Reactive oxygen species (ROS) are short-lived, highly electrophilic molecules. They are produced from secondary metabolites generated by a partial reduction of oxygen (1). When intracellular antioxidants are reduced or ROS accumulate excessively, an imbalance in the redox state occurs, which is referred to as oxidative stress. Under such conditions, excessive intracellular accumulation of ROS modifies redox-sensitive amino acid residues in regulatory proteins and alters the actions of proteins and enzymes. Protein kinases, transcription factors and the ubiquitin-proteasome system are vulnerable to excessive accumulation of ROS (2). Of note, when this occurs in tumor cells, it promotes tumor development. Stimulation of signaling pathways by ROS promotes the proliferation, migration and invasion of tumor cells, including in human breast, skin and liver cancers (3). Furthermore, oxidative stress caused by excessive accumulation of ROS can lead to genetic instability. Cell death modalities, such as apoptosis, autophagy, ferroptosis and pyroptosis, act as protective mechanisms to prevent the proliferation of damaged cells (4) and this is also seen in tumor cells. Thus, ROS effects are complex in tumor cells (5,6). Specifically, tumor cells maintain moderate-to-high ROS levels, namely, above the low cytostatic level and below the cytotoxic level, by enhancing their own antioxidant capacity. Therefore, the ROS level in tumor cells is subtoxic, which facilitates tumor cell progression, and ROS act as signaling molecules to increase the proliferation of tumor cells (7–10). However, under further oxidative stress, cancer cells are equally susceptible to excessive ROS (11), and increased ROS unbalance the redox response of cancer cells, ultimately leading to cellular senescence or death (12).

Curcumin is a plant polyphenol in the rhizome of turmeric and was classified as a third-generation cancer chemopreventive agent by the National Cancer Institute (13). Several studies have reported anticancer mechanisms mediated by curcumin through the induction of elevated ROS (14,15). This contradicts the antioxidant properties of curcumin, the potential reasons for which are discussed in the present review. Unfortunately, properties such as poor water solubility and low bioavailability limit the clinical application of curcumin (13). However, the clinical efficacy of curcumin has been enhanced by combining it with drugs, the introduction of nanocarriers and the development of curcumin derivatives, which have brought the clinical application of curcumin closer to reality (16–18). Therefore, the present study reviewed articles in which the effect of curcumin on tumors was evaluated, with a particular focus on its relationship with oxidative stress, to provide a reference for future studies.

Curcumin, also known as diferuloylmethane, has the chemical formula C₂₁H₂₀O₆, a molecular weight of 368.38 g/mol and a symmetrical molecular structure (19). Curcumin has been commonly used as an aromatic and natural food coloring agent; however, its biological effects are gradually being elucidated. Curcumin has anti-inflammatory, antibacterial, hepatoprotective and anticancer properties (20–22), and its anticancer effects have been reported in several tumor types (Table I). In melanoma, curcumin has been reported to increase the ROS level and activate oxidative stress in the cysteine asparaginase pathway, which causes tumor cell death (23). Lysosome-associated membrane protein 3 belongs to the fourth transmembrane protein superfamily, which promotes tumor cell invasion and metastasis. It interacts with ubiquitin-specific peptidase 4 and is positively regulated by the latter. A recent study reported that curcumin downregulated ubiquitin-specific peptidase 4 to modulate lysosome-associated membrane protein 3, and thus inhibited the malignant progression of colorectal cancer cells (24). Furthermore, curcumin-induced accumulation of ROS in tumors to kill tumor cells has been noted in several studies (25,26), as discussed in the present review.

Curcumin is well tolerated by humans. For example, a study that evaluated the toxicity of curcumin in humans reported that subjects administered 8 mg/day curcumin (99.3% purity) did not develop toxicity (27). However, certain physical and chemical properties of curcumin limit its clinical application. For example, whilst its high lipophilicity assists in penetrating lipid structures, it is insoluble in water and has poor stability, resulting in low bioavailability (13). In a previous study, 440–2,200 mg curcumin extract was administered to patients with advanced colorectal cancer for 29 consecutive days, and curcumin was not detected in patient blood or urine. In several clinical trials, ≤12 g/day curcumin was administered orally, but the amount of curcumin detected in serum was <1% (27,28). To overcome these drawbacks, the use of curcumin in combination with other drugs to enhance its anticancer activity has been reported (29). In addition, the development of curcumin derivatives, the use of carriers or coverings such as chitosan, and nanosystems have been suggested to improve the bioavailability of curcumin (30). Thus, the potential for the clinical application of curcumin is increasing.

