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Etoposide

Etoposide is a semisynthetic of , a natural toxin extracted from the rhizomes and roots of the American mayapple plant (), and serves as a key chemotherapeutic agent in . Approved by the U.S. (FDA) in 1983, it is primarily indicated for the treatment of refractory testicular tumors and small cell lung cancer, typically administered in combination with other antineoplastic drugs to enhance efficacy. Its development stemmed from efforts in the to modify into less toxic, more targeted anticancer compounds, with etoposide first synthesized around 1963–1966. The drug's mechanism of action centers on its role as a topoisomerase II inhibitor, where it forms a stable ternary complex with the enzyme and DNA, preventing the religation of double-strand DNA breaks during replication and transcription, ultimately leading to apoptosis in rapidly dividing cancer cells. This phase-specific activity predominantly affects cells in the late S and G2 phases of the cell cycle, making it particularly effective against aggressive malignancies. Etoposide is available in intravenous and oral formulations, with typical dosing regimens involving 50–100 mg/m² daily for 5 days or intermittent schedules (e.g., days 1, 3, and 5) every 3–4 weeks, adjusted based on patient tolerance and tumor type. While effective, its use requires careful monitoring due to significant toxicities, including dose-limiting myelosuppression (e.g., leukopenia and thrombocytopenia), gastrointestinal effects like nausea and vomiting, and alopecia; long-term risks encompass secondary leukemias and infertility. Beyond its FDA-approved indications, etoposide has been widely incorporated into regimens for other cancers, such as non-small cell lung cancer, lymphomas, acute leukemias, and , often as part of multi-agent protocols like BEP (, etoposide, ) for tumors. Its pharmacokinetic profile features a of 4–11 hours, hepatic metabolism via , and primarily renal excretion, necessitating dose reductions in patients with organ dysfunction. Ongoing research explores its synergies with targeted therapies and immunotherapies to mitigate resistance and broaden applications in precision oncology.

Medical uses

Indications

Etoposide is approved by the U.S. (FDA) for the first-line treatment of small cell lung cancer (SCLC) in combination with other chemotherapeutic agents, such as platinum-based drugs in the EP regimen (etoposide plus or ). It is also FDA-approved for the treatment of refractory testicular tumors, commonly as part of the BEP regimen (, etoposide, and ) for tumors. These approvals stem from its efficacy in rapidly proliferating cancers, where etoposide inhibits topoisomerase II to prevent in tumor cells. Beyond approved uses, etoposide is frequently employed off-label for (AML), often in salvage regimens like (fludarabine, cytarabine, ) combined with etoposide. It is also commonly used in and , such as in the CEOP regimen (cyclophosphamide, etoposide, vincristine, prednisone), particularly for patients ineligible for . Additional off-label applications include gastric cancer, , , , and other solid tumors exhibiting high II activity. In combination therapies, etoposide integrates with , notably in the trial where plus platinum-etoposide for extensive-stage SCLC demonstrated significant overall survival benefits compared to alone, with updates through 2025 confirming durable responses. First-line response rates for etoposide-platinum regimens in SCLC range from 60% to 80%, establishing its role as a cornerstone despite emerging immunotherapies. As of 2025, etoposide remains a mainstay for SCLC , with phase II and III trials showing good tolerability when combined with inhibitors like in elderly patients and those with untreated brain metastases, including improved survival outcomes in subgroups from the updates and dedicated phase II studies.

