Stability study of the compatibility of three chemotherapeutic agents in a mixture solution of different kinds of vehicles in the EPOCH chemotherapy scheme
Introduction
The EPOCH protocol is the first-line treatment for patients recommended by the non-Hodgkin lymphomas NCCN guidelines and the Chinese diffuse large B-cell lymphoma diagnosis and guidelines (1). At present, the EPOCH protocol has been discussed and adopted by the hospital’s Drug Administration Committee and applied in the Department of Hematology and lymphoma of our hospital. The traditional regimen was an injection of etoposide 50 mg/m2, doxorubicin 10 mg/m2, and vincristine 0.4 mg/m2, mixed with 500 mL of 0.9% sodium chloride slowly instilled over 24 h via the central vein (2,3). Doxorubicin is a cell cycle nonspecific drug whose primary site of action is the nucleus, and its mechanism of action is to bind to DNA, thereby inhibiting the synthesis of nucleic acids and mitosis. Vincristine, a cell cycle specific antineoplastic drug, acts by inhibiting the polymerization of intracellular tubulin and preventing the formation of the spindle apparatus in the mitosis of proliferating cells, resulting in the arrest of cell division in the mitotic phase. Etoposide, a cell cycle specific antitumor drug, acts on DNA topoisomerase II to form a drug enzyme DNA stable reversible complex that impedes DNA repair. In vitro studies have found that these drugs are more effective at killing tumor cells at low concentrations with prolonged exposure. Several studies have confirmed (4-7) this regimen is safe, effective, and well tolerated. There are several studies that confirm the vindesine has similar antitumor activity to vincristine but has a lower incidence of neurologic adverse effects (8), so vindesine is currently used instead of vincristine. Epirubicin is doxorubicin of the isoschizomers, antitumor activity is comparable to doxorubicin but has a larger safe dose range, and less cardiotoxicity and adverse effects of myelosuppression than doxorubicin (9), so it is currently mostly used epirubicin instead of doxorubicin. However, the epirubicin specification does not recommend that the drug be mixed with other drugs for intravenous infusion. At the same time the Chinese “280 rapid search form for changes in compatibility of injection materials” and “346 rapid search form for changes in compatibility of injection materials” publications both suggest that epirubicin and vindesine are not suitable for use, and suggest that the intravenous injection of vindesine should be selected as 0.9% sodium chloride injection, while intravenous infusion (2–6 hours) should be selected as a 5% glucose injection for deployment. Although several studies have now preliminarily confirmed the compatibility stability of these three drugs (10), because in clinical practice, physicians often consider the choice of the vehicle when using it if the patients are combined with other diseases such as diabetes, renal dysfunction, etc., so whether there is a difference in the stability of these three drugs when mixed in normal saline and glucose, respectively, still needs to be verified. Besides, our hospital has prepared imported and domestic two epirubicin, and these two drugs also have differences in the manufacturing process, excipients, etc. of the drug product, while the price aspects will also affect the clinician’s choice when using the EPOCH protocol, so we consider that imported and domestic varieties also need to be experimentally verified, respectively. To solve the problem of actual drug selection by clinicians in our hospital, while providing safer and rationalized medication advice and basis for clinic, we simulated the conditions under which the EPOCH protocol is clinically used to study the compatibility and stability of etoposide, vindesine, epirubicin (imported), and epirubicin (domestic) in 0.9% sodium chloride and 5% glucose, respectively, by evaluating changes of pH, insoluble microparticles, osmolarity, and content after mixing compatibility. The results may provide a basis for the safe and effective clinical administration of these drugs.
Methods
Instrument
A Waters 2690 HPLC instrument (Waters, USA), ultrapure water (Millipore, USA), electronic balance, pH meter (Diamagnetic, phs-3c), insoluble microparticle detector (GFW-5JA, Tianhe Medical Instrument Co., Ltd.), and osmolality measurement (SMC 30C, Tianjin Sgray Technology Co., Ltd.) were used in this study.
