Oxaliplatin
Descripción general
Descripción
Oxaliplatino es un fármaco quimioterapéutico a base de platino que se utiliza principalmente en el tratamiento del cáncer colorrectal. Pertenece a la clase de agentes antineoplásicos que contienen platino y es conocido por su capacidad de formar enlaces cruzados con el ADN, inhibiendo así la replicación y la transcripción del ADN. Este compuesto ha demostrado eficacia en el tratamiento de varios tipos de cáncer, incluidos los cánceres colorrectal, ovárico y pancreático .
Métodos De Preparación
Rutas sintéticas y condiciones de reacción: El oxaliplatino se sintetiza a través de un proceso de varios pasos que implica la reacción de compuestos de platino con ligandos específicos. La ruta sintética principal implica la reacción de cis-diiodo(trans-1,2-diaminociclohexano)platino(II) con ácido oxálico. Las condiciones de reacción suelen incluir una temperatura y un pH controlados para asegurar la formación del producto deseado .
Métodos de producción industrial: En entornos industriales, el oxaliplatino se produce utilizando reactores a gran escala donde las condiciones de reacción se controlan meticulosamente para lograr altos rendimientos y pureza. El proceso implica el uso de materiales de partida y disolventes de alta pureza, y el producto final se somete a rigurosas medidas de control de calidad para garantizar su eficacia y seguridad .
Análisis De Reacciones Químicas
Tipos de reacciones: El oxaliplatino experimenta varios tipos de reacciones químicas, incluidas la sustitución, la oxidación y la reducción. La reacción más notable es su capacidad de formar enlaces covalentes con el ADN, lo que lleva a la formación de enlaces cruzados intracatenarios e intercatenarios .
Reactivos y condiciones comunes: Las reacciones que involucran oxaliplatino a menudo requieren reactivos específicos como iones cloruro, agua y varios disolventes orgánicos. Las condiciones suelen incluir temperaturas y niveles de pH controlados para facilitar las transformaciones químicas deseadas .
Principales productos formados: Los principales productos formados a partir de las reacciones de oxaliplatino son los aductos de ADN, que son responsables de sus efectos citotóxicos. Estos aductos impiden la replicación y la transcripción del ADN, lo que lleva a la muerte celular .
Aplicaciones Científicas De Investigación
Colorectal Cancer
Indications:
- Oxaliplatin is primarily indicated for:
Efficacy:
- A phase II trial reported a response rate of 24.3% in patients with previously untreated metastatic colorectal adenocarcinoma, with a median progression-free survival of 126 days .
- Combination therapies have shown improved response rates ranging from 34% to 67% , significantly enhancing survival outcomes compared to treatments without this compound .
Off-Label Uses
This compound has also been explored for off-label indications, including:
- Refractory or relapsed solid tumors in pediatric patients.
- Refractory neuroendocrine tumors and various hematologic malignancies .
- Advanced ovarian cancer and refractory testicular cancer , often in combination with other agents like gemcitabine and paclitaxel .
Kounis Syndrome Induced by this compound
A notable case study documented a 52-year-old woman who experienced Kounis syndrome—a hypersensitivity reaction affecting cardiac tissue—after administration of this compound. This case highlighted the need for awareness regarding hypersensitivity reactions to platinum-based drugs .
Extravasation Events
Another case reported significant tissue damage following the extravasation of this compound during an infusion. Despite the severity of the incident, the patient showed remarkable recovery without surgical intervention after appropriate management .
Side Effects and Toxicity Profile
While this compound is effective, it is associated with several adverse effects:
- Peripheral sensory neuropathy : One of the most common side effects, reported in up to 40% of patients.
- Other toxicities include gastrointestinal disturbances (nausea, vomiting), hematologic issues (neutropenia), and acute dysesthesias .
