Glycodendrimer Nanocarriers for Direct Delivery of Fludarabine Triphosphate to Leukemic Cells: Improved Pharmacokinetics and Pharmacodynamics of Fludarabine.

Fludarabine, a nucleoside analogue antimetabolite, has complicated pharmacokinetics requiring facilitated transmembrane transport and intracellular conversion to triphosphate nucleotide form (Ara-FATP), causing it to be susceptible to emergence of drug resistance. We are testing a promising strategy to improve its clinical efficacy by direct delivery of Ara-FATP utilizing a biocompatible glycodendrimer nanocarrier system. Here, we present results of a proof-of-concept experiment in several in vitro-cultured leukemic cell lines (CCRF, THP-1, U937) using noncovalent complexes of maltose-modified poly(propyleneimine) dendrimer and fludarabine triphosphate. We show that Ara-FATP has limited cytotoxic activity toward investigated cells relative to free nucleoside (Ara-FA), but complexation with the glycodendrimer (which does not otherwise influence cellular metabolism) drastically increases its toxicity. Moreover, we show that transport via hENT1 is a limiting step in Ara-FA toxicity, while complexation with dendrimer allows Ara-FATP to kill cells even in the presence of a hENT1 inhibitor. Thus, the use of glycodendrimers for drug delivery would allow us to circumvent naturally occurring drug resistance due to decreased transporter activity. Finally, we demonstrate that complex formation does not change the advantageous multifactorial intracellular pharmacodynamics of Ara-FATP, preserving its high capability to inhibit DNA and RNA synthesis and induce apoptosis via the intrinsic pathway. In comparison to other nucleoside analogue drugs, fludarabine is hereby demonstrated to be an optimal candidate for maltose glycodendrimer-mediated drug delivery in antileukemic therapy.

Pharmacokinetics, bioavailability and effects on electrocardiographic parameters of oral fludarabine phosphate.

The pharmacokinetics, bioavailability and effects on electrocardiographic (ECG) parameters of fludarabine phosphate (2F-ara-AMP) were evaluated in adult patients with B-cell chronic lymphocytic leukemia. Patients received single doses of intravenous (IV) (25 mg/m(2), n=14) or oral (40 mg/m(2), n=42) 2F-ara-AMP. Plasma concentrations of drug and metabolites and digital 12-lead ECGs were monitored for 23 h after dosing. The dephosphorylated product fludarabine (2F-ara-A) was the principal metabolite present in the systemic circulation. Mean (+/-SD) elimination half-life did not differ significantly between IV and oral dosage groups (11.3+/-4.0 vs 9.7+/-2.0 h, p=0.053). Renal excretion was a major clearance pathway, along with transformation to a hypoxanthine metabolite 2F-ara-Hx. Estimated mean oral bioavailability of 2F-ara-A was 58%. Compared to the time-matched drug-free baseline Fridericia correction of the QT interval (QTcF), the mean QTcF change following 2F-ara-AMP did not differ from zero, and a treatment effect of >+10 and >+15 ms could be excluded following oral and IV 2F-ara-AMP, respectively. Similarly, heart rate, PR interval and QRS duration did not change following 2F-ara-AMP treatment. Thus the 25 mg/m(2) IV and 40 mg/m(2) oral doses of 2F-ara-AMP produce similar systemic exposure, and do not prolong QTcF, indicating low risk of drug induced Torsades de Pointes.

Simultaneous sustained release of fludarabine monophosphate and Gd-DTPA from an interstitial liposome depot in rats: potential for indirect monitoring of drug release by magnetic resonance imaging.