Trial medication
The following medication was used: etoposide injection (Jiangsu Hengrui Medicine Co., Ltd, specification: 5 mL: 0.1 g, lot No.170421BJ); epirubicin hydrochloride for injection (imported) (famaxine, FMX, Pfizer Pharmaceutical Ltd, specification 10 mg, lot No. R29762); epirubicin hydrochloride for injection (domestic) (Ai Dasheng, ADS, Zhejiang Hisun Pharmaceutical Co., Ltd., specification 10 mg, lot No. 17006321); vindesine sulfate for injection (Hangzhou Minsheng Pharmaceutical Co., Ltd., specification 1 mg, lot No. 170506D); etoposide control (Chinese Academy for food and drug control, lot No.100388); epirubicin hydrochloride control (Chinese Academy for food and drug control, lot No.130560); vindesine sulfate control (Chinese Academy for food and drug control, lot No.100454). 0.9% sodium chloride injection 500 mL, Qingdao Huaren Pharmaceutical Co., Ltd., lot No. G1707043; 5% glucose injection 500 mL, Qingdao Huaren Pharmaceutical Co., Ltd., lot No. E1707047. formic acid (analytical grade), acetonitrile, and methanol were used as chromatographically pure reagents.
Study methods and conditions
Chromatographic conditions
The following conditions applied: Column: Venus ASB C18 (4.6 mm ×250 mm, 5 μm); mobile phase: 0.5% formic acid: methanol: acetonitrile (60:25:15, v/v); flow rate: 1.0 mL·min−1; column temperature: room temperature, 25 °C; detection wavelength: 254 nm; injection volume: 10 μL. Chromatograms are shown in Figure 1.
Preparation of solutions
Reference solution
Etoposide 25 mg was accurately weighed and placed into a 25 mL volumetric flask, dissolved in methanol, and brought to volume as an etoposide control stock solution (1,000 μg/mL). Epirubicin 15 mg was then accurately weighted and placed in a 25 mL volumetric flask, dissolved in methanol, and brought to volume as an the epirubicin control stock solution (600 μg/mL).
Test solution
According to the clinical dosage (etoposide 50 mg/m2, epirubicin 30 mg/m2, and vindesine 1 mg/m2), the body surface area was calculated as 1.75 m2, and etoposide injection 4.20 mL, epirubicin hydrochloride (domestic) and epirubicin hydrochloride (imported) 50 mg, and vindesine sulfate 1.65 mg were obtained. Etoposide, epirubicin (imported), and vindesine were added to 500 mL of 0.9% sodium chloride injection and 5% glucose injection as N-FMX and G-FMX, respectively; etoposide, epirubicin (homemade), and vindesine were added to 500 mL of 0.9% sodium chloride injection and 5% glucose injection into test N-ADS and test G-ADS, respectively, and the four aliquots were placed at room temperature (25 °C).
Preparation of standard curves
An appropriate amount of etoposide control stock solution was taken and formulated into serial mass concentration control solutions containing etoposide 50, 100, 200, 500, and 1,000 μg/mL, respectively, and measured by injection under the chromatographic conditions described above. Peak area values (A) versus mass concentrations (C, μg/mL) were subjected to linear regression to obtain a standard curve for etoposide as A = 4194.2C − 1669.9, R2=0.9997, and the results showed a good linear relationship of etoposide in the range of 50–1,000μg/mL, respectively, which were injected and determined according to the chromatographic conditions described above. Peak area values (A) versus mass concentrations (C, μg/mL) were subjected to linear regression, and the standard curve of vindesine was obtained as A = 52742C + 3727.8, R2=0.9999. The results showed good linearity for vindesine in the range of 1–20 μg/mL.
Appropriate amounts of the stock solution of epirubicin were taken and formulated into serial mass concentration control solutions containing epirubicin 30, 60, 120, 300, and 600 μg/mL) were subjected to linear regression and the standard curve of epirubicin was obtained as A = 21320C + 6996.3, R2=0.9999. The results showed a good linear relationship between epirubicin in the range of 30–600 μg/mL.
Limit of quantitation
An appropriate amount of the lowest concentration solution under the linear term was taken and diluted stepwise with the mobile phase to determine the limits of quantification as 0.2 μg/mL for etoposide, 0.1 μg/mL for epirubicin at a signal-to-noise ratio of approximately 10.
Precision
The middle concentration solution under the linear term was taken and the injection was repeated six times under the above chromatographic conditions. The peak areas of the three drugs were recorded to calculate the injection precision and the results showed etoposide 0.25%, vindesine 0.66%, and epirubicin 0.26%.
Rate of recovery
Stock solutions with known concentrations were added to etoposide solution, formulated to contain 40%, 50%, and 60% etoposide in three portions each, measured under the chromatographic conditions described above, and the peak areas of etoposide were recorded, and the recoveries were calculated. The recoveries of vindesine and epirubicin were determined by the same method, and the results are shown in Table 1, indicating good repeatability.