Administration

Etoposide is available in several formulations for clinical use, including an solution at a concentration of 20 mg/mL supplied in vials containing 100 mg/5 mL, 500 mg/25 mL, or 1 g/50 mL, oral capsules of 50 mg each, and a formulation (Etopophos) as a lyophilized powder in single-dose vials providing 114 mg etoposide equivalent to 100 mg etoposide. Standard dosing regimens vary by indication; for small cell , the IV dose is typically 35 mg/m² daily for 4 days or 50 mg/m² daily for 5 days, repeated every 3-4 weeks, while for , it is 50-100 mg/m² daily for 5 days or 100 mg/m² on days 1, 3, and 5, often in combination with . Oral dosing for small cell is approximately twice the corresponding dose, rounded to the nearest 50 mg (e.g., 70 mg/m² or 100 mg/m² daily for the respective schedules), adjusted for lower oral absorption. For IV administration, the solution must be diluted in 5% dextrose or 0.9% to a concentration of 0.2-0.4 mg/mL and slowly over 30-60 minutes to minimize the risk of ; rapid or bolus injection should be avoided, with Etopophos allowing over 5 minutes to 3.5 hours after reconstitution. Oral capsules are taken with a glass of on an empty , and with antiemetics is recommended due to the moderate emetogenic potential of oral etoposide. Cycles are repeated every 3-4 weeks once recovery from myelosuppression occurs, with complete blood counts assessed prior to each cycle. Special considerations include dose adjustments for organ impairment; for renal dysfunction, administer 75% of the dose if clearance is 15-50 mL/min and further reduce (e.g., by 50%) if below 15 mL/min, while for hepatic impairment with total greater than 3 mg/dL, a 50% dose reduction is advised. rates should be controlled to prevent reactions, including , and conversion between oral and IV routes follows the approximate doubling of oral doses relative to IV equivalents. During administration, such as should be monitored continuously for signs of , particularly with IV , and blood counts evaluated before each dose to ensure neutrophils exceed 500/mm³ and platelets exceed 50,000/mm³.

Safety profile

Contraindications and precautions

Etoposide is absolutely contraindicated in patients with a history of severe reactions to etoposide, etoposide phosphate, or other derivatives, as such reactions can include , , and requiring immediate discontinuation of therapy. Treatment should not be initiated in patients with severe baseline myelosuppression, defined as an (ANC) below 500 cells/μL or platelet count below 50,000/μL, until hematologic recovery occurs to minimize the risk of life-threatening infections or bleeding. Relative contraindications include active infections or recent receipt of live , given etoposide's profound myelosuppressive effects that increase susceptibility to opportunistic infections and diminish or heighten adverse reactions. Severe renal or hepatic impairment also warrants caution without appropriate dose adjustments, as etoposide clearance is primarily renal and hepatic can be altered, potentially leading to excessive . Several precautions apply to at-risk populations to mitigate toxicity risks. In elderly patients, etoposide carries an increased risk of severe myelosuppression and other toxicities due to age-related declines in organ function and comorbidities; initiating therapy at a reduced dose and careful monitoring are recommended. Patients with exhibit heightened sensitivity to etoposide, necessitating dose reductions in treatment regimens for (AML) to avoid excessive toxicity while maintaining efficacy. Similarly, individuals with face an elevated risk of secondary malignancies, particularly therapy-related AML, from etoposide's topoisomerase II inhibition, compounded by their underlying defects; use requires weighing benefits against this oncogenic potential. No data are available regarding the presence of etoposide in human milk, the effects on the breastfed , or on milk production. Because of the potential for serious adverse reactions in a breastfed , advise women not to breastfeed during treatment with etoposide. In patients with alcohol use disorder, etoposide should be used cautiously due to its potential for , including transient elevations in liver enzymes, which may be exacerbated by concurrent alcohol consumption impairing liver function. Etoposide can cause fetal harm when administered to a pregnant based on findings from animal studies and its . Teratogenic effects have been observed in mice and rats. Advise pregnant women and females of reproductive potential of the potential risk to a . Effective contraception should be used during treatment and for at least 6 months after the final dose for females of reproductive potential and for at least 4 months after for males with partners of reproductive potential. Monitoring is essential prior to and during etoposide therapy. Baseline assessments should include a (CBC) to evaluate for myelosuppression, as well as liver and renal function tests to guide dosing; repeat s are required before each cycle and more frequently if clinically indicated. testing is advised for females of reproductive potential before starting treatment, with effective contraception recommended during therapy and for at least 6 months afterward. Although etoposide is not definitively linked to , caution is advised in patients with (G6PD) deficiency, as certain chemotherapeutic agents can trigger in this population. In special populations, etoposide is commonly incorporated into pediatric regimens for AML, including in children with , but long-term growth monitoring is necessary due to potential impacts from myelosuppression and overall treatment intensity. For geriatric patients, dose reduction to 75% of the standard amount is recommended if creatinine clearance is between 15 and 50 mL/min to prevent accumulation and heightened toxicity.

