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Antitumor Effects in Mice of Low-dose (Metronomic) Cyclophosphamide Administered Continuously through the Drinking Water¹

Sunnybrook and Women’s College Health Sciences Centre, Molecular and Cellular Biology, Departments of Medical Biophysics [S. M., G. B., G. F., S. K. G., R. S. K.] and Laboratory Medicine and Pathobiology [S. J.], University of Toronto, Toronto, Ontario, M4N 3M5 Canada; Hormone Research Institute, University of California, San Francisco, San Francisco, California 94143-0534 [D. H., G. B.]; and ImClone Systems, Inc., New York, New York 10014 [P. B., D. J. H.]

	ABSTRACT

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A number of recent preclinical studies have sparked interest in the conceptof exploiting conventional chemotherapeutic drugs as antiangiogenics. Such antiangiogenic activity is achieved or optimized by metronomic-dosing protocols in which the drug is given at comparatively low doses using a frequent schedule of administration (e.g., once to three times per week) with no breaks, particularly when combined with an endothelial cell-specific antiangiogenic drug. The use of p.o. chemotherapeutic drugs is particularly suitable for this type of treatment strategy. We tested one such drug, cyclophosphamide (CTX), in a protocol wherein the drug was administered to mice at low doses, of 10–40 mg/kg on a daily basis through the drinking water. CTX is typically given p.o. to patients, but it has almost always been injected when treating preclinical mouse tumor models. We found p.o. CTX to be a safe and convenient treatment with significant antitumor efficacy. Growth delays were observed for human orthotopic breast or ectopic colon cancer xenografts in nude or SCID mice. Established PC3 human prostate tumor xenografts could be induced to almost fully regress, remaining virtually nonpalpable for 2 months of continuous therapy, after which tumors began to grow progressively. These re-emergent tumors were not found to be drug resistant when tested in new hosts, using the same treatment protocol. Regression of spontaneously arising, late-stage pancreatic islet cell carcinomas in Rip Tag transgenic mice was also observed. The effects of continuous p.o. CTX treatment were enhanced significantly in an orthotopic, metastatic breast cancer xenograft model when used in combination with an antivascular endothelial growth factor receptor-2 blocking antibody. Maximum tolerated dose levels established for other mouse strains proved highly toxic to SCID mice, whereas daily p.o. low-dose regimens of CTX were well tolerated. Taken together, the results demonstrate the feasibility of delivering CTX in a p.o. metronomic chemotherapy regimen, which proved safe, reasonably efficacious, and potentially applicable to chronic treatment. Such a regimen may be particularly well suited for integration with antiangiogenic drugs.

	Introduction

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Conventional cytotoxic anticancer chemotherapeutic drugs were developed with the intent of treating cancer by direct killing, or inhibition of growth, of cycling tumor cells. Recently, however, there has been considerable interest in the notion of exploiting such drugs as angiogenesis inhibitors (1 , 2) . The rationale is based on the fact that virtually all classes of cancer chemotherapeutic drugs are designed to damage DNA or disrupt microtubules of dividing cells and that endothelial cell division takes place during new blood vessel formation, including tumor angiogenesis (3 , 4) . Moreover, for reasons that are unclear, cycling endothelial cells may actually be more sensitive to certain chemotherapeutic drugs than other types of normal cell or tumor cells (5, 6, 7) . Successfully targeting genetically stable, activated host endothelial cells in tumor vessels may have the advantage of a reduced susceptibility to drug resistance mechanisms driven by the types of genetic instabilities normally associated with the cancer cell genome (6 , 8 , 9) , although certain tumor cell genetic mutations may, in some cases, influence the response to antiangiogenic therapy (10) .