Table 1
| Loading volume | Rate of recovery, % | ||
|---|---|---|---|
| Vindesine | Etoposide | Epirubicin | |
| 40% | 98.2 | 100.6 | 100.3 |
| 99.1 | 101.1 | 99.8 | |
| 101.1 | 99.8 | 98.9 | |
| 50% | 99.3 | 100.6 | 98.7 |
| 101.2 | 100.2 | 99.8 | |
| 100.1 | 99.8 | 100.5 | |
| 60% | 98.6 | 98.2 | 98.5 |
| 100.2 | 99.4 | 99.2 | |
| 99.6 | 100.1 | 101.8 | |
| Average value | 99.7 | 99.9 | 99.7 |
Content assay
According to the common clinical volume and used concentration, the four groups of the compatibility mixed drug solution of “Test solution” above were respectively sampled at different times after addition (0, 2, 4, 6, 8, 10, 12, 24, 36, 48 h) for the content determination of the three drugs. The appearance traits of the drug solution were then observed to see the specific results with or without discoloration or impurity.
PH, osmolarity, and insoluble microparticle assay
The pH, osmolarity, and insoluble microparticles of the test solution were measured at 0, 2, 4, 6, 8, 10, 12, 24, 36, and 48 h after mixing the four groups of the compatibility mixture under “Test solution” above.
Statistics
SPSS17.0 software was used to analyze the experimental results and calculate the mean, standard deviation of the percentage contents, pH, osmolarity, and insoluble microparticles of each component, respectively. One way ANOVA was used to compare various data among samples from the four groups, and the LSD method was further selected for pairwise comparison according to the homogeneity of variance test, with the significance level set as α=0.05.
Results
Content assay results
The results of the test showed that within 48 h, the mixed drugs of the four compatibility groups had no color change in appearance and no impurities were produced. The content changes were in the range of ±5% or less, which was within the effective range of clinical medication (Table 2), and the chromatogram at 48 h showed no other absorption peaks.
Table 2
| Solution | Time/h | Content, % () | ||
|---|---|---|---|---|
| Vindesine | Etoposide | Epirubicin | ||
| N-FMX | 0 | 100.00±0.00 | 100.00±0.00 | 100.00±0.00 |
| 2 | 100.18±0.22 | 100.44±0.76 | 100.75±0.85 | |
| 4 | 100.02±0.04 | 100.04±0.41 | 100.33±0.57 | |
| 6 | 99.60±0.88 | 99.74±0.64 | 99.86±0.64 | |
| 8 | 99.35±0.23 | 100.49±0.59 | 100.08±0.09 | |
| 10 | 99.04±0.04 | 99.92±0.65 | 100.58±0.58 | |
| 12 | 98.96±0.22 | 100.04±0.02 | 100.14±0.09 | |
| 24 | 98.96±0.07 | 100.14±0.69 | 99.98±0.70 | |
| 36 | 99.15±0.61 | 100.06±0.02 | 100.11±0.81 | |
| 48 | 98.73±0.35 | 100.22±0.94 | 100.05±0.94 | |
| N-ADS | 0 | 100.00±0.00 | 100.00±0.00 | 100.00±0.00 |
| 2 | 99.80±0.12 | 99.86±0.53 | 100.01±0.37 | |
| 4 | 99.22±0.85 | 100.03±0.11 | 100.03±0.89 | |
| 6 | 99.08±0.88 | 99.97±0.33 | 99.75±0.29 | |
| 8 | 99.67±0.43 | 100.04±0.38 | 100.06±0.69 | |