INTRODUCTION: Cytostatic depot preparations are interstitially administered for local chemotherapy and prevention of tumor recurrence. It would be of interest to monitor in patients as to when, to what extent, and exactly where, the drug is actually released. Liposomes containing a hydrophilic cytostatic and a hydrophilic contrast agent might be expected to release both agents simultaneously. If so, then drug release could be indirectly followed by monitoring contrast enhancement at the injection site. METHODS: Multivesicular liposomes containing the antimetabolite fludarabine monophosphate and the magnetic resonance imaging (MRI) contrast agent Gd-DTPA were subcutaneously injected in rats and both agents were monitored at the injection site for 6 weeks by 19F nuclear magnetic resonance spectroscopy (MRS) in vivo and contrast-enhanced 1H MRI (T1w 3D FLASH), respectively, in a 1.5-T whole-body tomograph. The MRS and MRI data were analyzed simultaneously by pharmacokinetic modeling using NONMEM. RESULTS: During an initial lag time, the amount of drug at the injection site stayed constant while the contrast-enhanced depot volume expanded beyond the volume injected. Drug amount and depot volume then decreased in parallel. Lag time and elimination half-life were 9 and 6 days, respectively, in three animals, and were about 50% shorter in another animal where the depot split into sub-depots. CONCLUSION: The preliminary data in rats suggest that simultaneous release of a hydrophilic cytostatic and a hydrophilic contrast agent from an interstitial depot can be achieved by encapsulation in liposomes. Thus, there seems to be a potential for indirect drug monitoring through imaging.

Pharmacology of fludarabine phosphate after a phase I/II trial by a loading bolus and continuous infusion in pediatric patients.

Fludarabine phosphate is a nucleotide analogue of adenine arabinoside with antitumor activity in murine and human lymphoid malignancies; it has occasional, unpredictable neurotoxicity after high dose bolus injections in adults. To avoid this toxicity, we studied a loading dose plus 5-day continuous infusion in 47 evaluable pediatric patients. Dose limiting myelosuppression was seen in children with solid tumors after a loading dose of 8 mg/m2 followed by 23.5 mg/m2/day for 5 days. In children with leukemia, no dose limiting toxicity was seen at dose level 6, consisting of a loading dose of 10 mg/m2 and an infusion of 30.5 mg/m2/day for 5 days. One complete and 3 partial remissions were seen in 26 evaluable children with acute lymphoblastic leukemia. 9-beta-D-arabinofuranosyl-2-fluoroadenine plasma concentrations and the area under the moment curve increased linearly with dose. The terminal half-life was similar, while the total body clearance was shorter than that reported for adults receiving bolus or continuous doses. Lymphoblasts isolated from 2 patients during fludarabine phosphate (9-beta-D-arabinofuranosyl-2-fluoroadenine) treatment increased their ability to convert 1-beta-D-arabinofuranosylcytosine to 1-beta-D-arabinofuranosylcytosine 5'-triphosphate by more than 10-fold. The antileukemic activity of 9-beta-D-arabinofuranosyl-2-fluoroadenine 5'-phosphate and its ability to alter the metabolism of 1-beta-D-arabinofuranosylcytosine indicate that timed combinations of these 2 agents should be tested.

Sodium-dependent and equilibrative nucleoside transport systems in L1210 mouse leukemia cells: effect of inhibitors of equilibrative systems on the content and retention of nucleosides.

The presence of 10 microM dipyridamole in incubation media of L1210/C2 cells decreased initial rates of zero-trans influx of formycin B (FB, 50 microM), a poorly metabolized inosine analogue, from 4.84 pmol/microliters cell water/s to 0.87 pmol/microliter cell water/s. However, after a 5-min interval of uptake, free FB levels in dipyridamole-treated cells were 165 pmol/microliters cell water, 2.3-fold greater than in dipyridamole-free cultures. This indicated the presence of a concentrative, dipyridamole-insensitive nucleoside transport (NT) system in L1210 cells, in addition to the equilibrative NT systems known to be expressed in these cells. The concentrative system was demonstrable only in the presence of NT inhibitors and required extracellular Na+. The presence of 8 microM 6-[(4-nitrobenzyl)thio]-9-beta-D- ribofuranosylpurine or 15 microM dilazep also induced an accumulation of free FB above steady-state levels, although of a lesser magnitude than that observed with dipyridamole. It appears that NT inhibitors induced nucleoside accumulation by inhibiting bidirectional nucleoside movements mediated by the equilibrative component of nucleoside transport in L1210/C2 cells without interfering with inward FB fluxes mediated by the Na(+)-dependent transporter. The presence of NT inhibitors also enhanced the cellular accumulation and retention of arabinosyladenine and its 5'-triphosphate in these cells. The increased cellular accumulation of 9-beta-D-arabinofuranosyladenine and 9-beta-D-arabinofuranosyladenine triphosphate by dipyridamole was associated with enhanced antiproliferative activity of 9-beta-D-arabinofuranosyladenine towards the leukemia cells.