Comparative Efficacy
The following table summarizes key findings from various clinical trials regarding this compound's efficacy:
| Study Type | Population | Response Rate | Median Survival (Months) | Main Toxicity |
|---|---|---|---|---|
| Phase II Trial | Untreated Metastatic CRC | 24.3% | 216+ days | Peripheral neuropathy |
| Combination Therapy | Previously treated CRC | 34%-67% | 15-19 months | Gastrointestinal |
| Off-label Use | Refractory solid tumors | Variable | N/A | Varies by regimen |
Mecanismo De Acción
El oxaliplatino ejerce sus efectos formando enlaces covalentes con el ADN, lo que lleva a la formación de enlaces cruzados en el ADN. Estos enlaces cruzados impiden la replicación y la transcripción del ADN, causando en última instancia la muerte celular. Los principales objetivos moleculares del oxaliplatino son las bases púricas en el ADN, donde forma enlaces cruzados intracatenarios e intercatenarios .
Las vías involucradas en el mecanismo de acción del oxaliplatino incluyen la activación de las vías de respuesta al daño del ADN, lo que lleva al arresto del ciclo celular y la apoptosis. El compuesto también interfiere con los mecanismos de reparación de las células cancerosas, haciéndolas más susceptibles a sus efectos citotóxicos .
Comparación Con Compuestos Similares
El oxaliplatino a menudo se compara con otros fármacos quimioterapéuticos a base de platino como el cisplatino y el carboplatino. Si bien los tres compuestos comparten un mecanismo de acción similar, el oxaliplatino tiene propiedades únicas que lo distinguen de los demás.
Compuestos similares:
Cisplatino: Conocido por su eficacia en el tratamiento de cánceres testiculares, ováricos y de vejiga. .
Carboplatino: Se utiliza en el tratamiento de cánceres de ovario y pulmón. .
Unicidad del oxaliplatino: El oxaliplatino es único en su capacidad de formar aductos de ADN más estables, lo que lleva a una mayor citotoxicidad en las células cancerosas. También tiene un perfil de efectos secundarios diferente, con una menor incidencia de nefrotoxicidad y ototoxicidad, pero una mayor incidencia de neuropatía periférica .
En conclusión, el oxaliplatino es un agente quimioterapéutico vital con una amplia gama de aplicaciones en la investigación científica y la práctica clínica. Sus propiedades únicas y su mecanismo de acción lo convierten en una herramienta valiosa en la lucha contra el cáncer.
Actividad Biológica
Oxaliplatin is a platinum-based chemotherapeutic agent primarily used in the treatment of colorectal cancer. Its unique chemical structure and mechanism of action differentiate it from other platinum compounds like cisplatin and carboplatin. This article provides a comprehensive overview of the biological activity of this compound, including its mechanisms, efficacy in clinical studies, and potential side effects.
This compound is characterized by the presence of a diaminocyclohexane (DACH) moiety, which enhances its antitumor activity compared to traditional platinum drugs. The mechanism of action involves the formation of DNA cross-links, which inhibit DNA replication and transcription, leading to cell death. Specifically, this compound forms intrastrand and interstrand cross-links primarily at the N7 position of guanine bases in DNA. This action complicates DNA repair mechanisms, making cancer cells more susceptible to its effects .
Key Mechanisms:
- DNA Cross-Linking: Formation of Pt-DNA adducts that prevent DNA replication.
- Immunogenic Cell Death: this compound can induce immunogenic signals in colon cancer cells, promoting an immune response against tumors .
- Cell Cycle Effects: The cytotoxicity is cell-cycle nonspecific, affecting various phases of the cell cycle .
Efficacy in Clinical Studies
Numerous clinical trials have evaluated the efficacy of this compound, particularly in combination with other agents such as fluorouracil (5-FU) and leucovorin (LV). The following table summarizes key findings from significant studies:
Case Studies
- Phase II Trial on Metastatic Colorectal Cancer :
- MOSAIC Trial :
Pharmacokinetics
The pharmacokinetics of this compound involve rapid distribution and non-enzymatic conversion into active metabolites post-administration. After intravenous infusion, the drug is primarily bound to plasma proteins, with a volume of distribution indicating extensive tissue uptake . The elimination half-life is approximately 30 hours, with renal excretion being a significant route for its metabolites.
