Given the bulky nature of nanotherapeutics relative to small molecules, it is hypothesized that effective tumor delivery and penetration are critical barriers to their clinical activity. HER2-targeted PEGylated liposomal doxorubicin (MM-302, HER2-tPLD) is an antibody–liposomal drug conjugate designed to deliver doxorubicin to HER2-overexpressing cancer cells while limiting uptake into nontarget cells. In this work, we demonstrate that the administration and appropriate dose sequencing of cyclophosphamide can improve subsequent MM-302 delivery and enhance antitumor activity in preclinical models without negatively affecting nontarget tissues, such as the heart and skin. We demonstrate that this effect is critically dependent on the timing of cyclophosphamide administration. Furthermore, the effect was found to be unique to cyclophosphamide and related analogues, and not shared by other agents, such as taxanes or eribulin, under the conditions examined. Analysis of the cyclophosphamide-treated tumors suggests that the mechanism for improved MM-302 delivery involves the induction of tumor cell apoptosis, reduction of overall tumor cell density, substantial lowering of interstitial fluid pressure, and increasing vascular perfusion. The novel dosing strategy for cyclophosphamide described herein is readily translatable to standard clinical regimens, represents a potentially significant advance in addressing the drug delivery challenge, and may have broad applicability for nanomedicines. This work formed the basis for clinical evaluation of cyclophosphamide for improving liposome deposition as part of an ongoing phase I clinical trial of MM-302 in HER2-positive metastatic breast cancer. Mol Cancer Ther; 14(9); 2060–71. ©2015 AACR.

Effective delivery of drugs to tumors is limited by distinctive features of the tumor pathophysiology. Tumor growth is supported by a rapidly growing, hyperpermeable vasculature, with blood flow abnormalities due to compression by the surrounding tumor cells (1, 2). The hyperpermeability is advantageous for nanoparticle delivery (including liposomes) because it allows passive accumulation of nanoparticles in the tumor through the enhanced permeability and retention (EPR) effect (3). However, the extravasation of fluids/proteins from the leaky vasculature leads to elevation of the colloid osmotic pressure within the interstitium, a situation that is further exacerbated by the absence of functional lymphatics (4, 5). As a result, the interstitial fluid pressure (IFP) increases within tumors (6–8), counteracts drug extravasation, and limits the convection process, on which efficient tumor penetration of high-molecular-weight drugs depends (2, 9–11).

Normalization of the tumor vasculature with antiangiogenic agents has been shown to reduce IFP and improve the activity of concomitant chemotherapy, both in preclinical tumor xenograft models and in patients with metastatic rectal cancer (12–14). However, vascular normalization is not suitable to improve delivery of nanoparticles, likely because it decreases vascular leakage, thus compromising the EPR effect. The dual VEGF and PDGF receptor inhibitor pazopanib, while decreasing IFP and microvessel density within tumors, does not significantly affect overall accumulation of PEGylated liposomal doxorubicin (PLD) within tumors and compromises the penetration of PLD away from tumor blood vessels (15). Similarly, normalization of tumor blood vessels with the anti-VEGFR2 antibody, DC101, increases the tumor delivery of small nanoparticles (∼12-nm diameter) but reduces the delivery of large nanoparticles (∼125-nm diameter) and has no effect on the antitumor activity of the ∼100-nm diameter PLD (16). Targeting of the stroma and extracellular matrix was proven to be a more effective strategy for improving delivery and distribution of nanomedicines to tumors. Reduction of collagen content by blockade of TGFβ signaling, matrix degradation with hyaluronidase, or inhibition of hyaluronan synthesis improves the delivery and distribution of liposomal doxorubicin (17–22). Another strategy applied to improve delivery of nanomedicines to tumors has been to directly target the tumor cell mass. Uncontrolled tumor cell growth indirectly affects vasculature function by compressing and collapsing tumor blood vessels (23, 24). Treatment with taxanes, for example, results in a reduction of tumor cell mass and lowering of tumor IFP, and, as a consequence, increases PLD accumulation at the tumor site (25, 26).

Preclinical findings suggest a possible role for cyclophosphamide in altering liposome delivery, via a mechanism involving endothelial cell apoptosis (27). Cyclophosphamide is a widely used drug in breast cancer therapy and combines effectively with doxorubicin. Furthermore, recent clinical data indicate that cyclophosphamide likewise combines well with liposomal doxorubicin and trastuzumab in HER2-positive breast cancer, with observed overall response rates of about 69% and good tolerability (28, 29). Current clinical approaches suggest administration of cyclophosphamide and liposomal doxorubicin on the same day every 3 or 4 weeks for the treatment of patients with breast cancer (28–30).

