David J. Owen

A comparison of changes to doxorubicin pharmacokinetics, antitumor activity, and toxicity mediated by PEGylated dendrimer and PEGylated liposome drug delivery systems

UNLABELLED The pharmacokinetics, biodistribution, and antitumor efficacy of three doxorubicin formulations (doxorubicin in saline, conjugated to a polylysine dendrimer, and encapsulated within a stealth liposome) were investigated in Walker 256 tumor-bearing rats. Liposomal and dendrimer-based delivery systems resulted in more prolonged plasma exposure of total doxorubicin when compared to administration of doxorubicin in saline, although concentrations of free doxorubicin remained low in both cases. Biodistribution profiles revealed enhanced accumulation of dendrimer- and liposome-associated doxorubicin in tumors when compared to doxorubicin alone, although all three doxorubicin formulations reduced tumor growth to a similar extent. Markers of systemic toxicity (spleen weight, white blood cell counts, body weight, and cardiotoxicity) were more pronounced in rats that received doxorubicin and liposomal doxorubicin when compared to dendrimer-doxorubicin. The data provide preliminary evidence that dendrimer-doxorubicin displays similar antitumor efficacy to PEGylated liposomal doxorubicin, but with lower systemic toxicity (resulting from reduced drug exposure to nontarget organs). FROM THE CLINICAL EDITOR In this manuscript, three different doxorubicin preparations are compared and preliminary evidence suggests that dendrimer-doxorubicin displays similar antitumor efficacy to PEGylated liposomal doxorubicin, but with lower systemic toxicity.

Characterisation and tumour targeting of PEGylated polylysine dendrimers bearing doxorubicin via a pH labile linker

Polylysine dendrimers have potential as biodegradable vectors for the delivery of cytotoxic drugs to solid tumours. Here, the cytotoxicity, drug release and tumour targeting properties of Generation 5 PEGylated polylysine dendrimers comprising an outer generation of l-lysine or succinimyldipropyldiamine (SPN) and containing doxorubicin (DOX) linked through an acid labile 4-(hydrazinosulfonyl) benzoic acid (HSBA) linker have been characterised. Less than 10% of the DOX load was released from LYS or SPN dendrimers in pH 7.4 buffer over 3 days. In contrast approximately 100% release was evident at pH 5. The DOX-conjugated dendrimers also retained similar cytotoxic properties to free DOX in in vitro cell culture studies (presumably as a result of in situ liberation of free DOX). The clearance patterns of the DOX conjugated SPN and all-lysine dendrimers were similar to the equivalent non-DOX conjugated systems, however the SPN dendrimers showed reduced metabolic lability and increased uptake into RES organs when compared to the equivalent all-lysine dendrimers. In vivo assessment of the DOX-conjugated, PEGylated polylysine dendrimers (both SPN and LYS constructs) in rats bearing Walker 256 tumours revealed higher uptake into tumour tissue when compared with control tissue such as muscle (~8 fold) and heart (~3 fold). The data suggest that polylysine dendrimers containing DOX conjugated via an acid labile HSBA linker may provide a mechanism to target the delivery of DOX to tumours.

Pulmonary administration of a doxorubicin-conjugated dendrimer enhances drug exposure to lung metastases and improves cancer therapy

Direct administration of chemotherapeutic drugs to the lungs significantly enhances drug exposure to lung resident cancers and may improve chemotherapy when compared to intravenous administration. Direct inhalation of uncomplexed or unencapsulated cytotoxic drugs, however, leads to bolus release and unacceptable lung toxicity. Here, we explored the utility of a 56kDa PEGylated polylysine dendrimer, conjugated to doxorubicin, to promote the controlled and prolonged exposure of lung-resident cancers to cytotoxic drug. After intratracheal instillation to rats, approximately 60% of the dendrimer was rapidly removed from the lungs (within 24h) via mucociliary clearance and absorption into the blood. This was followed by a slower clearance phase that reflected both absorption from the lungs (bioavailability 10-13%) and biodegradation of the dendrimer scaffold. After 7days, approximately 15% of the dose remained in the lungs. A syngeneic rat model of lung metastasised breast cancer was subsequently employed to compare the anticancer activity of the dendrimer with a doxorubicin solution formulation after intravenous and pulmonary administration. Twice weekly intratracheal instillation of the dendrimer led to a >95% reduction in lung tumour burden after 2weeks in comparison to IV administration of doxorubicin solution which reduced lung tumour burden by only 30-50%. Intratracheal instillation of an equivalent dose of doxorubicin solution led to extensive lung-related toxicity and death withinseveral days of a single dose. The data suggest that PEGylated dendrimers have potential as inhalable drug delivery systems to promote the prolonged exposure of lung-resident cancers to chemotherapeutic drugs and to improve anti-cancer activity.