Browder et al. (9) reported that the potential antiangiogenic effects of a chemotherapeutic drug, such as CTX,³ may not be realized if the drug is administered in the conventional fashion, i.e., at the MTD with long rest periods (e.g., 2–3 weeks) between successive cycles of drug therapy. Such extended rest periods allow recovery of tumor endothelial cells from the damage inflicted by the chemotherapy (9) . However, by administering the drug more frequently, e.g., weekly, at lower doses (obligated to avoid myleosuppression), the recovery/repair process could be compromised, thus improving the antiangiogenic effects (9) . Indeed, mouse tumors selected for resistance to CTX in a conventional MTD schedule were nevertheless sensitive if the regimen was switched to a lower-dose, more frequent schedule (9) . This type of regimen, called "metronomic" dosing (11) , or "antiangiogenic chemotherapy" (9) , appears to have interesting precedents in the clinic (2) , e.g., significant percentages of breast or ovarian cancer patients who stopped responding to a once-every-3 week MTD taxane regimen have been reported to respond to a weekly, lower dose regimen of the same drug (reviewed in Ref. 2 ).

The effects of metronomic chemotherapy regimens can also be improved significantly by concurrent administration of a drug targeted to angiogenic endothelial cells, such as a monoclonal antibody to the VEGF R2, the small molecule TNP-470, the PEX protein fragment of MMP-2, or antibodies to endoglin (6 , 12 , 13) . These observations suggest a logic for integrating chemotherapy with antiangiogenic drugs so as to improve efficacy while circumventing the acute undesirable toxic side effects associated with standard or high-dose chemotherapy.

Interest in assessing low-dose metronomic chemotherapy regimens in the clinic (14) has also been stimulated by the availability of a number of p.o. chemotherapy drugs, such as CTX, along with some encouraging preliminary clinical trial results using such drugs, e.g., methotrexate, plus CTX (15) . Given the recent results of several preclinical metronomic chemotherapy studies in which drugs, such as CTX (9 , 13 , 16) , vinblastine (6) , taxol (7) , cisplatinum (7) , etoposide (12) , or carboplatin (12) , and topotecan (17) were administered by injection once to three times a week, we asked whether a p.o. drug in humans, such as CTX, can be chronically and safely administered in a similar (if not more frequent) but more convenient basis in mice, namely p.o., through drinking water. We report here that p.o. delivery is indeed possible, even in SCID mice, which are hypersensitive to the toxic effects of standard dosing schedules of CTX, and show that the effects of such a regimen can be improved by concurrent administration of an antiangiogenic drug, namely the anti-VEGF R2 antibody, DC101.

	Materials and Methods

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Tumor Cell Lines, Tumors, and Animals
The PC-3 human prostate and HT-29 human colon cancer cell lines were purchased from American Type Culture Collection (Rockville, MD). The WM115 and WM 239a human melanoma cell lines were obtained from Dr. Meenhard Herlyn. MDA-MB 231 is a human breast cancer cell line that was originally obtained from Dr. Jeff Lemontt (Genzyme Corp.), whereas MDA-MB 435, also a human breast cancer line, was originally obtained from Dr. Dalia Cohen (Novartis, East Hanover, NJ). HT-29 and MDA-MB 435 were transfected with pCleo-hCG (a gift from Dr. Bert Vogelstein, Johns Hopkins, Baltimore, MD) to generate HT-29hCG20 and 435hCG17. The pCleo-hCG gene expression construct was used to generate cell lines that secrete the ß-subunit of hCG, which can be used as a soluble surrogate marker of tumor burden (18) . WM115, WM239a, and MDA-MB 231 were maintained in tissue culture in RPMI 1640 supplemented with 5% FBS, and the other cell lines were grown in DMEM supplemented with 5% FBS. All cell lines were grown as monolayer cultures to 75% confluence, detached, made into single cell suspensions using 0.05% trypsin-EDTA (Invitrogen Canada, Inc., Burlington, Ontario, Canada), and washed once with complete medium and twice with FBS-free medium. Cells were counted and adjusted to the appropriate concentration for injection.

Male or female CB-17 SCID mice and NIH Swiss nude mice were purchased from Taconic (German Town, NY). PC-3 and HT29hCG20 were injected s.c. in the right flank at 2 x 10⁶/0.2 ml and 5 x 10⁶/0.2 ml, respectively, of each mouse. Two million/50 µl WM115 and WM239a cells were injected subdermally in the right flank; 2 x 10⁶/50 µl MDA-MB 231 and MDA-MB-435hCG17 cells were implanted orthotopically into the mammary fat pad. After cell implantation, the mice were randomized into groups of five or six and monitored on a weekly basis for tumor growth. Perpendicular tumor diameters were measured using Vernier scale calipers, and tumor volume was calculated using the formula [(x² x y)/2] for an ellipsoid. When the primary tumor volume reached 150–200 mm³, therapy was initiated. Institutional guidelines were followed for maintenance of animals and end point of tumor studies.