In this work, we use MM-302 (HER2-targeted PEGylated liposomal doxorubicin, HER2-tPLD) as a model nanoparticle to study the effects of alternative cyclophosphamide regimens on nanoparticles delivery and antitumor activity. MM-302 is an antibody–liposomal drug conjugate engineered to selectively deliver doxorubicin to HER2-overexpressing tumor cells while sparing nontarget tissues (31–33) and is being studied in a randomized phase II trial in HER2-positive metastatic breast cancer (MBC) in combination with trastuzumab (http://clinicaltrials.gov/ct2/show/NCT02213744). The proposed mechanism of action of MM-302 includes two sequential steps: (i) extravasation from the vascular lumen into the tumor interstitium through leaky endothelium, followed by (ii) internalization in HER2-expressing cells. The extravasation step is independent of the anti-HER2 targeting moiety of MM-302. Similarly to nontargeted liposomes, MM-302 accumulates at the tumor site by passive extravasation through the EPR effect. Once MM-302 has reached the tumor interstitium, the second step occurs: HER2-mediated internalization regulates uptake into HER2-overexpressing tumor cells (33). Our studies demonstrate that cyclophosphamide, when administered in a novel predosing regimen, has a unique ability to improve the delivery and antitumor activity of MM-302. We further demonstrate a mechanism that consists of tumor debulking, lowering of IFP, and increase in vascular perfusion. In addition, cyclophosphamide effects are in contrast with observations with other chemotherapeutic agents that counterintuitively have opposite effects on MM-302 delivery under the conditions investigated.

This newly explored combination regimen of MM-302 with cyclophosphamide is currently being investigated in the clinical setting in a phase I trial (http://clinicaltrials.gov/show/NCT01304797).

Cell culture

NCI-N87 and MDA-MB-361 were purchased from the ATCC. SUM190 were purchased from Asterand. The cell lines were cultured under recommended conditions. BT474-M3 cells are an HER2-overexpressing cell line gift from Hermes Biosciences and were grown in RPMI medium containing 10% FBS and 1% penicillin G/streptomycin sulphate. The cell lines were obtained between 2008 and 2011. All cell lines, with the exception of BT474-M3, were authenticated by the respective vendor (ATCC or Asterand) before receipt, and they were propagated for less than 6 months after resuscitation.

Animal studies

Seven-week-old female NCR/nu and nu/nu nude mice were purchased from Taconic and Charles River Laboratories, respectively. The care and treatment of experimental animals were in accordance with Institutional Animal Care and Use Committee (IACUC) guidelines.

Establishment of xenografts and dosing.

To establish tumors, NCR/nu mice were inoculated with 15 × 106 BT474-M3 cells, 8 × 106 MDA-MB-361 cells, or 10 × 106 SUM190 cells into the mammary fat pad (m.f.p.). Growth of estrogen-dependent models was supported by estrogen pellet implantation. Nu/nu mice were inoculated with 5 × 106 NCI-N87 cells (s.c. into the left and right flank of the mouse). When tumor volume reached 200 to 300 mm3, mice were dosed with PBS or with cyclophosphamide [170 mg/kg, intraperitoneally (i.p.)] at the designated time points. Alternatively, ifosfamide (150 mg/kg, i.p.), paclitaxel (40 mg/kg, intravenously), or eribulin (0.45 mg/kg, i.v.) were given 7 days before HER2-tPLD (3 mg/kg doxorubicin equivalents, i.v.). Cyclophosphamide, eribulin, and ifosfamide were each dissolved in PBS. Paclitaxel was dissolved in Cremophor:ethanol (1:1) and further diluted 1:4 with PBS (final Cremophor content of 12.5%), immediately before administration. Mice were subsequently dosed intravenously with fluorescently labeled HER2-tPLD (DiI5-labeled; 3 mg/kg) or free doxorubicin (3 mg/kg), as indicated. Following liposome (24 hours) or free doxorubicin injection (30 minutes or 24 hours) and 5 minutes before sacrificing, mice received 200 μL of FITC-lectin (i.v.) to label the perfused vasculature. Immediately after sacrificing, mice were perfused with PBS to remove liposomes still in circulation.

Tumor growth inhibition.

When tumor volume (width2 × length × 0.52) reached ∼320 mm3, the mice were randomized into groups of 10 mice per group that received PBS (control), HER2-tPLD (3 mg/kg, i.v. q7d; three total doses) or cyclophosphamide (170 mg/kg, i.p. q14d). Two additional groups received a combination of cyclophosphamide (170 mg/kg, i.p.) dosed 96 hours before the first and the third doses of HER2-tPLD or a combination of cyclophosphamide (170 mg/kg, i.p.) dosed simultaneously with the first and the third doses of HER2-tPLD (3 mg/kg i.v.). Tumor growth and changes in mouse weight were monitored twice a week. Tumor growth inhibition (TGI) was calculated by subtracting the average % tumor growth of the group investigated from the average % tumor growth of the control group and then by dividing the result by the average % tumor growth of the control group.