Capping methotrexate α-carboxyl groups enhances systemic exposure and retains the cytotoxicity of drug conjugated PEGylated polylysine dendrimers.

A generation 5 PEGylated (PEG 1100) polylysine dendrimer, conjugated via a stable amide linker to OtBu protected methotrexate (MTX), was previously shown to have a circulatory half-life of 2 days and to target solid tumors in both rats and mice. Here, we show that deprotection of MTX and substitution of the stable linker with a matrix metalloproteinase (MMP) 2 and 9 cleavable linker (PVGLIG) dramatically increased plasma clearance and promoted deposition in the liver and spleen (50-80% of the dose recovered in the liver 3 days post dose). Similar rapid clearance was also seen using a scrambled peptide suggesting that clearance was not dependent on the cleavable nature of the linker. Surprisingly, dendrimers where OtBu capped MTX was linked to the dendrimer surface via the hexapeptide linker showed equivalent in vitro cytotoxicity against HT1080 cells when compared to the uncapped dendrimer and also retained the long circulating characteristics of the stable constructs. The OtBu capped MTX conjugated dendrimer was subsequently shown to significantly reduce tumor growth in HT1080 tumor bearing mice compared to control. In contrast the equivalent dendrimer comprising uncapped MTX conjugated to the dendrimer via the same hexapeptide linker did not reduce tumor growth, presumably reflecting very rapid clearance of the construct. The results are consistent with the suggestion that protection of the α-carboxyl group of methotrexate may be used to improve the circulatory half-life and reduce the liver accumulation of similar MTX-conjugated dendrimers, while still retaining antitumor activity in vivo.

Pulmonary Administration of PEGylated Polylysine Dendrimers: Absorption from the Lung versus Retention within the Lung Is Highly Size-Dependent

The systemic delivery of drugs via the inhaled route is an attractive, needle-free means of improving the systemic exposure of molecules such as peptides and proteins that are poorly absorbed after oral administration. Directed delivery into the lungs also provides a means of increasing drug concentrations at the site of action for lung-specific disease states such as pulmonary infections and lung cancer. The current study has examined the potential utility of PEGylated polylysine dendrimers as pulmonary delivery agents and in particular sought to explore the relationship between dendrimer size and absorption of the intact construct (as a potential systemic delivery mechanism) versus retention within the lungs (as a potential pulmonary depot for controlled local release). Dendrimer absorption from the lungs was inversely correlated with molecular weight, with approximately 20-30% of the dose of relatively small (<22 kDa) dendrimers systemically absorbed compared to only 2% absorption for a larger (78 kDa) PEGylated dendrimer. Increasing the molecular weight of the dendrimers led to slower absorption and more prolonged retention in the lung tissue and bronchoalveolar lavage fluid. Oral administration of the two smaller dendrimers confirmed that oral bioavailability of the PEGylated dendrimers was essentially zero and did not contribute to exposure after pulmonary administration. The smaller PEGylated dendrimers were also degraded in the lungs to low molecular weight products that were subsequently absorbed and excreted via the urine, while the larger constructs showed good stability in the lungs. The data suggest first, that small PEGylated dendrimer-based drug delivery systems may be delivered to the blood via inhalation, providing a more attractive alternative to injections, and second that larger PEGylated dendrimers may be retained in the lungs providing the potential for controlled delivery of medications to the blood or lung tissue.