We also studied the Rip-Tag transgenic mouse model of de novo pancreatic islet carcinogenesis, wherein the large and small T antigen oncogenes of SV40 (SV40 Tag) are targeted to pancreatic ß cells using an insulin gene’s regulatory elements (19) . Mice die of tumor burden at 13–14 weeks of age. A regression trial was performed in which therapy was initiated at week 12, as described in "Results," and elsewhere (20) .

Drugs and Therapeutic Schedules
1. Low-dose Metronomic Schedule of Continuous p.o. Administration of Cyclophosphamide.
CTX (Procytox) is manufactured in the form of a white powder by Carter-Horner, Inc. (Mississauga, Ontario, Canada) and purchased from the hospital pharmacy (Sunnybrook & Women’s College Health Sciences Centre, Toronto, Ontario, Canada); it is reconstituted as per manufacturer’s instructions to a stock concentration of 20 mg/ml by the addition of sterile distilled H₂O. The reconstituted CTX was stored at 4°C in the dark and used within the week. Mice were housed five per cage and given 200 ml of water (with/without CTX), which is changed twice per week. Each mouse is estimated to drink 1.5 ml of water/10 grams of body weight/day (21 , 22) . To achieve as close as possible a dose of 10, 20, 25, or 40 mg/kg CTX, 0.66, 1.25, 1.67, or 2.67 ml, respectively, of the stock solution were added to 200 ml of water. Control mice are given an equivalent volume of normal saline in their drinking water because this is the only nonmedicinal ingredient in the powder. Weight loss was used as a parameter for toxicity; the mice were weighed once per week to determine any toxic effect of the drug. An estimated dose between 20 and 25 mg/kg/day was used in most experiments, whereas doses of 10 or 40 mg/kg/day were used in others.

2. Standard Therapy with CTX.
The schedule was a 21-day cycle of either 100 or 150 mg/kg CTX, administered i.p. once every other day over 6 days (i.e., three injections), followed by 2 weeks of rest (9) .

3. Administration of DC101 monoclonal anti-VEGF R2/flk-1 Antibody.
DC101 is a neutralizing monoclonal antibody against the mouse VEGF R2 (flk-1) (6) . The DC101 was administered at 800 µg/mouse i.p. twice per week.

Transfection.
The method of assessing the tumor burden in vivo through measurement of urinary ß-hCG by Shih (18) was adapted to independently verify the tumor volume as measured by using Vernier scale calipers. HT-29 and MDA-MB 435 cells were transfected with the pClneo-hCG and selected with neomycin. Medium was collected from individual clones and measured for hCG expression using the PATHOZYME-free ß-hCG measurement kit (Omega Diagnostics, Ltd., Scotland, United Kingdom).

Measurement of hCG in Mouse Urine.
Urine collection was carried out once per week at the same time that the tumors were measured. Each group of mice was placed in a "metabolic cage" lined with 96-well plates for 2 h, after which the urine in the wells were collected and pooled. The samples were stored at -80°C until the termination of the experiment when all of the samples were assayed together. The PATHOZYME-free ß-hCG kit was used to measure the amount of hCG in the samples, and a Creatinine kit (Sigma Canada) was used to normalize the hCG readings. The levels were expressed as hCG units/mg Creatinine.

Statistical Analysis.
The results (mean values ±SD) of all of the experiments were subjected to statistical analysis by ANOVA, followed by the Student-Newman-Keuls test, using the GraphPad Prism software package v. 3.0 (GraphPad Software, Inc., San Diego, CA). The level of significance was set at P < 0.05.

