Takao Kamei

Phase II study of weekly intravenous and intraperitoneal paclitaxel combined with S-1 for advanced gastric cancer with peritoneal metastasis

BACKGROUND A phase II study to evaluate the efficacy and tolerability of weekly i.v. and i.p. paclitaxel (PTX) combined with S-1 was carried out in gastric cancer patients with peritoneal metastasis. PATIENTS AND METHODS Gastric cancer patients with peritoneal dissemination and/or cancer cells on peritoneal cytology were enrolled. PTX was administered i.v. at 50 mg/m(2) and i.p. at 20 mg/m(2) on days 1 and 8. S-1 was administered at 80 mg/m(2)/day for 14 consecutive days, followed by 7 days rest. The primary end point was the 1-year overall survival (OS) rate. Secondary end points were the response rate, efficacy against malignant ascites and safety. RESULTS Forty patients were enrolled, including 21 with primary tumors with peritoneal dissemination, 13 with peritoneal recurrence and six with positive peritoneal cytology only. The median number of courses was 7 (range 1-23). The 1-year OS rate was 78% (95% confidence interval 65% to 90%). The overall response rate was 56% in 18 patients with target lesions. Malignant ascites disappeared or decreased in 13 of 21 (62%) patients. The frequent grade 3/4 toxic effects included neutropenia (38%), leukopenia (18%) and anemia (10%). CONCLUSION Combination chemotherapy of i.v. and i.p. PTX with S-1 is well tolerated and active in gastric cancer patients with peritoneal metastasis.

Phase I Pharmacokinetic Study of Weekly Intravenous and Intraperitoneal Paclitaxel Combined with S-1 for Advanced Gastric Cancer

Objectives: A dose-escalation study of weekly intraperitoneal paclitaxel (PTX) combined with S-1 and intravenous PTX was performed to determine the maximum-tolerated dose (MTD) and recommended dose (RD) in gastric cancer patients. Patients and Methods: Nine gastric cancer patients with peritoneal dissemination and/or cancer cells on peritoneal cytology were enrolled. PTX was administered intravenously on days 1 and 8 at a fixed dose of 50 mg/m2, and intraperitoneally with an initial dose of 20 mg/m2, stepped up to 30 or 40 mg/m2. S-1 was administered at a fixed dose of 80 mg/m2/day for 14 consecutive days, followed by 7 days of rest. A pharmacokinetic study of PTX was also performed. Results: The MTD was determined to be 30 mg/m2, as 2 of 3 patients developed dose-limiting toxicities, grade 3 febrile neutropenia and diarrhea. Therefore, the RD was determined to be 20 mg/m2. The intraperitoneal and serum PTX concentration remained effective for over 72 and 48 h, respectively. Conclusions: Combined chemotherapy of S-1 plus weekly intravenous and intraperitoneal PTX was shown to be a safe regimen that should be further explored in clinical trials.

Intraperitoneal administration of paclitaxel solubilized with poly(2-methacryloxyethyl phosphorylcholine-co n-butyl methacrylate) for peritoneal dissemination of gastric cancer

Intraperitoneal (i.p.) administration of paclitaxel (PTX) is a hopeful therapeutic strategy for peritoneal malignancy. Intravenously (i.v.) injected nanoparticle anticancer drugs are known to be retained in the blood stream for a long time and favorably extravasated from vessels into the interstitium of tumor tissue. In this study, we evaluated the effect of i.p. injection of PTX (PTX‐30W), which was prepared by solubulization with water‐soluble amphiphilic polymer composed of PMB‐30W, a co‐polymer of 2‐methacryloxyethyl phosphorylcholineand n‐butyl methacrylate, for peritoneal dissemination of gastric cancer. In a peritoneal metastasis model with transfer of MKN45P in nude mice, the effct of i.p. administration of PTX‐30W was compared with conventional PTX dissolved in Cremophor EL (PTX‐Cre). The drug accumulation in peritoneal nodules was evaluated with intratumor PTX concentration and fluorescence microscopic observation. PTX‐30W reduced the number of metastatic nodules and tumor volume significantly more than did conventional PTX dissolved in Cremophor EL (PTX‐Cre), and prolonged the survival time (P < 0.05). PTX concentration in disseminated tumors measured by HPLC was higher in the PTX‐30W than in the PTX‐Cre group up to 24 h after i.p. injection. Oregon green–conjugated PTX‐30W, i.p. administered, preferentially accumulated in relatively hypovascular areas in the peripheral part of disseminated nodules, which was significantly greater than the accumulation of PTX‐Cre. I.p. administration of PTX‐30W may be a promising strategy for peritoneal dissemination, due to its superior characteristics to accumulate in peritoneal lesions. (Cancer Sci 2009; 100: 1979–1985)