Curcumin is a pigment with a diketone structure. Curcumin-induced ROS is crucial for cancer cell death. In addition, curcumin mediates chemosensitization. However, its low solubility and poor stability limit its clinical application. To increase curcumin use, the combination of curcumin and drugs has been reported to sensitize drug-resistant cancer cells and enhance therapeutic effects (Table II) (70).

Polyphenols, such as curcumin, are a large family of organic compounds that contain a common ternary flavonoid ring system structure and polyphenolic units (70). These natural compounds are mainly found in plants and are beneficial to humans. For instance, certain polyphenols have been used to treat tumors, such as in one study where the treatment of breast cancer cells with resveratrol resulted in differential expression of several genes related to the cell cycle and induced S-phase arrest (71). Curcumin has also been reported to mediate the arrest of tumor cells in G2/M phase via p53 (17). However, polyphenols are also associated with negative outcomes, such as drug resistance induction. Nevertheless, studies have reported that combinations of certain polyphenols improved therapeutic effects on tumors, and both curcumin and resveratrol reduced cancer cell survival by upregulating ROS. Furthermore, the combination of curcumin and resveratrol notably increased ROS production compared with either agent alone (16,72). Furthermore, NAC treatment significantly reversed apoptosis induced by the combination of curcumin and resveratrol, and the expression of caspase-3, −8, and −9 was also reduced. These findings suggest that combination therapy with curcumin and resveratrol may induce apoptosis by activating caspases and ROS production. In addition, the combination of curcumin and resveratrol was reported to have activated ER stress, enhanced the activity of the protein kinase RNA-like ER kinase/eukaryotic initiation factor-2α/CHOP axis and induced apoptosis (73). The combination of the two increased poly (ADP-ribose) polymerase expression inhibited DNA damage, promoted apoptosis and reduced drug resistance in bladder cancer cells (74).

Paclitaxel (PTX), which is widely used for the treatment of lung cancer, induces cell death by disrupting the normal microtubule dynamics required for cell division and important interphase processes. In addition, PTX induces cell cycle arrest (75). However, PTX also has several toxic effects on normal cells, such as the induction of neurotoxicity and hematotoxicity (76). By measuring the amount of ROS produced when the lung cancer A549 and Calu-3 cell lines were co-treated with curcumin and PTX using a fluorescent probe, a study reported that the combination resulted in higher levels of ROS and showed stronger anticancer effects, such as the inhibition of cell proliferation, as well as induction of apoptosis and cell cycle arrest, compared with curcumin or PTX treatment alone (77). Of note, in the aforementioned study, curcumin also attenuated the toxic effects of PTX on normal cells. For instance, when the curcumin dose was higher, the combination was less cytotoxic to the normal lung Beas-2B cell line compared with the higher PTX dose group. This may indicate that curcumin cannot be internalized by normal cells (78,79) and therefore cannot induce the production of superoxide compounds or be toxic to normal cells. However, in tumor cells, curcumin has been reported to be internalized and induced the production of superoxide compounds (80), which, in conjunction with PTX, enhanced oxidative stress in tumor cells. In addition, as an antioxidant, curcumin in turn attenuated the oxidative stress caused by PTX in normal cells via several mechanisms, such as increasing the expression of glutathione and antioxidant proteins (81,82). Therefore, the combination of curcumin and PTX may enhance anticancer activity in cancer cells whilst protecting healthy cells from irreversible damage.

P-glycoprotein (P-gp) is the pump responsible for drug efflux and its high expression is associated with drug resistance in tumors (83). Attia et al (84) reported that combining curcumin and PTX reduced the activity and expression of P-gp and multidrug resistance 1 and increased PTX sensitivity in breast cancer. Furthermore, curcumin downregulated NF-κB, which increased the sensitivity of gastric cancer cells to PTX (85). Doxorubicin (Dox) is commonly used to treat malignant tumors (86–88). However, developing P-gp-mediated multidrug resistance during tumor chemotherapy severely reduces the therapeutic efficacy of Dox. Curcumin has been reported to have inhibited D-glutamine metabolism by decreasing the expression of ornithine decarboxylase. It also markedly inhibited the biosynthesis of spermine and spermidine, thereby reducing the oxidative stress capacity of SW620/AD300 cells and the ATP-dependent transport activity of P-gp. This increased the intracellular accumulation of Dox in drug-resistant cells and ultimately reversed the multidrug resistance of tumors (89). Finally, deguelin is a fish-like pigment in an African rhizome plant, which is used as an insecticide. Deguelin inhibits sperm function via the PI3K/AKT signaling pathway (90) and serves a role in cancer inhibition (91). For instance, deguelin has been reported to kill prostate cancer cells (92). Kocdor et al (93) reported that curcumin and deguelin were able to reduce the oxidative stress index and enhance the activity of superoxide dismutase.