	Results

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When CTX was administered continuously in the drinking water of xenotransplanted female NIH Swiss nude mice carrying tumors derived from human breast (435hCG17), colon (HT-29hCG20), and melanoma (WM115 and WM239a) cell lines, significant growth delays were observed, as early as 14–21 days (P < 0.05) after initiation of therapy. The results are shown in Fig. 1A for a derivative of HT29, called HT29hCG20; the results for 435hCG17, WM115, and WM239a tumors were very similar (data not shown). The changes in tumor volume measurements were confirmed by using secreted ß-hCG in the urine as a surrogate marker of relative tumor burden (18) for HT29 colon tumor line engineered to express ß-hCG, as shown in Fig. 1B . In addition, even more impressive antitumor responses were observed for s.c. PC-3 tumors growing in male NIH Swiss nude mice (Fig. 1, C and D ); p.o. CTX produced almost complete regression of palpable tumor mass, followed by a long period (almost 60 days) of no net expansion in tumor mass during therapy, after which the tumors began to grow progressively while on therapy. When such "recurrent" tumors (e.g., the cell line called ‘00.15,5–6) were excised, cultured for two to three passages, and then reimplanted into a new group of mice, they again responded to the low-dose p.o. metronomic schedule of CTX in a manner similar to the parental PC3 cells (Fig. 1D) , suggesting that the tumor cells per se had not acquired resistance to the CTX therapy. This experiment has been repeated three times, and the results are similar.

View larger version (30K): [in this window] [in a new window]   Fig. 1. Antitumor effects of continuous low-dose (40 mg/kg/day) CTX administered through the drinking water of NIH Swiss nude mice. A, the tumor growth delay effect on established s.c. HT29 human colon carcinoma HT29hCG20 xenografts; very similar growth delay effects were noted on established MDA-MB-435 human breast cancer cell xenografts implanted orthotopically (using a dose of 25 mg/kg/day) and established WM115 and WM239 human implanted melanoma xenografts s.c. using a dose of 40 mg/kg/day (data not shown). B, noninvasive assessment of relative tumor burdens of s.c. human colon HT29hCG20 xenografts in NIH Swiss nude mice assessed by tumor volume as measured by Vernier scale calipers versus urinary ß-hCG levels. The measurement of ß-hCG is of pooled urine samples from each group of mice. C, effect of continuous low-dose CTX (25 mg/kg/day) on established s.c. PC3 human prostate cancer xenografts. The tumors fully regressed and then remained dormant (nonpalpable) for almost 2 months of continuous therapy, after which they began to relapse, around day 85. In D, when relapsing PC3 variant tumors were removed from the p.o. CTX-treated mice, established as cell lines in culture, and reinjected within 3–4 weeks into new hosts, such variants, e.g., cell line 00.15.5–6, responded to the p.o. CTX therapy in a similar fashion as the parental population, suggesting the tumor cells are not stable drug-resistant subpopulations.

View larger version (34K): [in this window] [in a new window]   Fig. 2. Top, the response of established orthotopic MDA-MB-231 breast tumor xenografts to contrasting CTX therapy regimens. CTX 25 mg/kg refers to a continuous low-dose p.o. (administered via the drinking water) regimen. Mice were sacrificed at day 70. CTX 150 mg/kg refers to a MTD regimen in which CTX was injected i.p. every other day over 6 days for a total dose of 450 mg/kg/cycle therapy. Vertical arrows below the middle panel, the time of injections. This panel also shows body weight of tumor-bearing control and CTX-treated mice. Note the rapid decline in body weight is the group treated with the 450 mg/kg/cycle (150 mg/kg/injection) CTX. Bottom panel, the efforts of a p.o. low-dose CTX regimen at 20 mg/kg/day versus an MTD regimen consisting of 100 mg/kg/injection (300 mg/kg/cycle) MTD CTX therapy. Three injections (vertical arrowheads) comprised one cycle of therapy, which was followed by a 2-week rest period. DC101, the DC101 anti-VEGF R2 antibody treatment, which was administered twice a week at a dose of 800 µg/mouse. All mice in the MTD CTX + DC101 group died between days 82 and 100. In contrast, all mice in the low-dose + DC101 treatment group were alive at day 120. Thus, prolongation of survival was maximal in the low-dose CTX + DC101 treatment group. These mice were also found to be largely free of lymph node, lung, and liver metastases, in contrast to the other treatment groups and control.4