Spatial distribution of intraperitoneally administrated paclitaxel nanoparticles solubilized with poly (2‐methacryloxyethyl phosphorylcholine‐co n‐butyl methacrylate) in peritoneal metastatic nodules

Intraperitoneal (i.p.) administration of paclitaxel nanoparticles (PTX‐30W) prepared by solubulization with the amphiphilic copolymer of 2‐methacryloxyethyl phosphorylcholine and n‐butyl methacrylate can efficiently suppress the growth of peritoneal metastasis. In this study, we characterized the drug distribution of i.p. injected PTX‐30W in peritoneal tumor and liver in a mouse model using MKN45, human gastric cancer cells. Oregon green‐conjugated PTX‐30W showed perivascular accumulation in MKN45 tumor in the peritoneum at 24 h after intravenous (i.v.) injection; however, the amount of PTX in tumor was markedly less than that in liver. In contrast, a larger amount of PTX accumulated in the peripheral area of disseminated nodules at 1 h after i.p. injection and the area gradually enlarged. The depth of PTX infiltration reached 1 mm from the tumor surface at 48 h after i.p. injection, and the fluorescence intensity was markedly greater than that in liver. Interestingly, i.p. injected PTX preferentially accumulated in relatively hypovascular areas, and many tumor cells in the vicinity of PTX accumulation showed apoptosis. This unique accumulation pattern and lesser washout in hypovascular areas are thought to be attributable to the superior penetrating activity of PTX‐30W, and thus, PTX‐30W is considered to be highly suitable for i.p. chemotherapy for peritoneal dissemination. (Cancer Sci 2011; 102: 200–205)

Intraoperative blood loss is a critical risk factor for peritoneal recurrence after curative resection of advanced gastric cancer.

BackgroundPerioperative blood transfusion has been shown to be associated with poor outcome in various types of malignancy. However, the relationship between the amount of blood loss and specific types of cancer recurrence has not been documented.MethodsWe retrospectively examined the amount of intraoperative blood loss and the recurrence pattern in 146 patients who underwent curative gastrectomy for advanced gastric cancer and assessed the possible correlation between intraoperative blood loss and peritoneal, locoregional, and hematogenous recurrences.ResultsThe amount of intraoperative blood loss in patients who developed peritoneal recurrence was significantly greater than that in patients without peritoneal recurrence, irrespective of blood transfusion. In contrast, the blood loss was not associated with nodal or hematogenous recurrence. Multivariate analysis demonstrated that large blood loss as well as operative curability B and adjuvant chemotherapy were independent risk factors for peritoneal recurrence and a worse outcome in advanced gastric cancer.ConclusionsIntraoperative blood loss in curative gastrectomy for advanced gastric cancer may have a specific association with the development of peritoneal recurrence. Surgeons must remember that clean and dry surgery may lessen not only 30-day mortality and morbidity but long-term peritoneal recurrence in gastric cancer.

Intra-peritoneal administration of paclitaxel with non-animal stabilized hyaluronic acid as a vehicle--a new strategy against peritoneal dissemination of gastric cancer.