IFP measurements within tumors.

IFP measurements were performed as described in Ozerdem U and colleagues (34). Mice were sedated with isoflurane and the tumor surface was disinfected. After pressure calibration, the tip of a catheter (SPR-320, ADInstruments, Inc.) was inserted into a sterile 18-G needle that, in turn, was inserted into the mouse tumor for IFP measurement. After insertion in the tumor mass, the needle was retracted, the pressure was allowed to equilibrate, and finally the intratumoral pressure was recorded for an average of 2 minutes with the LabChart software (ADInstruments, Inc.). IFP was measured in an average of 5 different locations per tumor.

Radiolabeling of HER2-tPLD for PET imaging

HER2-tPLD was labeled with 64Cu for positron emission tomography (PET) imaging. Detailed development and characterization of 64Cu-HER2-tPLD as a liposomal PET agent were described elsewhere (35). Briefly, 64CuCl2 was added to the chelator, 4-DEAP-ATSC, in 0.1 mol/L citrate buffer, pH 6 (∼0.35 mCi/nmol chelator) and mixed at room temperature for 1 minute. Formation of the 64Cu:4-DEAP-ATSC complex was confirmed using instant thin layer chromatography (ITLC) with chelation efficiency >98%. The 64Cu:4-DEAP-ATSC complex was then loaded into HER2-tPLD by incubating at 65°C for 10 minutes. Loading of 64Cu:4-DEAP-ATSC into HER2-tPLD was confirmed using size exclusion chromatography (SEC), at a loading efficiency of >90%.

Noninvasive PET/CT imaging of HER2-tPLD tumor deposition

BT474-M3 tumor–bearing mice were randomized into a PBS-treated group (n = 6) and a cyclophosphamide-treated group (n = 6). All mice were injected intravenously with the liposomes described below at a total lipid dose of 20 μmol/kg (3 mg/kg HER2-tPLD equivalent). At day 0, mice were injected with a trace dose of 64Cu-HER2-tPLD mixed with drug-free HER2-tPLD (20%/80% v/v, respectively) to maintain the total lipid dose and to minimize potential treatment effects (“64Cu-HER2-tPLD-trace”). At 20 hours postinjection (day 1), mice were imaged (baseline tumor deposition). On day 3, mice were injected intraperitoneally with PBS or 170 mg/kg of cyclophosphamide. On day 8, mice were injected with a full dose of 64Cu-MM-302 and were imaged 20 hours postinjection (day 9, posttreatment tumor deposition). Two weeks later (week 5), the experiment was repeated.

PET/CT image acquisition and tumor deposition quantification

PET images were acquired using a Focus 220 microPET (Siemens). PET data were reconstructed using Siemens's 3D ordered subset expectation maximization and a maximum a posteriori (OSEM3D/MAP) algorithm (with scatter and attenuation correction) with a voxel size of 0.32 × 0.32 × 0.8 mm3. Computer tomography (CT) scans were acquired using a Locus Ultra microCT (GE Healthcare) operating at 80 kVp and 50 mA and an isotropic voxel size of 154 μm. PET/CT images were registered and analyzed using the Inveon Research Workplace software (IRW, Siemens). The mean tumor deposition of 64Cu-MM-302 was measured from the contoured regions-of-interest (ROIs).

Quantification of doxorubicin within tissues

Quantification of doxorubicin within tumors, hearts, and dorsal skin was performed by high-performance liquid chromatography (HPLC) as previously described (32).

Immunofluorescence

Immediately after collection, one part of each tumor was fixed in 10% neutral-buffered formalin to generate formalin-fixed, paraffin-embedded slides (5-μm-thick). An additional tumor piece was embedded in OCT (optimal cutting temperature) compound and further processed to cryosections (10-μm-thick). Cleaved caspase-3, γ-H2AX, cleaved PARP, HER2, and cytokeratin stainings were performed as described (36). For collagen type I and CD31 stainings, slides were air-dried and fixed in 10% neutral-buffered formalin (20 minutes at room temperature). A summary of the reagents and methods is included in Supplementary Table S3. DiI5-labeled liposomes, doxorubicin and perfused vessels (FITC-lectin labeled) were imaged on unfixed frozen tumor sections on an Aperio Scanscope FL (Aperio) as described (32).