Finally, we also found the p.o. CTX protocol in this case, used at 10 mg/kg/day, caused modest regressions of spontaneously arising pancreatic islet tumors in Rip-Tag transgenic mice (Fig. 3) . Treatment was initiated when mice were 12 weeks of age, i.e., a so-called "regression trial" of advanced stage tumors (20) . Mice normally die by weeks 13–14. As shown in Fig. 3 , tumors were smaller at week 16 than at week 12. Half the treated mice were still alive at week 16, whereas all sham-treated mice were dead by 14 weeks. For comparison, a low-dose vinblastine protocol (6) was also evaluated, demonstrating no such efficacy.

View larger version (21K): [in this window] [in a new window]   Fig. 3. Regression trial (20) of continuous p.o. CTX (10 mg/kg/day), administered through the drinking water or vinblastine injected every 3 days at 1.5 mg/m2, as described previously (6) in transgenic mice developing pancreatic islet cell carcinomas (19) . Therapy was initiated when mice reached 12 weeks of age. Untreated mice died by week 16. The p.o. CTX protocol induced tumor regressions. Both the p.o. CTX and injected vinblastine protocols caused prolongation of survival of similar magnitude (data not shown).

	Discussion

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The results we obtained are encouraging in several respects. The antitumor efficacy results were obvious, ranging from significant tumor growth delays and prolongation of survival to actual regressions of established s.c. (ectopic), transplanted tumors (e.g., the PC3 prostate carcinoma), or spontaneous pancreatic islet cell tumors arising in Rip Tag transgenic mice. Furthermore, the antitumor effects were not restricted to ectopic (s.c.) growing primary tumors. Thus, orthotopic human breast cancers (and the resultant distant lung and liver metastases in such mice) were affected by the daily p.o. low-dose CTX therapy. Toxic side effects, such as loss of body weight, were not apparent, even when the drug was ingested every day for 3 months in SCID mice, despite the fact that these mice appear to be so sensitive to the same drug given the MTDs for other strains of mice (e.g., 450 mg/cycle) they died within a week.

An obvious experimental drawback of p.o. drugs given by the drinking water to mice, as opposed to gavaging, is that the exact amounts of drug the animals receive are not known. Estimates of drug dose are based on the average daily amount of water (3 ml for a 20-gram mouse) that mice normally drink. Pyruvate kinase studies to examine levels of CTX pro-drug and its active toxic metabolites 4-hydroperoxycyclophosphamide and acrolein (23, 24, 25) are under way. Although CTX could be detected, the levels of the active metabolites were below the limit of detection of the assay.⁵

An important question raised by our results is whether the metronomic cyclophosphamide protocol we tested is specifically antiangiogenic, and if so, whether this property accounts for all the antitumor activity observed. We have recently obtained evidence using the Matrigel perfusion assay (6) that the oral cyclophosphamide schedule can suppress angiogenesis.⁶ However, it is unclear whether the chronic CTX regimen affects tumor cell growth/survival directly. We are currently addressing this issue in our ongoing studies. Also noteworthy is our observation regarding PC3 tumors, which began to grow again after an initial regression and a prolonged period of no net tumor growth. This could be interpreted as a developing form of tumor cell resistance against CTX. However, our finding that these tumors, when passaged and reimplanted into new host mice, show no sign of acquired resistance, may be an indication of an CTX-altered host mechanism such as altered drug metabolism by host liver enzymes (16) . Alternatively, the susceptibility of endothelial cells may be affected by prolonged exposure to CTX, resulting in a reduced antiangiogenic effect of CTX. It should be noted that there is no direct experimental evidence for either of these possibilities. Nevertheless, this phenomenon of apparent resistance to CTX deserves further study.