| 10 | 99.09±0.11 | 99.82±0.68 | 100.09±0.45 | |
| 12 | 98.81±0.45 | 99.74±0.18 | 99.99±0.19 | |
| 24 | 98.74±0.25 | 99.41±0.39 | 99.41±0.32 | |
| 36 | 98.60±0.38 | 100.00±0.28 | 99.67±0.22 | |
| 48 | 98.34±0.63 | 99.76±0.63 | 99.89±0.63 | |
| G-FMX | 0 | 100.00±0.00 | 100.00±0.00 | 100.00±0.00 |
| 2 | 100.56±0.96 | 100.37±0.31 | 100.54±0.41 | |
| 4 | 100.43±0.83 | 100.31±0.27 | 100.37±0.19 | |
| 6 | 99.35±0.30 | 100.24±0.64 | 99.67±0.29 | |
| 8 | 99.26±0.29 | 100.10±0.19 | 100.22±0.47 | |
| 10 | 98.90±0.44 | 99.89±0.74 | 99.66±0.81 | |
| 12 | 99.01±0.59 | 100.03±0.24 | 99.94±0.05 | |
| 24 | 98.87±0.20 | 100.29±0.74 | 99.66±0.59 | |
| 36 | 98.87±0.39 | 100.24±0.59 | 99.67±0.73 | |
| 48 | 98.26±0.43 | 100.12±0.57 | 99.99±0.20 | |
| G-ADS | 0 | 100.00±0.00 | 100.00±0.00 | 100.00±0.00 |
| 2 | 99.99±0.82 | 99.93±0.05 | 99.81±0.04 | |
| 4 | 99.28±0.34 | 99.86±0.13 | 99.40±0.36 | |
| 6 | 98.82±0.25 | 99.21±0.36 | 99.21±0.57 | |
| 8 | 99.70±0.50 | 99.94±0.69 | 99.24±0.03 | |
| 10 | 99.10±0.40 | 99.74±0.75 | 99.74±0.37 | |
| 12 | 99.08±0.68 | 99.89±0.11 | 99.89±0.16 | |
| 24 | 98.72±0.12 | 99.84±0.51 | 99.84±0.91 | |
| 36 | 98.14±0.71 | 99.95±0.51 | 99.95±0.90 | |
| 48 | 98.58±0.37 | 100.33±0.78 | 100.12±0.34 | |
N-FMX, imported epirubicin, vindesine, and etoposide in 0.9% sodium chloride injection; N-ADS, locally made epirubicin, vindesine, and etoposide in 0.9% sodium chloride injection; G-FMX, imported epirubicin, vindesine, and etoposide in 5% glucose injection; G-ADS, locally made epirubicin, vindesine, and etoposide in 5% glucose injection.
PH, osmolality, insoluble microparticle assay results
The test results showed (Table 3) there was no obvious change in the pH and osmotic pressure of the mixed drug solutions of the four groups within 48 h, and the change of insoluble microparticles did not exceed the requirements of the 2020 edition of Pharmacopoeia of the Peoples Republic of China, which is 10μm or more particles no more than 25 per mL, and 25 μm or more particles no more than 3 particles per mL.
Table 3
| Test solution | Time/h | pH () | Osmotic pressure (), mOsm·kg−1 | Insoluble particles () | |
|---|---|---|---|---|---|
| ≥10 μm | ≥25 μm | ||||
| N-FMX | 0 | 4.50±0.02 | 348±1 | 22.5±0.1 | 0.8±0.0 |
| 2 | 4.48±0.02 | 346±3 | 17.9±1.1 | 0.3±0.1 | |
| 4 | 4.51±0.02 | 346±2 | 17.8±0.6 | 0.1±0.1 | |
| 6 | 4.48±0.02 | 346±2 | 15.7±0.3 | 0.2±0.2 | |
| 8 | 4.49±0.02 | 348±2 | 14.7±0.5 | 0.2±0.2 | |
| 10 | 4.52±0.01 | 348±2 | 13.1±1.2 | 0.2±0.0 | |
| 12 | 4.52±0.03 | 348±2 | 10.2±1.4 | 0.1±0.1 | |
| 24 | 4.52±0.01 | 348±2 | 8.8±0.2 | 0.2±0.0 | |
| 36 | 4.53±0.03 | 346±1 | 8.9±0.2 | 0.1±0.1 | |
| 48 | 4.53±0.02 | 348±1 | 12.0±2.0 | 0.1±0.1 | |
| N-ADS | 0 | 4.51±0.02 | 344±3 | 23.5±0.1 | 0.9±0.1 |
| 2 | 4.51±0.02 | 344±2 | 23.5±0.6 | 1.2±0.2 | |