Image analysis of immunofluorescence

Images were analyzed using custom rulesets in Definiens Developer XD 2 (Definiens) as described in the Supplementary Material. The whole cross section of the individual tumors was analyzed (1 level per tumor).

Statistical analysis

The data were analyzed with the software GraphPad Prism version 6.0. Results were analyzed by a nonparametric unpaired two-tailed Student t test (Mann–Whitney). Alternatively, for the analysis of the IFP measurements, results were generated in SAS version 9.3 using a randomized block ANOVA model for pressure with treatment as a fixed effect and blocks (mice) as a random effect in the model. The data are shown as mean ± SD when not differently indicated.

Effects of cyclophosphamide on delivery of HER2-tPLD and free doxorubicin

BT474-M3 tumor–bearing mice were predosed with cyclophosphamide (170 mg/kg) 2 to 5 days before injection of HER2-tPLD or free doxorubicin (both at 3 mg/kg). The doxorubicin content within individual tumors, dorsal skin, and hearts was quantified by HPLC and expressed as percentage of injected dose per gram of tissue (% i.d./g; Fig. 1A–C). Predose with cyclophosphamide had no effect on the delivery of free doxorubicin but significantly increased (2- to 3-fold) the tumor delivery of HER2-tPLD in a dose-dependent fashion (Fig. 1A and Supplementary Fig. S1A). The predose timing was critical. Indeed, coinjection of cyclophosphamide with HER2-tPLD showed only a mild trend toward increasing delivery of HER2-tPLD to tumors (Supplementary Fig. S1B). The tumor delivery of PLD was also increased by predose with cyclophosphamide in both BT474-M3 and SUM190 tumors (Supplementary Fig. S1C and S1D). Pharmacokinetic studies confirmed that the increase in HER2 t-PLD tumor delivery was not a result of a delay of HER2 t-PLD blood clearance (Supplementary Fig. S1E). Importantly, the increase in delivery of HER2-tPLD was tumor-specific, as no change in doxorubicin deposition was detected in dorsal skin or heart tissue (Fig. 1B and C).

The ratios of %i.d./g tissue in matched tumors and heart tissues were calculated for HER2-tPLD (24 hours) and free doxorubicin (30 minutes). The 30-minute time point was chosen for free doxorubicin because, whereas the levels of free doxorubicin in tumors are similar at 30 minutes and 24 hours, the 30-minute time point is a better representative of the peak delivery of free doxorubicin to the heart tissue (32). Predosing with cyclophosphamide resulted in a significant improvement in the tumor:heart delivery ratio for HER2-tPLD (Fig. 1D). Conversely, the tumor:heart delivery ratio remained unchanged for free doxorubicin (Fig. 1D).

Effects of multiple cycles of cyclophosphamide treatment on intra-animal tumor deposition

PET/CT imaging studies were performed to monitor cyclophosphamide-induced changes in 64Cu-HER2-tPLD deposition within an individual tumor as described in Fig. 2A. BT474-M3 tumor–bearing mice were injected with “64Cu-HER2-tPLD-trace,” containing trace amounts of doxorubicin to minimize effects on the tumor microenvironment. Baseline deposition of HER2-tPLD was assessed by PET/CT imaging 20 hours post-liposome injection (day 1). Subsequently (day 3), mice received either PBS (control group, n = 5) or a single dose of cyclophosphamide (170 mg/kg, n = 6), and changes in deposition relative to day 1 were recorded by PET/CT scans on day 9, 20 hours after injection of 64Cu-HER2-tPLD (end of cycle 1). After a washout period of about 2 weeks, the above was repeated for a second cycle of PBS or cyclophosphamide treatment. Maximum intensity projection (MIP) and axial views of representative mice of both groups for weeks 1 and 2 are shown in Fig. 2B. An increase in total 64Cu-HER2-tPLD tumor deposition can be observed in the cyclophosphamide pretreated mouse at week 2 relative to week 1 but not in the PBS-treated mouse (Fig. 2B). Tumor deposition of 64Cu-MM-302 was quantified in each individual mouse by ROI analysis. Significant increases in tumor deposition at week 2 relative to week 1 and at week 6 relative to week 5 were observed in cyclophosphamide-treated mice but not in control mice (Supplementary Table S1). The percentage changes in tumor deposition at week 2 relative to week 1 (cycle 1) and at week 6 relative to week 5 (cycle 2) were calculated for the individual mice (Fig. 2C). A significant increase in tumor deposition relative to the PBS-treated group at both cycles 1 and 2 was observed in the cyclophosphamide-treated mice, indicating that the cyclophosphamide effects on HER2-tPLD deposition persist and can be detected in subsequent cycles if a predose is applied.