Excellent in vivo bystander activity of fludarabine phosphate against human glioma xenografts that express the escherichia coli purine nucleoside phosphorylase gene.

Escherichia coli purine nucleoside phosphorylase (PNP) expressed in tumors converts relatively nontoxic prodrugs into membrane-permeant cytotoxic compounds with high bystander activity. In the present study, we examined tumor regressions resulting from treatment with E. coli PNP and fludarabine phosphate (F-araAMP), a clinically approved compound used in the treatment of hematologic malignancies. We tested bystander killing with an adenoviral construct expressing E. coli PNP and then more formally examined thresholds for the bystander effect, using both MuLv and lentiviral vectoring. Because of the importance of understanding the mechanism of bystander action and the limits to this anticancer strategy, we also evaluated in vivo variables related to the expression of E. coli PNP (level of E. coli PNP activity in tumors, ectopic expression in liver, percentage of tumor cells transduced in situ, and accumulation of active metabolites in tumors). Our results indicate that F-araAMP confers excellent in vivo dose-dependent inhibition of bystander tumor cells, including strong responses in subcutaneous human glioma xenografts when 95 to 97.5% of the tumor mass is composed of bystander cells. These findings define levels of E. coli PNP expression necessary for antitumor activity with F-araAMP and demonstrate new potential for a clinically approved compound in solid tumor therapy.

Fludarabine phosphate: a synthetic purine antimetabolite with significant activity against lymphoid malignancies.

Fludarabine phosphate is the 2-fluoro, 5'-monophosphate derivative of vidarabine (ara-A) with the advantages of resistance to deamination by adenosine deaminase (ADA) and improved solubility. The mechanism of cytotoxic action of the compound appears to involve metabolic conversion to the active triphosphate. Fludarabine phosphate has substantial activity against lymphoid malignancies, particularly chronic lymphocytic leukemia (CLL) and low-grade non-Hodgkin's lymphoma (NHL). Its single-agent activity in CLL appears at least comparable to those of other conventional combination regimens. Its activity in Hodgkin's disease, mycosis fungoides, and macroglobulinemia, although suggestive, needs to be further defined and clinical trials are warranted in hairy cell leukemia, prolymphocytic leukemia, and previously untreated myeloma. The compound does not appear active against most common solid tumors. Early clinical trials indicated significant myelosuppression and the potential for severe neurotoxicity. Toxicity on the currently used low-dose schedules includes transient and reversible myelosuppression, nausea and vomiting, diarrhea, somnolence/fatigue, and elevations of liver enzymes and/or serum creatinine. Possible pulmonary toxicity has been suggested in several patients. The currently used low-doses of fludarabine phosphate, even with repeated administration, are well tolerated and appear safe with a negligible risk for severe neurotoxicity. Based on its single-agent activity and tolerability, the Food and Drug Administration recently granted group C designation of the drug for the treatment of patients with refractory CLL outside the clinical trials setting. The use of fludarabine phosphate in combination regimens and its impact on the natural history of the lymphoid malignancies is yet to be determined. Fludarabine phosphate may well occupy a pivotal role in the management of CLL and low-grade NHL.

Pharmacokinetic study of single doses of oral fludarabine phosphate in patients with "low-grade" non-Hodgkin's lymphoma and B-cell chronic lymphocytic leukemia.