| 4 | 4.51±0.01 | 343±2 | 22.7±0.6 | 0.7±0.1 | |
| 6 | 4.49±0.01 | 346±3 | 22.0±1.0 | 0.5±0.1 | |
| 8 | 4.50±0.02 | 346±1 | 20.7±0.5 | 0.3±0.1 | |
| 10 | 4.52±0.02 | 345±3 | 20.4±0.3 | 0.4±0.0 | |
| 12 | 4.51±0.02 | 349±1 | 21.7±1.5 | 0.5±0.1 | |
| 24 | 4.51±0.02 | 349±1 | 22.5±0.4 | 0.7±0.1 | |
| 36 | 4.52±0.01 | 349±3 | 22.7±0.3 | 0.6±0.0 | |
| 48 | 4.52±0.02 | 348±2 | 22.9±0.4 | 0.5±0.1 | |
| G-FMX | 0 | 4.03±0.03 | 329±1 | 22.8±0.2 | 0.9±0.1 |
| 2 | 4.05±0.04 | 329±2 | 21.1±1.3 | 0.9±0.3 | |
| 4 | 4.06±0.04 | 328±2 | 18.3±0.5 | 0.9±0.1 | |
| 6 | 4.07±0.02 | 330±2 | 18.7±1.1 | 0.6±0.3 | |
| 8 | 4.05±0.03 | 331±3 | 18.3±0.3 | 0.4±0.0 | |
| 10 | 4.04±0.03 | 330±2 | 20.6±0.7 | 0.5±0.2 | |
| 12 | 4.05±0.03 | 332±3 | 21.7±0.5 | 0.6±0.3 | |
| 24 | 4.03±0.03 | 329±1 | 20.9±1.3 | 0.7±0.1 | |
| 36 | 4.04±0.02 | 328±1 | 22.3±0.8 | 0.7±0.1 | |
| 48 | 4.02±0.02 | 330±2 | 22.1±1.5 | 0.6±0.0 | |
| G-ADS | 0 | 4.00±0.01 | 330±2 | 23.6±0.2 | 1.0±0.2 |
| 2 | 4.05±0.04 | 328±1 | 21.7±1.3 | 0.8±0.2 | |
| 4 | 4.04±0.03 | 332±3 | 22.1±0.2 | 0.7±0.1 | |
| 6 | 4.05±0.01 | 332±2 | 18.8±0.3 | 0.6±0.2 | |
| 8 | 4.04±0.02 | 333±2 | 19.3±0.6 | 0.3±0.3 | |
| 10 | 4.02±0.02 | 333±2 | 21.7±1.3 | 0.3±0.1 | |
| 12 | 4.03±0.02 | 330±3 | 22.2±0.3 | 0.3±0.1 | |
| 24 | 4.02±0.02 | 331±2 | 21.6±1.2 | 0.5±0.1 | |
| 36 | 4.01±0.03 | 330±2 | 22.3±0.3 | 0.3±0.1 | |
| 48 | 4.01±0.01 | 330±1 | 22.7±0.3 | 0.4±0.0 | |
N-FMX, imported epirubicin, vindesine, and etoposide in 0.9% sodium chloride injection; N-ADS, locally made epirubicin, vindesine, and etoposide in 0.9% sodium chloride injection; G-FMX, imported epirubicin, vindesine, and etoposide in 5% glucose injection; G-ADS, locally made epirubicin, vindesine, and etoposide in 5% glucose injection.
Statistical results
The results showed that there were no significant differences in the contents of the three drugs among the four groups within 48 h after the deployment of the infusion (P>0.05). The different vehicle groups were compared, and significant differences (P<0.05) were observed between saline (N-FMX and N-ADS) and glucose groups (G-FMX and G-ADS) in pH and osmolarity results. In terms of insoluble microparticles, at hour 0, four groups with ≥10 μm (P=0.848) and ≥25 μm (P=0.330) did not significantly differ in the number of microparticles. However, with longer placement time, at ≥10 μm, the number of microparticles (17.9±1.1) of the N-FMX group compared with the other three groups of N-ADS (23.5±0.6), G-FMX (21.1±1.3), and G-ADS (21.7±1.3) were significantly different (P=0.000, 0.013, 0.000, respectively), and at ≥25 μm of particles (0.3±0.1) compared with the other three groups of N-ADS (1.2±0.2), G-FMX (0.9±0.3), and G-ADS (0.8±0.2) were similarly significant (P=0.001, 0.009, and 0.029, respectively).