Doxorubicin-Conjugated PEGylated Dendrimers Show Similar Tumoricidal Activity but Lower Systemic Toxicity When Compared to PEGylated Liposome and Solution Formulations in Mouse and Rat Tumor Models

PEGylated polylysine dendrimers show promise as novel drug delivery systems with the potential to direct site specific deposition patterns and to reduce toxicity at nontarget sites. Here the activity and toxicity profiles of a generation 5 polylysine dendrimer with 50% surface conjugation of PEG1100 and 50% surface conjugation of doxorubicin (via an acid labile 4-hydrazinosulfonyl benzoic acid linker) have been compared in a Walker 256 rat tumor model and a human MDA-MB231 xenograft in mice. A direct comparison was also made to a PEGylated liposomal formulation of doxorubicin and a doxorubicin solution. In both rat and mouse breast cancer models, the dendrimer formulation gave equivalent antitumor efficacy when compared to the liposomal or solution doxorubicin formulations and administration of all three doxorubicin formulations resulted in a significant reduction (>75%) in tumor growth in both models at doses ranging from 2 to 10 mg/kg doxorubicin equivalents. The dendrimer formulation, however, was better tolerated by both rats and mice, and approximately 2-fold higher doses were required to induce similar levels of toxicity (as assessed by organ weight, peripheral white cell counts, body weight and survival curves) when compared to administration of the doxorubicin solution or PEGylated liposomal doxorubicin. In rats the appearance of palmar plantar erythematosis (PPE), or hand foot syndrome, was also less evident after administration of dendrimer doxorubicin when compared to the liposome. Finally, even after administration to mice at 2-fold higher doses, dendrimer-doxorubicin resulted in a reduced incidence of cardiotoxicity when compared with a simple solution formulation of doxorubicin. The data suggest that dendrimer-based doxorubicin formulations may provide advantage over solution and liposomal formulations of doxorubicin via a reduction in systemic toxicity.

PEGylated polylysine dendrimers increase lymphatic exposure to doxorubicin when compared to PEGylated liposomal and solution formulations of doxorubicin.

Improved delivery of chemotherapeutic drugs to the lymphatic system has the potential to augment outcomes for cancer therapy by enhancing activity against lymph node metastases. Uptake of small molecule chemotherapeutics into the lymphatic system, however, is limited. Nano-sized drug carriers have the potential to promote access to the lymphatics, but to this point, this has not been examined in detail. The current study therefore evaluated the lymphatic exposure of doxorubicin after subcutaneous and intravenous administration as a simple solution formulation or when formulated as a doxorubicin loaded PEGylated poly-lysine dendrimer (hydrodynamic diameter 12 nm), a PEGylated liposome (100 nm) and various pluronic micellar formulations (~5 nm) to thoracic lymph duct cannulated rats. Plasma and lymph pharmacokinetics were analysed by compartmental pharmacokinetic modelling in S-ADAPT, and Berkeley Madonna software was used to predict the lymphatic exposure of doxorubicin over an extended period of time. The micelle formulations displayed poor in vivo stability, resulting in doxorubicin profiles that were similar to that observed after administration of the doxorubicin solution formulation. In contrast, the dendrimer formulation significantly increased the recovery of doxorubicin in the thoracic lymph after both intravenous and subcutaneous dosing when compared to the solution or micellar formulation. Dendrimer-doxorubicin also resulted in increases in lymphatic doxorubicin concentrations when compared to the liposome formulation, although liposomal doxorubicin did increase lymphatic transport when compared to the solution formulation. Specifically, the dendrimer formulation increased the recovery of doxorubicin in the lymph up to 30 h post dose by up to 685 fold and 3.7 fold when compared to the solution and liposomal formulations respectively. Using the compartmental model to predict lymphatic exposure to longer time periods suggested that doxorubicin exposure to the lymphatic system would ultimately be 9796 times and 6.1 times greater after administration of dendrimer doxorubicin when compared to the solution and liposome formulations respectively. The recovery of doxorubicin in the sentinel lymph nodes draining the subcutaneous injection site was also quantified directly, and consistent with the lymph pharmacokinetic data, lymph node recovery was greatest for the dendrimer formulation (12% of dosed doxorubicin/g node) when compared to the liposome (1.4%/g node) and solution (<1%/g node) formulations. The data suggest that dendrimer-based drug delivery systems have the potential to enhance drug exposure to lymph-based drug targets such as lymphatic metastases.