In addition to its use in combination with drugs, derivatives of curcumin are being developed to improve its pharmacological effects (Fig. 2). A study synthesized niacin (an essential vitamin necessary for normal cell function) with curcumin to produce a new curcumin derivative called nicotinic acid (17), which has greater selectivity for cancer cells than curcumin itself. As the curcumin derivative had an improved pharmacokinetic profile in vivo, it more strongly stimulated oxidative stress. Furthermore, β-diketones may be responsible for the instability and weak pharmacokinetic profile of curcumin in vitro. In a study, its β-diketone structure was deleted and a new curcumin derivative, WZ35, was constructed, which exhibited markedly improved chemical stability in vitro (94). In a follow-up study, WZ35 induced apoptosis in gastric cancer cells by increasing the ROS level, thereby causing ER stress and activating the JNK signaling pathway (95). Furthermore, WZ35 caused cell death in hepatocellular carcinoma and breast cancer cells via a similar mechanism (96,97). ST03, a recently synthesized curcumin derivative (98,99), has been reported to have improved bioavailability and stability, and to be detectable in plasma for up to 12 h. In a previous study, ST03 induced a peak in ROS within 1 h and a reduction in the transcription of mitochondrion DNA-encoded respiratory chain-associated protein genes after 48 h, which ultimately led to ovarian cancer cell death (99). A recent study synthesized novel mitochondrion-targeted curcumin derivatives by unilateral coupling of the curcumin phenolic hydroxyl group to triphenylphosphine through an ester bond or bilateral coupling (CUR-2T) (38). CUR-2T demonstrated a clear preferential selectivity for cancer cells and directly targeted mitochondria, resulting in disruption of the redox balance accompanied by increased ROS levels, decreased ATP levels and tumor cell cycle arrest.

The introduction of nanocarriers and loaders has greatly enhanced the loading and targeting ability of curcumin. A study constructed metal-organic frameworks (MOFs) modified with glucose oxidase (GOx). After loading with curcumin, it is further modified with tumor-targeting hyaluronic acid (HA) to obtain Cur@MOF-GOx/HA nano-enzymes. Exposure to GOx triggered tumor starvation and produced H₂O₂ to provide reactants for the MOF-mediated Fenton reaction to produce large amounts of ROS, whilst releasing curcumin to induce the autophagic death of tumor cells (18). In another study, a nanocomposite hydrogel platform for montmorillonite nanoparticles added to chitosan-agarose was constructed, increasing the loading capacity of curcumin from 63 to 76% and increasing the apoptotic rate. The delivery platform in the present study enhanced the curcumin load, sustained its release and increased its anticancer effects (100). In another study, magnetic nanoparticles containing curcumin with carboxymethyl chitosan (MNP-CMC-CUR) were designed and used to treat breast cancer MCF-7 and MDA-MB-231 cell lines and human fibroblasts, and their effect was compared to that of curcumin alone in MTT assays (101). It was observed that the IC₅₀ of MCF-7 cells treated with MNP-CMC-CUR was notably reduced compared with that of curcumin itself without affecting the metabolic activity of normal cells. Furthermore, p53 and caspase-3 gene expression was markedly increased in MCF-7 cells treated with MNP-CMC-CUR. A study reported the cessation of G1-stage cancer cell growth after hyperthermia, as well as an increase in caspase-3 expression and ROS production. Furthermore, MNP-CMC-CUR improved drug effectiveness, and when combined with hyperthermia, the therapeutic effect was enhanced (102).

Mesoporous silica nanoparticles (MSNs) are a class of nanoparticles extensively studied for drug delivery applications. Curcumin and naphthoquinone (NQ) are novel therapeutic diagnostic molecules for cancer targeting, detection and treatment (103). A novel nanosystem has been developed using MSN_CurNQ that increases drug delivery of CurNQ by increasing the enhanced permeability and retention effect and sustained release (104). A study demonstrated that MSN_CurNQ treatment did not elicit any cytotoxicity in the fibroblast 3T3 cell line, but reduced the viability of cancer cells to <50%, indicating tumor-specific toxicity (103). Water- and alcohol-soluble cerium oxide-curcumin conjugates were obtained by co-evaporation with polyN-vinylpyrrolidone (PVP) (105), which induced oxidative stress under ultraviolet (UV) irradiation or hydrogen peroxide conditions. Nanoceramic PVP-curcumin (NPC) conjugates exhibited selective cytotoxicity. Unlike curcumin itself, NPC conjugates demonstrated photosensitivity in tumor cell cultures, whilst protecting untransformed cultures from the damaging effects of UV radiation and oxidative stress.

Curcumin combined with MOFs, nanocomposite hydrogel platforms, nanoparticles and nanosystems may enhance the sustained release of curcumin via several mechanisms of action to improve its targeting and release curve, increase the solubility of curcumin and toxicity in tumor cells, improve bioavailability and increase its anticancer effects.