Similar to our results published previously (6) , as recently confirmed by others (12 , 13 , 17) , we found that the addition of an antiangiogenic drug, DC101, to the low-dose p.o. cyclophosphamide protocol significantly increased antitumor efficacy and prolonged survival in an orthotopic breast cancer model. We are currently extending the p.o. CTX regimen to tumor cell lines preselected for high levels of acquired cyclophosphamide resistance and using quantitative assays to measure changes in metastatic tumor burden, such as the ß-hCG method described by Shih et al. (18) , as confirmed in this paper (Fig. 1B) .

In summary, chronic administration of cyclophosphamide at low doses on a daily basis through the drinking water of mice appears to be a relatively safe and efficacious form of low-dose metronomic therapy. It will be of interest to determine whether other p.o. chemotherapeutic drugs can be similarly efficacious when delivered in comparable fashion, using nontoxic metronomic dosing schedules, especially in combination with other classes of antiangiogenic drugs. Finally, further delineation of the target cells of metronomic chemotherapy will be important, as there is prospect that such regimens are targeting multiple cell types of tumors (26) , including endothelial cells and drug-sensitive tumor cells, as well as other constituents that contribute to the tumor phenotype.

	FOOTNOTES

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Supported primarily by a grant (to R. S. K.) from the NIH, National Cancer Institute, Bethesda, MD (ROI-CA-41233), and a contract from ImClone Systems, Inc., New York, NY. Guido Bocci is financially supported by international scholarships of the Italian Society of Pharmacology and of the Interdepartmental Centre of Clinical Pharmacology and Experimental Therapeutics, University of Pisa, Pisa, Italy, generously donated by the Ente Cassa di Risparmio di Lucca.

² To whom requests for reprints should be addressed, at Sunnybrook and Women’s College, Health Sciences Centre, S-218, 2075 Bayview Avenue, University of Toronto, Toronto, Ontario, M4N 3M5 Canada. Phone: (416) 480-5711; Fax: (416) 480-5703; E-mail: Robert.Kerbel{at}swchsc.on.ca

³ The abbreviations used are: CTX, cyclophosphamide; MTD, maximum tolerated dose; VEGF R2, vascular endothelial cell growth factor, type 2 receptor; hCG, human chorionic gonadotropin; FBS, fetal bovine serum; p.o., per os (oral).

⁴ S. Man et al., unpublished observations.

⁵ S. Ludeman and M. Colvin, unpublished observations.

⁶ S. Man and R. S. Kerbel, unpublished observations.

Received 12/19/01. Accepted 4/ 1/02.

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				J. Ma and D. J. Waxman Collaboration between hepatic and intratumoral prodrug activation in a P450 prodrug-activation gene therapy model for cancer treatment Mol. Cancer Ther., November 1, 2007; 6(11): 2879 - 2890. [Abstract] [Full Text] [PDF]

				K. M. Bell-McGuinn, A. L. Garfall, M. Bogyo, D. Hanahan, and J. A. Joyce Inhibition of Cysteine Cathepsin Protease Activity Enhances Chemotherapy Regimens by Decreasing Tumor Growth and Invasiveness in a Mouse Model of Multistage Cancer Cancer Res., August 1, 2007; 67(15): 7378 - 7385. [Abstract] [Full Text] [PDF]

				U. Emmenegger, Y. Shaked, S. Man, G. Bocci, I. Spasojevic, G. Francia, A. Kouri, R. Coke, W. Cruz-Munoz, S. M. Ludeman, et al. Pharmacodynamic and pharmacokinetic study of chronic low-dose metronomic cyclophosphamide therapy in mice Mol. Cancer Ther., August 1, 2007; 6(8): 2280 - 2289. [Abstract] [Full Text] [PDF]

				S. Kesari, D. Schiff, L. Doherty, D. C. Gigas, T. T. Batchelor, A. Muzikansky, A. O'Neill, J. Drappatz, A. S. Chen-Plotkin, N. Ramakrishna, et al. Phase II study of metronomic chemotherapy for recurrent malignant gliomas in adults Neuro-oncol, July 1, 2007; 9(3): 354 - 363. [Abstract] [Full Text] [PDF]