BACKGROUND AND AIM Intra-peritoneal administration (i.p.) of Taxanes has recently been reported to be effective for the treatment of peritoneal dissemination, presumably because extremely high concentration of the drug is achievable onto the disseminated nodules as compared to intra-venous administration. Here, we aimed to investigate the ability of non-animal stabilized hyaluronic acid (NASHA) to retain the anti-cancer drugs in the peritoneal cavity, and, consequently, improve the efficacy of i.p. administration of paclitaxel. METHODS Mice were inoculated i.p. with MKN45P gastric cancer cells. The mice received i.p. administrations of paclitaxel, without or with NASHA, once a week for 3 consecutive weeks, and the intra-peritoneal nodules were counted after 4 weeks. The ability of NASHA to retain the i.p. administered liquid and paclitaxel in abdominal cavity was also investigated. Finally, the concentration of paclitaxel in metastatic nodule was measured with HPLC. RESULTS In the group receiving paclitaxel with NASHA, the number of disseminated nodules were significantly smaller than in those receiving paclitaxel without NASHA. The fluid volumes and concentration of paclitaxel recovered from the abdominal cavity as well as the concentrations of paclitaxel in metastatic nodule were significantly increased by the addition of NASHA. CONCLUSION Our results indicate that NASHA improves the exposure time of i.p. administrated paclitaxel to disseminated nodules by retaining the drug in the abdominal cavity. Since the material is used in cosmetic surgery with few adverse effects, NASHA can be clinically used as the vehicle for the i.p. administration of anti-cancer agents for advanced gastric cancer with peritoneal dissemination.

Weekly intravenous and intraperitoneal paclitaxel combined with S-1 for malignant ascites due to advanced gastric cancer.

Malignant ascites caused by gastric cancer are chemotherapy resistant and carry a poor prognosis. The efficacy of a regimen including intraperitoneal paclitaxel (PTX) was evaluated in 33 gastric cancer patients with ascetic fluid in the peritoneal cavity diagnosed with computed tomography (CT) scanning. Synchronous administration of intravenous (50 mg/m2) and intraperitoneal (20 mg/m2) PTX was performed via a subcutaneously placed intraperitoneal catheter on days 1 and 8, and S-1 was administered twice daily at 80 mg/m2/day for 14 consecutive days from day 1 to day 14, followed by 7 days of rest. The ascitic fluid volume was calculated with NIH Image J software using continuous CT images. After 2–4 treatment cycles, 23 (70%) patients showed reductions in their ascitic volumes of >50%. Ascites disappeared completely in 8 patients and were markedly reduced (to <3% of the original volume) in 4 of the 9 patients (44%) who initially had massive (>2,500 ml) ascites. Median overall survival was significantly better in patients with ascitic reduction. Weekly intravenous and intraperitoneal PTX combined with S-1 was highly effective in gastric cancer with malignant ascites. The change in ascitic fluid volumes determined by CT image measurements is a useful predictor of outcome in these patients.

Flow cytometric quantification of intraperitoneal free tumor cells in patients with peritoneal metastasis.

Peritoneal metastasis (PM) is the most life‐threatening type of metastasis in abdominal malignancy. To improve the diagnostic accuracy of cytologic detection (CY) of free tumor cells (FTC) in the peritoneal cavity, we tried to quantify the FTC to leukocyte ratio using flow cytometry in patients with peritoneal metastasis.

Optimal drug delivery for intraperitoneal paclitaxel (PTX) in murine model

Abstract Background Repeated intraperitoneal (IP) administration of paclitaxel (PTX) with concurrent systemic chemotherapy is clinically effective for the treatment of peritoneal metastases (PM) from gastric cancer. However, it is unclear how biochemical modifications may affect the pharmacokinetics and bioavailability of IP administered PTX. Methods In a xenograft PM model using human gastric cancer cells, MKN45, fluorescein-conjugated PTX (OG-PTX) was given IP and the intra-tumor distribution of PTX examined with fluorescein microscopy. Results After IP injection, PTX was seen to directly infiltrate up to several hundred micrometers from the surface of the PM. Co-injection with 5 % non-animal stabilized hyaluronic acid increased PTX infiltration and suppressed the development of PM more efficiently than PTX alone. PTX solubilized with amphiphilic polymer composed of 2-methacryloyloxyethyl phosphorylcholine (MPC) and n-butyl methacrylate (BMA) efficiently formed a micellar formation 50–100 nm in diameter. IP injection of the nanomicellar PTX (PTX-30W) also showed significantly enhanced tumor infiltration and further inhibition of the growth of PM compared with PTX solubilized with Cremophor–ethanol (PTX-Cre). Finally, IP administration of NK105, another nanomicellar PTX, inhibited the growth of subcutaneous tumors as well as PM, compared with conventional PTX-Cre in the same murine model. Conclusions PTX administered IP directly infiltrates PM and are thus a useful strategy for the treatment of PM. Drug modification with nanotechnology may further enhance penetration of PM resulting in improved clinical efficacy.