PURPOSE: Fludarabine phosphate (F-AMP), a purine analog, requires daily intravenous administration. A pharmacokinetic study of an oral formulation (10 mg immediate-release tablet) was undertaken in patients with "low-grade" non-Hodgkin's lymphoma and B-cell chronic lymphocytic leukemia. PATIENTS AND METHODS: Oral F-AMP was incorporated into the "conventional" treatment schedule. Single oral trial doses of 50, 70, and 90 mg of F-AMP were given on the first day of three cycles of treatment; a comparative 50-mg intravenous trial dose was given on the first day of the fourth cycle. Intravenous F-AMP (25 mg/m2) was given on days 2 to 5 at 4-week intervals. Pharmacokinetic samples taken after each trial dose were analyzed for plasma 2-fluoro-arabinofuranosyladenine (2F-ara-A) concentration (its main metabolite); area under the curve 0 to 24 hours (AUC(0-24h)) and maximum concentration (Cmax) were calculated. Eighteen patients received all three oral trial doses, and bioavailability was determined in 15 patients who completed four courses of therapy. RESULTS: Oral administration of F-AMP resulted in a dose-dependent increase in Cmax and AUC(0-24h) of 2F-ara-A and achieved an AUC(0-24h) similar to intravenous administration, although at a lower Cm. The linear increase in mean AUC(0-24h) by factors of 1.36 +/- 0.22 (mean +/- SD) and 1.72 +/- 0.31 corresponded well with the increase in oral dose from 50 to 70 mg (factor of 1.4) and 90 mg (factor of 1.8), respectively. Bioavailability (approximately 55%, with low intraindividual variation) and time to Cmax were dose independent. CONCLUSION: Oral doses of F-AMP can achieve an AUC(0-24h) of 2F-ara-A similar to intravenous administration, with dose-independent bioavailability. The tablet will greatly enhance the use of F-AMP in a palliative setting.

Population pharmacokinetic/dynamic model of lymphosuppression after fludarabine administration.

PURPOSE: Quantitative relationships between 9-ß-D-arabinofuranosyl-2-fluoroadenine (F-ara-A) concentrations and lymphosuppression have not been reported, but would be useful for regimen design. A population pharmacokinetic/pharmacodynamic model was constructed in this study using data from 41 hematopoietic cell transplant (HCT) recipients conditioned with busulfan in combination with fludarabine (total dose 120 mg/m², Protocol 1519) or with fludarabine (total dose 250 mg/m²) with rabbit antithymocyte globulin (rATG, Protocol 2041). METHODS: Individual pharmacokinetic parameters were fixed to post hoc Bayesian estimates, and circulating absolute lymphocyte counts (ALC) were obtained during the 3 weeks prior to graft infusion. A semi-physiological cell-kill model with three lymphocyte transit compartments was applied and aptly characterized the time course of suppression of circulating ALC by fludarabine administration. Drug- and system-specific parameters were estimated using a maximum likelihood expectation maximization algorithm, and the final model was qualified using an internal visual predictive check. RESULTS: The final model successfully characterized the time course and variability in ALC. Pharmacodynamic parameters exhibited considerable between subject variability (38.9-211 %). The HCT protocol was the only covariate associated with the pharmacodynamic parameters, specifically the lymphocyte kill rate, the transit rate between lymphocyte compartments, and the baseline ALC. CONCLUSIONS: This model can be used to simulate the degree of lymphosuppression for design of future fludarabine-based conditioning regimens.

Metabolism and action of fludarabine phosphate.

Fludara I.V. (fludarabine phosphate) (9-beta-D-arabinosyl-2-fluoroadenine, F-ara-A) is an adenine nucleoside analogue resistant to adenosine deaminase that shows promising therapeutic activity in the clinical treatment of lymphocytic hematologic malignancies. F-ara-A is transported into cells, where it is converted to its 5'-triphosphate (F-ara-ATP), the principal active metabolite. Deoxycytidine kinase is the enzyme responsible for the initial step of this activation metabolism. The differential transport and phosphorylation of F-ara-A and accumulation of F-ara-ATP by normal and cancer cells may constitute the metabolic basis of its positive therapeutic index. The major action of F-ara-A is the inhibition of DNA synthesis. F-ara-ATP competes with deoxyadenosine triphosphate for incorporation into the A sites of the elongating DNA strand by DNA polymerases and terminates DNA synthesis at the incorporation sites. That action is potentiated by the decrease of cellular dATP that results from inhibition of ribonucleotide reductase by F-ara-ATP. In vitro experiments demonstrated that DNA polymerase delta is able to excise the incorporated F-ara-AMP residues from DNA with its 3' to 5' exonuclease activity. The terminal incorporation of F-ara-AMP into DNA results in deletion of genetic material. That mechanism may be responsible for the observed mutagenicity of Fludara I.V., and ultimately its cytotoxic action.