Safety Profile and Side Effects
While this compound is effective against various cancers, it is associated with several side effects:
Q & A
Basic Research Questions
Q. What are the pharmacodynamic distinctions between oxaliplatin and cisplatin, and how do these differences influence experimental design?
this compound differs from cisplatin in its DNA adduct formation and resistance mechanisms. Unlike cisplatin, this compound forms bulky platinum-DNA adducts that evade mismatch repair (MMR) detection, contributing to activity in MMR-deficient tumors . Experimental comparisons should include cytotoxicity assays across cell lines with varying MMR status (e.g., HCT116 MMR-proficient vs. MMR-deficient models) and use COMPARE analysis to evaluate differential gene expression profiles .
Q. How should researchers optimize combination therapies involving this compound in preclinical models?
Synergy studies require factorial experimental designs to test this compound with agents like 5-fluorouracil (5-FU) or bevacizumab. For example, in the NSABP C-07 trial, this compound combined with fluorouracil/leucovorin improved 3-year disease-free survival (78.2% vs. 72.9%; HR: 0.77, P=0.002) . Preclinical models should replicate clinical dosing schedules (e.g., FOLFOX regimens) and include endpoints like tumor growth delay and apoptosis markers (e.g., caspase-3 activation) .
Q. What experimental models best recapitulate this compound-induced neuropathy for mechanistic studies?
Rodent models using cumulative this compound doses (4–6 mg/kg/week) mimic chronic neuropathy. Assess mechanical allodynia via von Frey filaments and correlate with histopathological changes in dorsal root ganglia. In vitro models using sensory neurons can evaluate mitochondrial dysfunction and oxidative stress via Seahorse assays .
Advanced Research Questions
Q. How do molecular subtypes of colorectal cancer (CRC) predict this compound benefit?
CRC subtypes (e.g., CMS4/stem-like) show differential responses. In the NSABP C-07 trial, enterocyte-subtype stage III patients had significant this compound benefit (HR: 0.22, P=0.001 in discovery cohort), while stem-like subtypes showed no benefit (HR: 0.99, P=0.96) . Researchers should integrate transcriptomic profiling (e.g., RNA-seq) with clinical outcomes and validate findings using locked algorithms in independent cohorts .
Q. What biomarkers predict this compound resistance, and how can they be functionally validated?
BRAF mutations (e.g., V600E) are prognostic for poor survival (HR: 2.31 for post-recurrence survival, P<0.0001) but not predictive of this compound resistance . Validate candidates via CRISPR/Cas9 knock-in models and assess platinum-DNA adduct repair efficiency using comet assays. Correlate with ATP7A/B transporter expression in patient-derived organoids .
Q. How does this compound reintroduction impact survival in metastatic CRC, and what statistical methods adjust for confounding factors?
In the OPTIMOX1 trial, this compound reintroduction improved OS (HR: 0.56, P=0.009). Use Cox proportional hazards models with time-dependent covariates (e.g., progression events, second-line therapies) and shared frailty models to account for center-specific reintroduction rates .
Q. Methodological Guidance
Q. What statistical approaches are critical for analyzing this compound clinical trial data with heterogeneous subtypes?
- Stratified log-rank tests : Compare survival between treatment arms within molecular subgroups .
- Multivariate Cox models : Adjust for baseline risk factors (e.g., WBC, alkaline phosphatase) .
- Interaction tests : Evaluate treatment-by-subtype effects (e.g., enterocyte vs. stem-like) .
| Subtype | This compound Benefit (HR) | 95% CI | P-Value |
|---|---|---|---|
| Enterocyte | 0.22 | 0.09–0.56 | 0.001 |
| Stem-like | 0.99 | 0.73–1.34 | 0.96 |
| Data from NSABP C-07 trial |
Q. How can network pharmacology models elucidate this compound’s off-target effects?
Integrate transcriptomic data (e.g., microarray profiling of pancreatic cancer cells) with protein interaction networks. Use systems biology tools like Cytoscape to identify hubs (e.g., autophagy-related proteins LC3B/Beclin-1) and validate via siRNA knockdown and functional assays (e.g., autophagosome quantification) .