Adverse effects

Etoposide therapy is associated with a range of adverse effects, primarily due to its cytotoxic mechanism, with myelosuppression being the most common and dose-limiting toxicity. Common adverse effects occur in more than 10% of patients and include myelosuppression manifesting as (incidence 60-91%), (20-50%), and (13-66%), alongside and (20-30%), alopecia (20-30% at standard doses), , and . These effects are generally reversible but can lead to significant clinical complications such as infections and bleeding. Serious adverse effects, though less frequent (under 10% incidence), carry high clinical impact and include secondary (1-5% risk, often characterized by 11q23 chromosomal translocations and a latency period of 1-3 years), hypersensitivity reactions (1-2%, typically during intravenous infusion), (associated with rapid infusion rates), and (elevated ALT/AST in approximately 15% of cases). Hypersensitivity reactions may present as anaphylactic-like symptoms including chills, fever, , bronchospasm, dyspnea, and . The incidence of myelosuppression is dose-dependent, with nadirs typically occurring 10-14 days post-administration and recovery by day 20; risk factors include higher cumulative doses exceeding 2 g/m² or combination with other II inhibitors, which elevate the secondary risk. Elderly patients and those with low or elevated baseline liver enzymes are at increased risk for severe hematological toxicities. Management strategies focus on supportive care and dose adjustments to mitigate risks. (G-CSF) is commonly used to reduce the duration and severity of and associated infections. Dose delays or reductions are recommended if platelet counts fall below 50,000/mm³ or neutrophil counts below 500/mm³; desensitization protocols with (corticosteroids and antihistamines) can allow continuation in cases of . Long-term surveillance for secondary is essential, particularly in patients receiving high cumulative doses. Recent 2025 studies on etoposide in combination with immunotherapies, such as atezolizumab and bevacizumab in small-cell lung cancer, confirm an increased risk of infections due to persistent myelosuppression but report no emergence of novel toxicities beyond the established profile.

Pharmacology

Mechanism of action

Etoposide primarily targets DNA topoisomerase II (topo II), an essential enzyme that relieves torsional stress in DNA by creating transient double-strand breaks during replication and transcription, with activity against both the α and β isoforms. By binding at the interface between topo II and DNA, etoposide stabilizes the normally transient cleavable complex, in which the enzyme is covalently attached to the 5' ends of the broken DNA strands, thereby inhibiting the religation step and resulting in persistent DNA double-strand breaks that overwhelm cellular repair mechanisms and trigger cell death. This process positions etoposide as a topo II poison rather than a catalytic inhibitor, as it exploits the enzyme's normal function to induce damage rather than blocking its activity outright. Etoposide exhibits cell cycle specificity, exerting its effects predominantly in the late S and G2 phases, where topo IIα levels are elevated to support and chromosome segregation, leading to in rapidly proliferating cancer cells while sparing quiescent ones. It demonstrates higher affinity for topo II compared to topoisomerase I, which handles single-strand breaks, allowing selective induction of double-strand damage critical for anticancer efficacy. Active metabolites of etoposide, such as the derivative formed via oxidation, further enhance cytotoxicity by undergoing further oxidation to etoposide , which generates and causes while acting as a covalent topo II poison through adduction to enzyme cysteine residues, thereby amplifying DNA cleavage. Resistance to etoposide can arise through mutations or downregulation of topo II that reduce drug binding or enzyme levels, as well as overexpression of multidrug proteins like ABCB1 that efflux the drug from cells, diminishing intracellular accumulation and therapeutic impact.

Pharmacokinetics

Etoposide exhibits variable oral ranging from 40% to 75%, primarily due to (P-gp) efflux in the intestine and influences from food intake, while intravenous administration achieves 100% immediate systemic availability. Following administration, etoposide is highly bound to proteins (97%, mainly ), with a of 7–17 L/m²; it crosses the blood-brain barrier poorly but achieves adequate concentrations in tumor tissues. Metabolism occurs primarily in the liver via and , involving O-demethylation to form the etoposide (which can oxidize to a semi-quinone intermediate, potentially more toxic) and other pathways like and sulfation; approximately 30% of the dose is excreted unchanged, with 60% as metabolites. Excretion is mainly renal, with 56% of an intravenous dose recovered in (about 30–45% as unchanged drug) and 44% via biliary/fecal routes within 120 hours. The terminal elimination is 4–11 hours, which can be prolonged in due to altered protein binding and clearance. Pharmacokinetic parameters are influenced by age, with slower clearance observed in elderly patients; renal impairment requires dose adjustment (e.g., reduce to 75% if creatinine clearance 15–50 mL/min, or more substantially if <20 mL/min); and drug interactions, such as with cyclosporine, can inhibit clearance and increase (AUC) by 80–100% or more. Pharmacodynamic relationships show that etoposide exposure, particularly , correlates with the degree of as the dose-limiting toxicity and with antitumor efficacy in (SCLC).