Cancer is a significant health issue, and although early diagnosis and targeted therapy have markedly reduced mortality, cancer drug resistance and drug side effects are still clinical problems that need to be resolved (106). Curcumin is a natural compound that has been used for the treatment of numerous types of diseases, such as Alzheimer's disease, fatty liver and cancer (53,107,108). Of note, curcumin has a dual role in oncological and non-oncologic diseases. Specifically, in non-neoplastic diseases, curcumin is a potent antioxidant that attenuates oxidative stress and mitochondrial damage (35). Conversely, in tumors, curcumin binds to several enzymes and increases ROS levels (23,24). These different effects may be the result of differences in dosage. For instance, in a previous study on curcumin treatment of drug-resistant tumor cells, a low dose of curcumin showed no effect on antioxidant proteins, whereas a high dose resulted in the inhibition of antioxidant proteins, thereby increasing ROS levels (25,109–112). Furthermore, mitochondria may be a potential target for high-dose curcumin. During tumorigenesis, mitochondria are often functionally and morphologically impaired, leading to aberrant changes in ROS levels, and high-dose curcumin treatment has been reported to exacerbate the effects on damaged mitochondria (42,113). In addition, compared with normal cells, proteins abnormally expressed in tumor cells, such as GSH and HO-1, may be targeted by curcumin to cause oxidative stress in tumor cells. The reasons for the dual action of curcumin need to be further explored.

Curcumin induces high levels of ROS accumulation, leading to an imbalance in the redox response. This results in mitochondrial and DNA damage and subsequent activation of the cell death pathway, providing possible approaches for cancer therapy. The MAPK signaling pathway consists of three distinct cascades, ERK, JNK and p38, which serve a role in cell growth, proliferation, motility and death (114); therefore, it may be an important pathway to target using curcumin to induce apoptosis in cancer cells. Curcumin promotes phosphorylation of ERK and JNK and induces ROS production, leading to mitochondrial damage and cytochrome C release, which activates caspase-related signaling pathways to cause apoptosis (115). In addition, it disrupts intracellular calcium homeostasis and activates ER stress, leading to apoptosis (42). Of note, changes in caspase-3 expression have also been reported to induce the production of GSDME-N and the formation of large amounts of pore, which ultimately lead to cell membrane rupture and pyroptosis (66). In terms of autophagy, curcumin has been reported to induce elevated ROS levels and the appearance of autophagy markers and autophagosomes, causing tumor cells to undergo autophagy. Nrf2 is a classical transcription factor that regulates the cellular oxidative stress response, which controls several cellular behaviors, such as cellular detoxification and oxidative stress, and induces the downstream production of a series of cytoprotective proteins to maintain the balance of the intracellular environment and prevent diseases (116). Curcumin achieves anticancer effects by regulating the expression of Nrf2 and its downstream target HO-1, inhibiting the expression of GPX4 and altering the accumulation of intracellular iron and inducing the Fenton reaction (60). In addition, the combination of curcumin with drugs, the introduction of curcumin derivatives and nanocarriers have markedly improved the pharmacokinetics of curcumin and enhanced its effects, including oxidative stress to kill tumor cells.

Over the past two decades, the mechanisms by which curcumin inhibits several types of tumor have been gradually elucidated. In addition, research on curcumin derivatives and nanocarriers has been performed and its clinical therapeutic potential has been evaluated. However, research on curcumin needs to be further deepened in terms of the following aspects: i) Studies have reported that the cytotoxicity of curcumin nanoparticles is notably increased and water-soluble curcumin components demonstrate greater toxicity compared with curcumin itself (117,118). Therefore, the toxicity of nanoparticles and water-soluble curcumin needs to be reduced in the development of these substances; ii) clinical trials of nano-curcumin in tumor patients should be performed; iii) several formulations of curcumin have produced markedly different results in clinical trials. In a study by Sharma et al (119), patients experienced adverse reactions such as diarrhea at a dosage of 3.6 g curcumin, whereas no relevant therapeutic toxicity was observed at 8 g curcumin with 99.3% purity as described above. The difference between the two studies may be due to the different formulations of curcumin. Therefore, several formulations of curcumin should be assessed to reduce its clinical toxicity and enhance its pharmacokinetic effects; iv) the mechanism of action of curcumin in several tumor types should continue to be evaluated, with oxidative stress being the potential predominant mechanism.

In conclusion, curcumin may have the potential to become a cutting-edge drug for the treatment of tumors and other diseases. In-depth research on curcumin should be performed, as well as more clinical trials related to curcumin, to evaluate its anticancer activity.