A conjugate of lactosaminated poly-L-lysine with adenine arabinoside monophosphate, administered to mice by intramuscular route, accomplishes a selective delivery of the drug to the liver.

A conjugate of the antiviral agent adenine arabinoside monophosphate (ara-AMP) with a low molecular mass lactosaminated poly-L-lysine, administered to mice by i.m. route, selectively delivers the drug to the liver. In mice the conjugate is devoid of acute toxicity even at high dose (1.3 mg/g) and injected i.m. for 20 days does not induce antibodies. Moreover it is highly soluble in water; this means that a pharmacologically active dose may be administered in a small volume compatible with the i.m. route. Compared to the similar ara-AMP complex with lactosaminated albumin which must be injected intravenously, the present conjugate might assure a better compliance of patients with hepatitis B virus infection for a long lasting, liver targeted antiviral treatment.

Selective delivery to the liver of antiviral nucleoside analogs coupled to a high molecular mass lactosaminated poly-L-lysine and administered to mice by intramuscular route.

In order to obtain hepatotropic conjugates of antiviral drugs suitable for intramuscular administration, three nucleoside analogs (adenine arabinoside monophosphate, ribavirin and azidothymidine) were coupled to a high molecular mass lactosaminated poly-L-lysine. The conjugates had a high molar ratio drug/conjugate and after intramuscular administration to mice, were selectively taken up by the liver and eliminated by the kidney only in minute quantities. The high molar ratio and low renal elimination are important properties not possessed by conjugates previously prepared by using a small molecular mass lactosaminated poly-L-lysine. The conjugate with adenine arabinoside monophosphate (ara-AMP) was found to be devoid of acute toxicity for mice and in spite of its high molecular dimension (Mn = ca. 72,500) did not induce antibodies in this animal after repeated intramuscular injections. This conjugate could have two advantages over a similar complex of ara-AMP with lactosaminated human albumin currently under clinical trials for the treatment of chronic type B hepatitis which must be injected intravenously: it might provide better patient compliance since it is injectable intramuscularly and could introduce larger amounts of ara-AMP into hepatocytes due to its higher drug/carrier molar ratio.

The bioavailability of oral fludarabine phosphate is unaffected by food.

INTRODUCTION: A prospective, open and randomized, two-way crossover study was conducted to evaluate the pharmacokinetics and bioavailability of oral fludarabine phosphate when taken on a full versus an empty stomach. The effectiveness of therapy was also assessed after two cycles of treatment, four weeks apart MATERIALS AND METHODS: Patients with chronic lymphocytic leukemia or low-grade non-Hodgkin's lymphoma were randomly assigned to two groups, both of which received two cycles of treatment with 90 mg of oral fludarabine phosphate administered when either fed or fasted. Patients in Group 1 (n = 8) received oral treatment on a full stomach for the first cycle then on a fasted stomach for the second, while those in Group 2 (n = 10) received their treatment in the reverse sequence. Oral fludarabine phosphate was administered on the first day of the two study cycles and intravenous fludarabine phosphate was administered on days 3-6. RESULTS AND CONCLUSION: Of 22 patients recruited, 18 (CLL n = 10; NHL n = 8) were eligible for efficacy and safety evaluation, and 16 for bioavailability and pharmacokinetic analyses. The response to oral 2-F-ara-AMP was rapid: by two treatment cycles, 12 out of 18 patients (66.7%) had achieved partial response. Of the six patients who did not respond, five patients (27.7%) had stable disease. There was no notable difference in the rate of response between patients with B-CLL and lg-NHL. There was a marginal increase in total systemic availability of fludarabine phosphate when administered orally on a fed stomach (2-F-ara-A AUC((0-24 h)) = 3.28 +/- 1.48 microg.h/ml) compared to a fasted stomach (2-F-ara-A AUC((0-24 h)) = 3.05 +/- 1.56 microg.h/ml). Time to peak plasma concentration was slightly extended by the presence of food (2.2 +/- 1.0 versus 1.3 +/- 0.74 h) but the terminal half-life was unaffected. The minor differences in the pharmacokinetics of oral fludarabine phosphate when taken after food were not statistically significantly different and seem unlikely to be clinically relevant. The efficacy and safety data closely paralleled previous experience with the intravenous formulation.