Chemistry

Structure and properties

Etoposide, chemically designated as (5R,5aR,8aR,9R)-9-[4,6-O-(R)-ethylidene-β-D-glucopyranosyloxy]-5,5a,6,8,8a,9-hexahydro-5-(4-hydroxy-3,5-dimethoxyphenyl)furo[3',4':6,7]naphtho[2,3-d]-1,3-dioxol-6-one, possesses the molecular formula C₂₉H₃₂O₁₃ and a molecular weight of 588.56 g/mol. This compound is a semisynthetic derivative of , characterized by an epipodophyllotoxin core that includes 4'-demethylation at the pendant phenyl ring and a β-D- unit linked at the C9 position, with an ethylidene bridge spanning the 4' and 6' hydroxyl groups of the glucoside to enhance stability. Etoposide manifests as a white to off-white crystalline , exhibiting poor aqueous of approximately 0.08 mg/mL at 25°C while demonstrating good solubility in organic solvents such as and (DMSO). Its spans 236–251°C, and the phenolic hydroxyl group has a pKa of 9.8, influencing its behavior in physiological environments. The molecule displays sensitivity to light and heat, requiring storage in amber containers at controlled to prevent . For parenteral , is improved via the etoposide phosphate formulation, which hydrolyzes to the active form ; oral capsules remain stable under standard conditions, though is pH-dependent in the . Analytical characterization of etoposide typically involves UV with at approximately 285 nm in , alongside () for structural confirmation and () with UV detection for assessing purity and quantifying impurities.

Synthesis

Etoposide is semisynthetically derived from podophyllotoxin, a lignan extracted from the roots and rhizomes of the North American mayapple plant, Podophyllum peltatum. Podophyllotoxin is obtained through solvent extraction processes, traditionally using ethanol or more efficiently aqueous methods that yield 4- to 10-fold higher quantities compared to ethanolic extraction. The primary semisynthetic route begins with commercial and involves two key transformations to form the aglycone precursor, 4'-demethylepipodophyllotoxin (DMEP). First, selective demethylation at the 4'-position is achieved using acidic conditions, such as in acetic acid, followed by epimerization at the position to invert the from the to the form, typically under basic conditions like in ; this two-step process affords DMEP in approximately 52% yield. The subsequent at the C4 hydroxyl group couples DMEP with a protected glucose derivative, specifically 2,3-di-O-acetyl-4,6-O-ethylidene-α-D-glucopyranosyl , in the presence of as a catalyst to promote β-stereoselectivity; this step, originally developed by researchers in the , proceeds in and yields the protected etoposide intermediate. Deprotection of the acetyl and ethylidene groups via mild acid , followed by purification through , completes the synthesis. This semisynthetic pathway from podophyllotoxin achieves an overall yield of 20-30%, making full total synthesis impractical due to the structural complexity of the tetracyclic lignan core. The process avoids de novo construction of the podophyllotoxin scaffold, relying instead on the natural precursor's availability, though extraction from wild-harvested plants has raised sustainability concerns. Alternative methods have been explored to improve efficiency and stereocontrol. Enzymatic glycosylation using engineered glycosyltransferases, such as chimeric variants of plant-derived UGTs, enables direct O-glycosylation of DMEP with UDP-glucose, achieving up to 53% conversion in one step while enhancing β-selectivity through substrate promiscuity optimization. For the phosphate prodrug etopophos (etoposide phosphate), synthesis involves selective phosphorylation of the 4'-demethyl-4-epipodophyllotoxin β-D-glucopyranoside's 4″-hydroxyl group by reaction with phosphoryl chloride (POCl₃) and diisopropylethylamine in acetonitrile, followed by hydrolysis and salt formation. Modern improvements incorporate advanced protecting groups, such as in crystallization-induced glycosidation protocols using 4,6-O-ethylidene-2,3-di-O-benzoyl-D-glucal with boron trifluoride etherate (BF₃·Et₂O) as a Lewis acid catalyst, boosting overall yields to 79% from DMEP while ensuring stereochemical purity at the anomeric center. To address sustainability issues with podophyllotoxin sourcing, recent advances include the 2020 engineering of the complete biosynthetic pathway for etoposide precursors into tobacco plants (Nicotiana benthamiana), enabling direct in planta production and potentially reducing reliance on wild-harvested materials. This approach circumvents traditional semisynthetic steps like epimerization and demethylation, offering a more efficient and environmentally friendly alternative. Key challenges in etoposide synthesis include achieving stereochemical control at the anomeric linkage to favor the β-glycoside, which is critical for , and preventing degradation of the sensitive aglycone during acidic or acid-mediated steps. The original process, patented in the 1960s, addressed these by optimizing conditions for epimerization and but required multiple purifications; subsequent s have refined yields and scalability.