				C. Folkins, S. Man, P. Xu, Y. Shaked, D. J. Hicklin, and R. S. Kerbel Anticancer Therapies Combining Antiangiogenic and Tumor Cell Cytotoxic Effects Reduce the Tumor Stem-Like Cell Fraction in Glioma Xenograft Tumors Cancer Res., April 15, 2007; 67(8): 3560 - 3564. [Abstract] [Full Text] [PDF]

				G. Giaccone The Potential of Antiangiogenic Therapy in Non-Small Cell Lung Cancer Clin. Cancer Res., April 1, 2007; 13(7): 1961 - 1970. [Abstract] [Full Text] [PDF]

				A. A. Kamat, T. J. Kim, C. N. Landen Jr., C. Lu, L. Y. Han, Y. G. Lin, W. M. Merritt, P. H. Thaker, D. M. Gershenson, F. Z. Bischoff, et al. Metronomic Chemotherapy Enhances the Efficacy of Antivascular Therapy in Ovarian Cancer Cancer Res., January 1, 2007; 67(1): 281 - 288. [Abstract] [Full Text] [PDF]

				M. F. McCarty and K. I. Block Preadministration of High-Dose Salicylates, Suppressors of NF-{kappa}B Activation, May Increase the Chemosensitivity of Many Cancers: An Example of Proapoptotic Signal Modulation Therapy. Integr Cancer Ther, September 1, 2006; 5(3): 252 - 268. [Abstract] [PDF]

				R. Buckstein, R. S. Kerbel, Y. Shaked, R. Nayar, C. Foden, R. Turner, C. R. Lee, D. Taylor, L. Zhang, S. Man, et al. High-Dose Celecoxib and Metronomic "Low-dose" Cyclophosphamide Is an Effective and Safe Therapy in Patients with Relapsed and Refractory Aggressive Histology Non-Hodgkin's Lymphoma Clin. Cancer Res., September 1, 2006; 12(17): 5190 - 5198. [Abstract] [Full Text] [PDF]

				P. Mancuso, M. Colleoni, A. Calleri, L. Orlando, P. Maisonneuve, G. Pruneri, A. Agliano, A. Goldhirsch, Y. Shaked, R. S. Kerbel, et al. Circulating endothelial-cell kinetics and viability predict survival in breast cancer patients receiving metronomic chemotherapy Blood, July 15, 2006; 108(2): 452 - 459. [Abstract] [Full Text] [PDF]

				R. Saito, M. T. Krauze, C. O. Noble, D. C. Drummond, D. B. Kirpotin, M. S. Berger, J. W. Park, and K. S. Bankiewicz Convection-enhanced delivery of Ls-TPT enables an effective, continuous, low-dose chemotherapy against malignant glioma xenograft model Neuro-oncol, July 1, 2006; 8(3): 205 - 214. [Abstract] [Full Text] [PDF]

				S.-J. Kim, H. Uehara, S. Yazici, J. E. Busby, T. Nakamura, J. He, M. Maya, C. Logothetis, P. Mathew, X. Wang, et al. Targeting platelet-derived growth factor receptor on endothelial cells of multidrug-resistant prostate cancer. J Natl Cancer Inst, June 7, 2006; 98(11): 783 - 793. [Abstract] [Full Text] [PDF]

				M. F. McCarty and K. I. Block Toward a core nutraceutical program for cancer management. Integr Cancer Ther, June 1, 2006; 5(2): 150 - 171. [Abstract] [PDF]

				S. D. Young, M. Whissell, J. C.S. Noble, P. O. Cano, P. G. Lopez, and C. J. Germond Phase II Clinical Trial Results Involving Treatment with Low-Dose Daily Oral Cyclophosphamide, Weekly Vinblastine, and Rofecoxib in Patients with Advanced Solid Tumors. Clin. Cancer Res., May 15, 2006; 12(10): 3092 - 3098. [Abstract] [Full Text] [PDF]

				R. Munoz, S. Man, Y. Shaked, C. R. Lee, J. Wong, G. Francia, and R. S. Kerbel Highly Efficacious Nontoxic Preclinical Treatment for Advanced Metastatic Breast Cancer Using Combination Oral UFT-Cyclophosphamide Metronomic Chemotherapy. Cancer Res., April 1, 2006; 66(7): 3386 - 3391. [Abstract] [Full Text] [PDF]