A pilot pharmacologic biomarker study in HLA-haploidentical hematopoietic cell transplant recipients.

PURPOSE: Eleven patients diagnosed with various hematologic malignancies receiving an HLA-haploidentical hematopoietic cell transplant (HCT) participated in an ancillary biomarker trial. The goal of the trial was to evaluate potential pharmacologic biomarkers pertinent to the conditioning regimen [fludarabine monophosphate (fludarabine) and cyclophosphamide (CY)] or postgrafting immunosuppression [CY and mycophenolate mofetil (MMF)] in these patients. METHODS: We characterized the interpatient variability of nine pharmacologic biomarkers. The biomarkers evaluated were relevant to fludarabine (i.e., area under the curve (AUC) of 2-fluoro-ara-A or F-ara-A), CY (i.e., AUCs of CY and four of its metabolites), and MMF (i.e., total mycophenolic acid (MPA) AUC, unbound MPA AUC, and inosine monophosphate dehydrogenase (IMPDH) activity). RESULTS: Interpatient variability in the pharmacologic biomarkers was high. Among those related to HCT conditioning, the interpatient variability ranged from 1.5-fold (CY AUC) to 4.0-fold (AUC of carboxyethylphosphoramide mustard, a metabolite of CY). Among biomarkers evaluated as part of postgrafting immunosuppression, the interpatient variability ranged from 1.7-fold (CY AUC) to 4.9-fold (IMPDH area under the effect curve). There was a moderate correlation (R (2) = 0.441) of within-patient 4-hydroxycyclophosphamide formation clearance. CONCLUSIONS: Considerable interpatient variability exists in the pharmacokinetic and drug-specific biomarkers potentially relevant to clinical outcomes in HLA-haploidentical HCT recipients. Pharmacodynamic studies are warranted to optimize the conditioning regimen and postgrafting immunosuppression administered to HLA-haploidentical HCT recipients.

In vivo antitumor activity of intratumoral fludarabine phosphate in refractory tumors expressing E. coli purine nucleoside phosphorylase.

PURPOSE: Systemically administered fludarabine phosphate (F-araAMP) slows growth of human tumor xenografts that express Escherichia coli purine nucleoside phosphorylase (PNP). However, this treatment has been limited by the amount of F-araAMP that can be administered in vivo. The current study was designed to (1) determine whether efficacy of this overall strategy could be improved by intratumoral administration of F-araAMP, (2) test enhancement of the approach with external beam radiation, and (3) optimize recombinant adenovirus as a means to augment PNP delivery and bystander killing in vivo. METHODS: The effects of systemic or intratumoral F-araAMP in mice were investigated with human tumor xenografts (300 mg), in which 10 % of the cells expressed E. coli PNP from a lentiviral promoter. Tumors injected with an adenoviral vector expressing E. coli PNP (Ad/PNP; 2 × 10(11) viral particles, 2 times per day × 3 days) and the impact of radiotherapy on tumors treated by this approach were also studied. Radiolabeled F-araAMP was used to monitor prodrug activation in vivo. RESULTS: Intratumoral administration of F-araAMP in human tumor xenografts expressing E. coli PNP resulted in complete regressions and/or prolonged tumor inhibition. External beam radiation significantly augmented this effect. Injection of large human tumor xenografts (human glioma, nonsmall cell lung cancer, or malignant prostate tumors) with Ad/PNP followed by intratumoral F-araAMP resulted in excellent antitumor activity superior to that observed following systemic administration of prodrug. CONCLUSION: Activation of F-araAMP by E. coli PNP results in destruction of large tumor xenografts in vivo, augments radiotherapy, and promotes robust bystander killing. Our results indicate that intratumoral injection of F-araAMP leads to ablation of tumors in vivo with minimal toxicity.

High fludarabine exposure and relationship with treatment-related mortality after nonmyeloablative hematopoietic cell transplantation.