Discussion
Selection of chromatographic conditions
Chromatographic conditions for the mobile phase of etoposide, epirubicin, and vindesine were selected with reference to the 2020 edition of Pharmacopoeia of the Peoples Republic of China and other studies, most of which mentioned the use of phosphate buffer as an integral part of the mobile phase under the condition of the C18 column. However, as this experiment mimicked the impurities in the liquid-mass combination deployment solution analyzed in the future, the nonvolatile phosphate buffer was not selected as the aqueous phase. A review of the literature found that the lower the pH of the mobile phase, the better the separation of the three, so a formic acid dilution commonly used in chromatographic conditions was chosen to lower the pH of the mobile phase. Following the concentration of formic acid from low to high injection, it was found that the vindesine retention time was around 5 min when 0.5% formic acid was used, and there was no other heterogenous peak interference in the peak region. Adjusting the ratio of methanol to acetonitrile showed etoposide produced an overlap in retention time with epirubicin when the ratio of methanol was too low, while increasing the methanol ratio and decreasing the acetonitrile ratio improved the resolution of the two. The experimental mobile phase was finally determined to be 0.5% formic acid: methanol: acetonitrile (60:25:15, v/v), with a flow rate 1.0 mL·min−1; column temperature: room temperature, 25 °C; and detection wavelength: 254 nm. Under these conditions, vindesine, etoposide, and epirubicin showed peaks at 5.7, 13.7, and 24.1 min, respectively, which did not interfere with each other.
Choice of vehicle for sample solution
Since the concentrations of each component of the sample solution were in the linear range, they could be directly injected for detection, and the results showed there was no statistical difference in the changes of the contents of the three drugs, whether in saline or glucose.
As no significant changes in content were observed between samples, we focused on the safety of infusion use. Osmolality can influence the movement of water molecules in cells of the vessel wall, and the higher the osmolality, the greater the venous irritation (11). Hypertonic solutions (>340 mOsm/L), which dehydrate the vessel intima, cause damage to the intima by exposing the intima to irritant solutions, resulting in phlebitis, venospasm, and thrombosis. In this experiment, the osmolality of the mixed solution saline group was greater than that of the glucose group (all time periods were statistically different, P<0.05), and the measured results at each time were slightly higher than 340 mOsm/L. Extensive research in this country and abroad has been conducted on how to reduce the phlebitis caused by the irritation of injectable agents, and results have shown that the pH range of tolerable infusion for humans is 4–9, and a pH value below 4 or above 9 will lead to pain and phlebitis. Further, the severity of phlebitis is directly related to the pH of infusion, and the lower the pH value, the more serious the phlebitis. In this study, the pH of the dextrose group was smaller (all time periods were statistically different, P<0.05) and closer to 4.00 than that of the saline group, which is close to the human tolerable pH minimum for infusion. Comparing the pH and osmolality of the saline and glucose groups showed there were pros and cons to using the two vehicle configurations of mixed infusion. While there were some statistical differences, considering this treatment regimen has a longer instillation time (~48 h) and slower instillation rate, the effects of lower pH and higher osmolality on blood vessels were of little clinical significance between groups.
Insoluble microparticles are particulate impurities in infusion fluid which widely exist in infusion products, and are an important factor leading to adverse reactions/events in intravenous administration. Insoluble microparticles in an infusion are macroscopically invisible nonmetabolic particulate impurities that are typically less than 50 μm and can cause immediate or long-term hazards to the human body. When deployment was just completed in this experiment, insoluble microparticles of the four groups did not differ significantly due to incomplete mixing of the drug with the system of diluted solutions, but all were close to the upper limit of the prescribed range of pharmacopoeias. Whereas there were fewer insoluble microparticles in the group that imported epirubicin in saline with progressively longer placement time, they were less affected by the time variation. After the time of placement reached 2 h, ≥10 and ≥25 μM of the microparticle number of the other three compatibility solutions (N-ADS, G-FMX, G-ADS) were significantly different (P<0.05). Since this chemotherapy regimen had a longer instillation time (about 48 h), there is some clinical practical significance of this statistical difference. Taking the above results together, when using the EPOCH protocol, imported epirubicin is recommended, and should be used as an intravenous infusion together with etoposide and vindesine diluted in 500 mL of normal saline solution. This mixed liquid character is stable and less irritating at room temperature, which is suitable for clinical practical applications. While central venous infusion is recommended to reduce the possibility of peripheral vascular irritancy and extravasation, in cases involving prolonged infusion, patients should be monitored for possible adverse effects such as granulocytopenia, gastrointestinal reactions, mucositis, cardiac toxicity, and phlebitis, which may be managed symptomatically as necessary to ensure patient safety.
Acknowledgments
Funding: None.
Footnote
Data Sharing Statement: Available at https://dx.doi.org/10.21037/tcr-21-1819
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://dx.doi.org/10.21037/tcr-21-1819). The authors have no conflicts of interest to declare.
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(English Language Editor: B. Draper)