Q. Contradictions and Validation
- vs. 11 : While molecular subtyping predicts this compound benefit in specific cohorts (e.g., enterocyte), BRAF mutations are prognostic but not predictive. Researchers must validate subtype-specific findings in independent trials and control for confounding variables like microsatellite instability .
- : this compound reintroduction improves survival, but trial designs should predefine reintroduction criteria to avoid selection bias.
Propiedades
Key on ui mechanism of action |
Oxaliplatin undergoes nonenzymatic conversion in physiologic solutions to active derivatives via displacement of the labile oxalate ligand. Several transient reactive species are formed, including monoaquo and diaquo DACH platinum, which covalently bind with macromolecules. Both inter and intrastrand Pt-DNA crosslinks are formed. Crosslinks are formed between the N7 positions of two adjacent guanines (GG), adjacent adenine-guanines (AG), and guanines separated by an intervening nucleotide (GNG). These crosslinks inhibit DNA replication and transcription. Cytotoxicity is cell-cycle nonspecific. |
|---|---|
Número CAS |
61825-94-3 |
Fórmula molecular |
C8H14N2O4Pt |
Peso molecular |
397.29 g/mol |
Nombre IUPAC |
[(1R,2R)-2-azanidylcyclohexyl]azanide;oxalic acid;platinum(2+) |
InChI |
InChI=1S/C6H12N2.C2H2O4.Pt/c7-5-3-1-2-4-6(5)8;3-1(4)2(5)6;/h5-8H,1-4H2;(H,3,4)(H,5,6);/q-2;;+2/t5-,6-;;/m1../s1 |
Clave InChI |
DRMCATBEKSVAPL-BNTLRKBRSA-N |
SMILES |
C1CCC(C(C1)[NH-])[NH-].C(=O)(C(=O)[O-])[O-].[Pt+4] |
SMILES isomérico |
C1CC[C@H]([C@@H](C1)[NH-])[NH-].C(=O)(C(=O)O)O.[Pt+2] |
SMILES canónico |
C1CCC(C(C1)[NH-])[NH-].C(=O)(C(=O)O)O.[Pt+2] |
Apariencia |
white solid powder |
Punto de ebullición |
100ºC |
Key on ui other cas no. |
63121-00-6 61825-94-3 |
Descripción física |
Solid |
Pictogramas |
Irritant; Health Hazard |
Pureza |
>98% (or refer to the Certificate of Analysis) |
Números CAS relacionados |
63121-00-6 63121-00-6 (SP-4-2 (trans)) |
Vida útil |
>10 years if stored properly |
Solubilidad |
Soluble in water at 4 mg/mL and DMSO at 20 mg/mL; slightly soluble in methanol; insoluble in ethanol. |
Almacenamiento |
Dry, dark and at 0 - 4 C for short term (days to weeks) or -20 C for long term (months to years). |
Sinónimos |
1,2 Diaminocyclohexane Platinum Oxalate 1,2-diaminocyclohexane platinum oxalate 1,2-diamminocyclohexane(trans-1)oxolatoplatinum(II) ACT 078 ACT-078 ACT078 cis-oxalato-(trans-l)-1,2-diaminocyclohexane-platinum(II) Eloxatin Eloxatine L-OHP cpd oxalato-(1,2-cyclohexanediamine)platinum II oxaliplatin oxaliplatin, (SP-4-2-(1R-trans))-isomer oxaliplatin, (SP-4-2-(1S-trans))-isomer oxaliplatin, (SP-4-3-(cis))-isomer oxaliplatine Platinum(2+) ethanedioate (1R,2R)-1,2-cyclohexanediamine (1:1:1) platinum(II)-1,2-cyclohexanediamine oxalate |
Origen del producto |
United States |
Retrosynthesis Analysis
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Strategy Settings
| Precursor scoring | Relevance Heuristic |
|---|---|
| Min. plausibility | 0.01 |
| Model | Template_relevance |
| Template Set | Pistachio/Bkms_metabolic/Pistachio_ringbreaker/Reaxys/Reaxys_biocatalysis |
| Top-N result to add to graph | 6 |
Feasible Synthetic Routes
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