Despite its common use in nonmyeloablative preparative regimens, the pharmacokinetics of fludarabine are poorly characterized in hematopoietic cell transplantation (HCT) recipients and exposure-response relationships remain undefined. The objective of this study was to evaluate the association between plasma F-ara-A exposure, the systemically circulating moiety of fludarabine, and engraftment, acute GVHD, TRM and OS after HCT. The preparative regimen consisted of CY 50 mg/kg/day i.v. day -6; plus fludarabine 30-40 mg/m²/day i.v. on days -6 to -2 and TBI 200 cGy on day -1. F-ara-A pharmacokinetics were carried out with the first dose of fludarabine in 87 adult patients. Median (range) F-ara-A area-under-the-curve (AUC((0-∞))) was 5.0 µg h/mL (2.0-11.0), clearance 15.3 L/h (6.2-36.6), C(min) 55 ng/mL (17-166) and concentration on day(zero) 16.0 ng/mL (0.1-144.1). Despite dose reductions, patients with renal insufficiency had higher F-ara-A exposures. There was strong association between high plasma concentrations of F-ara-A and increased risk of TRM and reduced OS. Patients with an AUC((0-∞)) greater than 6.5 µg h/mL had 4.56 greater risk of TRM and significantly lower OS. These data suggest that clinical strategies are needed to optimize dosing of fludarabine to prevent overexposure and toxicity in HCT.

Lactosaminated human albumin, a hepatotropic carrier of drugs.

A selective delivery of drugs to liver can be obtained by conjugation with galactosyl terminating macromolecules. The conjugates selectively enter hepatocytes after interaction of the carrier galactose residues with the asialoglycoprotein receptor (ASGP-R) present only on these cells. Within hepatocytes the conjugates are transported to lysosomes where the drug is set free from the carrier, becoming concentrated in liver cells. The present article reviews the liver targeting of drugs obtained with lactosaminated albumin (L-SA), a neoglycoprotein exposing galactosyl residues. We report: (1) experiments which demonstrate the antiviral efficacy of the L-H(human)SA-ara-AMP conjugate in laboratory animals and in humans with viral hepatitis; (2) the property of a L-HSA conjugate with fluorodeoxyuridine to produce concentrations of the drug higher in hepatic sinusoids than in systemic circulation, with the potential of accomplishing a loco-regional, noninvasive treatment of liver micrometastases; (3) the increased anticancer activity of doxorubicin (DOXO) when coupled to L-HSA on all the forms of chemically induced rat hepatocellular carcinomas including those which do not express the ASGP-R.

Cytotoxic activity of 2-Fluoro-ara-AMP and 2-Fluoro-ara-AMP-loaded erythrocytes against human breast carcinoma cell lines.

Fludarabine phosphate (2-Fluoro-ara-AMP) is a purine analogue approved for the clinical treatment of haematological malignancies. This antimetabolite has also shown 'in vitro' antiproliferative activity against experimental models of solid mammary tumor. In this perspective, we have determined the cytotoxic effects of 2-Fluoro-ara-AMP against two human breast cancer cell lines (the ER-positive MCF-7 and the ER-negative MDA-MB-435), by adding the drug both in its free form and encapsulated into erythrocytes, as a strategy to modify the pharmacokinetic profile of the compound in order to increase its efficacy and decrease its toxicity. Similar antiproliferative activity of 2-Fluoro-ara-AMP in the two cell lines was obtained, reaching an almost complete abrogation of growth already after just 24 h of free drug exposure at all the tested doses. Meanwhile, encapsulated 2-Fluoro-ara-AMP was successfully released from erythrocytes into the culture media in a time-dependent manner with an efficacy comparable to that of the free drug treatment. This result suggests the possibility of administering 2-Fluoro-ara-AMP in patients with breast cancer using autologous erythrocytes as a system to slowly and constantly deliver 2-Fluoro-ara-A into circulation. In addition, possible mechanisms involved in the antiproliferative activity of 2-Fluoro-ara-AMP, such as the effects on cell cycle progression, p53 expression and STAT1 pathway activation in ER+ and ER- cancer cell lines, are proposed.