				M. Franco, S. Man, L. Chen, U. Emmenegger, Y. Shaked, A. M. Cheung, A. S. Brown, D. J. Hicklin, F. S. Foster, and R. S. Kerbel Targeted Anti-Vascular Endothelial Growth Factor Receptor-2 Therapy Leads to Short-term and Long-term Impairment of Vascular Function and Increase in Tumor Hypoxia. Cancer Res., April 1, 2006; 66(7): 3639 - 3648. [Abstract] [Full Text] [PDF]

				U. Emmenegger, G. C. Morton, G. Francia, Y. Shaked, M. Franco, A. Weinerman, S. Man, and R. S. Kerbel Low-Dose Metronomic Daily Cyclophosphamide and Weekly Tirapazamine: A Well-Tolerated Combination Regimen with Enhanced Efficacy That Exploits Tumor Hypoxia Cancer Res., February 1, 2006; 66(3): 1664 - 1674. [Abstract] [Full Text] [PDF]

				J. M. du Manoir, G. Francia, S. Man, M. Mossoba, J. A. Medin, A. Viloria-Petit, D. J. Hicklin, U. Emmenegger, and R. S. Kerbel Strategies for Delaying or Treating In vivo Acquired Resistance to Trastuzumab in Human Breast Cancer Xenografts Clin. Cancer Res., February 1, 2006; 12(3): 904 - 916. [Abstract] [Full Text] [PDF]

				K. Tsuji, K. Yamauchi, M. Yang, P. Jiang, M. Bouvet, H. Endo, Y. Kanai, K. Yamashita, A. R. Moossa, and R. M. Hoffman Dual-Color Imaging of Nuclear-Cytoplasmic Dynamics, Viability, and Proliferation of Cancer Cells in the Portal Vein Area Cancer Res., January 1, 2006; 66(1): 303 - 306. [Abstract] [Full Text] [PDF]

				Y. Shaked, U. Emmenegger, S. Man, D. Cervi, F. Bertolini, Y. Ben-David, and R. S. Kerbel Optimal biologic dose of metronomic chemotherapy regimens is associated with maximum antiangiogenic activity Blood, November 1, 2005; 106(9): 3058 - 3061. [Abstract] [Full Text] [PDF]

				G. Francia, S. K. Green, G. Bocci, S. Man, U. Emmenegger, J. M.L. Ebos, A. Weinerman, Y. Shaked, and R. S. Kerbel Down-regulation of DNA mismatch repair proteins in human and murine tumor spheroids: implications for multicellular resistance to alkylating agents Mol. Cancer Ther., October 1, 2005; 4(10): 1484 - 1494. [Abstract] [Full Text] [PDF]

				L. Hu, J. Hofmann, J. Holash, G. D. Yancopoulos, A. K. Sood, and R. B. Jaffe Vascular Endothelial Growth Factor Trap Combined with Paclitaxel Strikingly Inhibits Tumor and Ascites, Prolonging Survival in a Human Ovarian Cancer Model Clin. Cancer Res., October 1, 2005; 11(19): 6966 - 6971. [Abstract] [Full Text] [PDF]

				R. Yap, D. Veliceasa, U. Emmenegger, R. S. Kerbel, L. M. McKay, J. Henkin, and O. V. Volpert Metronomic Low-Dose Chemotherapy Boosts CD95-Dependent Antiangiogenic Effect of the Thrombospondin Peptide ABT-510: A Complementation Antiangiogenic Strategy Clin. Cancer Res., September 15, 2005; 11(18): 6678 - 6685. [Abstract] [Full Text] [PDF]

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C.-S. Chen, Y. Jounaidi, and D. J. Waxman ENANTIOSELECTIVE METABOLISM AND CYTOTOXICITY OF R-IFOSFAMIDE AND S-IFOSFAMIDE BY TUMOR CELL-EXPRESSED CYTOCHROMES P450 Drug Metab. Dispos., September 1, 2005; 33(9): 1261 - 1267. [Abstract] [Full Text] [PDF]