Methotrexate-conjugated PEGylated dendrimers show differential patterns of deposition and activity in tumor-burdened lymph nodes after intravenous and subcutaneous administration in rats.

The current study sought to explore whether the subcutaneous administration of lymph targeted dendrimers, conjugated with a model chemotherapeutic (methotrexate, MTX), was able to enhance anticancer activity against lymph node metastases. The lymphatic pharmacokinetics and antitumor activity of PEGylated polylysine dendrimers conjugated to MTX [D-MTX(OH)] via a tumor-labile hexapeptide linker was examined in rats and compared to a similar system where MTX was α-carboxyl O-tert-butylated [D-MTX(OtBu)]. The latter has previously been shown to exhibit longer plasma circulation times. D-MTX(OtBu) was well absorbed from the subcutaneous injection site via the lymph, and 3 to 4%/g of the dose was retained by sentinel lymph nodes. In contrast, D-MTX(OH) showed limited absorption from the subcutaneous injection site, but absorption was almost exclusively via the lymph. The retention of D-MTX(OH) by sentinel lymph nodes was also significantly elevated (approximately 30% dose/g). MTX alone was not absorbed into the lymph. All dendrimers displayed lower lymph node targeting after intravenous administration. Despite significant differences in the lymph node retention of D-MTX(OH) and D-MTX(OtBu) after subcutaneous and intravenous administration, the growth of lymph node metastases was similarly inhibited. In contrast, the administration of MTX alone did not significantly reduce lymph node tumor growth. Subcutaneous administration of drug-conjugated dendrimers therefore provides an opportunity to improve drug deposition in downstream tumor-burdened lymph nodes. In this case, however, increased lymph node biodistribution did not correlate well with antitumor activity, possibly suggesting constrained drug release at the site of action.

Effect of increased surface hydrophobicity via drug conjugation on the clearance of inhaled PEGylated polylysine dendrimers

Graphical abstract Figure. No Caption available. Abstract PEGylated polylysine dendrimers are attractive and well tolerated inhalable drug delivery platforms that have the potential to control the release, absorption kinetics and lung retention time of conjugated drugs. The clinical application of these systems though, would likely require partial substitution of surface PEG groups with drug molecules that are anticipated to alter their lung clearance kinetics and clearance pathways. In the current study, we therefore evaluated the impact of increased surface hydrophobicity via substitution of 50% surface PEG groups with a model hydrophobic drug (&agr;‐carboxyl OtButylated methotrexate) on the lung clearance of a Generation 5 PEGylated polylysine dendrimer in rats. PEG substitution with OtBu‐methotrexate accelerated lung clearance of the dendrimer by increasing polylysine scaffold catabolism, improving systemic absorption of the intact dendrimer and low molecular weight products of scaffold catabolism, and enhancing mucociliary clearance. These results suggest that the conjugation of hydrophobic drug on the surface of a PEGylated dendrimer is likely to accelerate lung clearance when compared to a fully PEGylated dendrimer.

Lymphatic transport and lymph node targeting of methotrexate-conjugated PEGylated dendrimers are enhanced by reducing the length of the drug linker or masking interactions with the injection site.

Drug conjugation to dendrimer-based delivery systems has been shown to enhance delivery to the lymphatic system after subcutaneous administration. Dendrimer interaction with components of the interstitium at the injection site, however, may prevent drainage from the injection site. The current study sought to vary the length of a linker employed to conjugate methotrexate (MTX) to a PEGylated dendrimer, in an attempt to reduce MTX interaction with interstitial binding sites and enhance lymphatic drainage. Dendrimers with shorter linkers resulted in higher lymphatic drainage, presumably via shielding of interaction sites by the PEG mantle, but were not retained in lymph nodes. Improved drainage of dendrimers with longer linkers was achieved through coadministration with dextran to mask interactions at the injection site while maintaining retention within the node. Enhanced drug exposure to the lymph node has the potential to enhance the treatment of lymph-node resident cancer metastases.