History

Discovery

Podophyllotoxin, the natural precursor to etoposide, was first isolated in 1820 from the roots and rhizomes of (mayapple), a plant native to . By the mid-19th century, extracts of P. peltatum were employed in folk and primarily as a topical treatment for and other lesions, leveraging its resinous properties. In the 1940s, researchers noted 's potent cytotoxic and antimitotic effects, sparking interest in its potential as an anticancer agent; however, its clinical development was hindered by severe , poor aqueous , and limited when administered systemically. During the 1950s and 1960s, Laboratories in initiated systematic screening of derivatives to address these limitations, focusing on glucosides to improve and reduce while preserving antitumor activity. Key progress occurred in 1966 when chemists A. von Wartburg and A. Kuhn at synthesized etoposide (initially designated VP-16-213), chemically known as 4'-demethylepipodophyllotoxin 9-[4,6-O-(R)-ethylidene-β-D-glucopyranoside], through stereoselective of the demethylated epipodophyllotoxin aglycone. This derivative exhibited markedly reduced cytotoxicity compared to yet demonstrated a superior due to enhanced water solubility and lower non-specific toxicity. The code name VP-16 originated from 's internal for vegetable-derived products, distinguishing it from the related compound teniposide (VM-26). Preclinical evaluation in the revealed etoposide's promising antitumor effects in animal models, including significant prolongation of survival in mice bearing L1210 leukemia and inhibition of growth in Walker 256 sarcoma. These findings highlighted its activity against rapidly proliferating tumors, with identified as the primary dose-limiting toxicity but manageable at therapeutic doses. Early publications, such as the 1971 report by Keller-Juslén, Kuhn, Stähelin, and von Wartburg, detailed the synthesis route and confirmed etoposide's antimitotic potency and efficacy against transplanted tumors in mice, establishing its potential as a viable anticancer agent.

Development and approvals

Preclinical studies in the demonstrated etoposide's efficacy in animal models of and testicular tumors, showing significant antitumor activity that supported advancement to human trials. Phase I clinical trials conducted between 1972 and 1975 established the maximum tolerated dose (MTD) at approximately 100 mg/m² when administered daily for five days, with myelosuppression identified as the dose-limiting toxicity (DLT). In 1978, Sandoz licensed the further development of etoposide to Bristol-Myers Squibb, which led to its FDA approval in 1983. Pivotal phase II and III trials in the 1970s and 1980s evaluated etoposide in refractory testicular cancer, achieving response rates around 80% when combined with cisplatin, which became a cornerstone of therapy. For small cell lung cancer (SCLC), European Organisation for Research and Treatment of Cancer (EORTC) trials in the 1980s confirmed etoposide's role in combination regimens, particularly with cisplatin, improving outcomes in extensive-stage disease. The U.S. (FDA) granted initial approval for etoposide in November 1983 for refractory testicular tumors and as part of combination therapy. The () approved etoposide in 1996, following initial national authorizations in Europe. Etoposide has been included on the (WHO) Model List of since 1984, recognizing its critical role in cancer treatment. Post-approval, etoposide saw expanded in the 1990s for (AML) and lymphomas, integrated into regimens like those combining it with cytarabine or . The 2019 CASPIAN phase III trial demonstrated that adding durvalumab to platinum-etoposide improved overall survival in extensive-stage SCLC by 2-4 months compared to alone. Ongoing phase II trials as of 2024-2025 are investigating etoposide-based combinations for SCLC with metastases and in elderly patients, showing promising intracranial activity. Etoposide became available as a starting in 2001, following patent expiry in the late or early . The global market for etoposide is projected to grow at a (CAGR) of 5-6% through 2030, driven by its incorporation into novel combination therapies.

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