.; Heine, S.; Olayioye, M.A.; Aulitzky, W.E.; Essmann, F. Direct impact of cisplatin on mitochondria induces ROS production that dictates cell fate of ovarian cancer cells. Cell Death Dis.; 2019; 10, 851. [DOI: https://dx.doi.org/10.1038/s41419-019-2081-4]

167. Magnano, S.; Hannon Barroeta, P.; Duffy, R.; O’Sullivan, J.; Zisterer, D.M. Cisplatin induces autophagy-associated apoptosis in human oral squamous cell carcinoma (OSCC) mediated in part through reactive oxygen species. Toxicol. Appl. Pharmacol.; 2021; 427, 115646. [DOI: https://dx.doi.org/10.1016/j.taap.2021.115646]

168. Yu, W.; Chen, Y.; Dubrulle, J.; Stossi, F.; Putluri, V.; Sreekumar, A.; Putluri, N.; Baluya, D.; Lai, S.Y.; Sandulache, V.C. Cisplatin generates oxidative stress which is accompanied by rapid shifts in central carbon metabolism. Sci. Rep.; 2018; 8, 4306. [DOI: https://dx.doi.org/10.1038/s41598-018-22640-y]

169. Sritharan, S.; Sivalingam, N. A comprehensive review on time-tested anticancer drug doxorubicin. Life Sci.; 2021; 278, 119527. [DOI: https://dx.doi.org/10.1016/j.lfs.2021.119527]

170. Thorn, C.F.; Oshiro, C.; Marsh, S.; Hernandez-Boussard, T.; McLeod, H.; Klein, T.E.; Altman, R.B. Doxorubicin pathways: Pharmacodynamics and adverse effects. Pharmacogenet. Genom.; 2011; 21, pp. 440-446. [DOI: https://dx.doi.org/10.1097/FPC.0b013e32833ffb56]

171. Filippova, M.; Filippov, V.; Williams, V.M.; Zhang, K.; Kokoza, A.; Bashkirova, S.; Duerksen-Hughes, P. Cellular Levels of Oxidative Stress Affect the Response of Cervical Cancer Cells to Chemotherapeutic Agents. BioMed Res. Int.; 2014; 2014, 574659. [DOI: https://dx.doi.org/10.1155/2014/574659] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25478571]

172. Tsang, W.P.; Chau, S.P.Y.; Kong, S.K.; Fung, K.P.; Kwok, T.T. Reactive oxygen species mediate doxorubicin induced p53-independent apoptosis. Life Sci.; 2003; 73, pp. 2047-2058. [DOI: https://dx.doi.org/10.1016/S0024-3205(03)00566-6] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/12899928]

173. Shafei, A.; El-Bakly, W.; Sobhy, A.; Wagdy, O.; Reda, A.; Aboelenin, O.; Marzouk, A.; El Habak, K.; Mostafa, R.; Ali, M.A. et al. A review on the efficacy and toxicity of different doxorubicin nanoparticles for targeted therapy in metastatic breast cancer. Biomed. Pharmacother.; 2017; 95, pp. 1209-1218. [DOI: https://dx.doi.org/10.1016/j.biopha.2017.09.059] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28931213]

174. Nguyen, M.P.; Pham, D.P.; Kim, D. Oxidative Stress-Induced Silver Nano-Carriers for Chemotherapy. Pharmaceuticals; 2022; 15, 1449. [DOI: https://dx.doi.org/10.3390/ph15121449]

175. Hernandes, E.P.; Lazarin-Bidóia, D.; Bini, R.D.; Nakamura, C.V.; Cótica, L.F.; de Oliveira Silva Lautenschlager, S. Doxorubicin-Loaded Iron Oxide Nanoparticles Induce Oxidative Stress and Cell Cycle Arrest in Breast Cancer Cells. Antioxidants; 2023; 12, 237. [DOI: https://dx.doi.org/10.3390/antiox12020237]

176. Zheng, G.; Zheng, M.; Yang, B.; Fu, H.; Li, Y. Improving breast cancer therapy using doxorubicin loaded solid lipid nanoparticles: Synthesis of a novel arginine-glycine-aspartic tripeptide conjugated, pH sensitive lipid and evaluation of the nanomedicine in vitro and in vivo. Biomed. Pharmacother.; 2019; 116, 109006. [DOI: https://dx.doi.org/10.1016/j.biopha.2019.109006]

177. Xu, J.; Su, X.; Burley, S.K.; Zheng, X.F.S. Nuclear SOD1 in Growth Control, Oxidative Stress Response, Amyotrophic Lateral Sclerosis, and Cancer. Antioxidants; 2022; 11, 427. [DOI: https://dx.doi.org/10.3390/antiox11020427]

178. Hu, Y.; Lin, Q.; Zhao, H.; Li, X.; Sang, S.; McClements, D.J.; Long, J.; Jin, Z.; Wang, J.; Qiu, C. Bioaccessibility and bioavailability of phytochemicals: Influencing factors, improvements, and evaluations. Food Hydrocoll.; 2023; 135, 108165. [DOI: https://dx.doi.org/10.1016/j.foodhyd.2022.108165]

179. Cheng, Z.; Li, M.; Dey, R.; Chen, Y. Nanomaterials for cancer therapy: Current progress and perspectives. J. Hematol. Oncol.; 2021; 14, 85. [DOI: https://dx.doi.org/10.1186/s13045-021-01096-0]

180. Luo, M.; Zhou, L.; Huang, Z.; Li, B.; Nice, E.C.; Xu, J.; Huang, C. Antioxidant Therapy in Cancer: Rationale and Progress. Antioxidants; 2022; 11, 1128. [DOI: https://dx.doi.org/10.3390/antiox11061128]