Cyclophosphamide-mediated changes in the tumor microenvironment

To understand the mechanism by which cyclophosphamide increases HER2-tPLD tumor delivery, BT474-M3 tumor sections were analyzed by histology. HER2-tPLD accumulation at the tumor site is driven by EPR and is minimally affected by HER2 expression (33). To rule out increased HER2-tPLD retention at the tumor site via increased HER2 expression, HER2 was quantified by staining and quantification as in (36). Cyclophosphamide did not alter HER2 expression (receptor numbers/cell; Supplementary Table S2).

To detect DNA damage/response, BT474-M3 tumors were stained with an anti-γ-H2AX antibody and images were analyzed. The extent of γ-H2AX–positive cells increased as early as 2 days post-cyclophosphamide dose, peaked at 4 days, and started to decrease 5 days post-cyclophosphamide dose (Supplementary Fig. S2A). DNA damage was accompanied by apoptosis, detected by an antibody against cleaved caspase-3 (Supplementary Fig. S2B), with a timing similar to that observed for γ-H2AX. In addition, apoptosis was also detected with an anti-cleaved PARP antibody coupled with cytokeratin staining to specifically detect apoptosis in tumor cells (cytokeratin-positive). The results showed a similar dynamics as observed for cleaved caspase-3 (Supplementary Fig. S2C). As a result of persistent tumor cell apoptosis, cyclophosphamide caused significant changes in tumor cell density relative to control tumors (Fig. 3A). Changes in interstitial space within tumors, defined as the area not occupied by any cellular component, were also quantified (Fig. 3B). Treatment with cyclophosphamide resulted in a significant increase (up to 1.6-fold) in interstitial space area.

The above effects could result in changes in IFP that ultimately could account for the improved delivery of HER2-tPLD. IFP measurements were carried out in BT474-M3 tumor–bearing mice to test this hypothesis (Fig. 3C). Treatment with cyclophosphamide (4 days) resulted in an about 36% decrease in IFP (10.6 ± 2 mmHg) compared with the control group (16.6 ± 4.7 mmHg).

Modifications of the extracellular matrix to reduce collagen deposition have been shown to significantly improve deposition of nanoparticles (4, 17, 18, 37). Cyclophosphamide however did not alter the deposition of collagen type I in BT474-M3 tumors (Supplementary Table S2).

We subsequently investigated the effects of cyclophosphamide on the vasculature of BT474-M3 tumors. Changes in microvessel density (MVD) were evaluated by CD31 immunostaining. Cyclophosphamide did not induce any changes in MVD (Supplementary Table S2). Besides MVD, the extent of vascular perfusion was quantified and expressed as percentage of FITC-lectin–positive vessels relative to the total CD31-positive vessels. Control BT474-M3 tumors showed a relatively high extent of perfusion (85.03%; Supplementary Table S2). The small blood vessels were characterized by the lowest extent of perfusion in the control tumors (64.92%) followed by the medium (85.81%) and the large blood vessels (96.52%). After cyclophosphamide treatment (4 days), an increase in perfusion was observed in all three populations with more prominent changes in the small blood vessels (15.5%), followed by the medium (3.72%) and the large blood vessels (1.61%; Fig. 3D; Supplementary Table S2).

Only cyclophosphamide and its analogue, ifosfamide, increase HER2-tPLD delivery

We next investigated whether other chemotherapeutic agents would elicit changes in HER2-tPLD delivery. The cyclophosphamide analogue, ifosfamide, and two microtubule inhibitors, paclitaxel and eribulin, were tested. BT474-M3 tumor–bearing mice (bilateral tumors) were treated with PBS or dosed with the above agents, and HER2-tPLD was subsequently administered. Tumors were collected 24 hours after HER2-tPLD injection and doxorubicin was quantified by HPLC (Fig. 4A). Ifosfamide (I) increased delivery of HER2-tPLD similarly to cyclophosphamide (∼2-fold). No changes in delivery were observed following pretreatment with eribulin (E). Surprisingly, pretreatment with paclitaxel (P) reduced delivery of HER2-tPLD. Similar results were observed with paclitaxel in an additional tumor model (Supplementary Fig. S3A). The effects of paclitaxel were driven by its vehicle Cremophor, as Cremophor alone caused a similar response. The negative effects of paclitaxel on HER2-tPLD delivery persisted for up to 3 weeks after paclitaxel administration (Supplementary Fig. S3B).

To gain insight into comparative mechanisms for the other agents tested, matched FFPE tumor sections were stained for cytokeratin to quantify tumor cell density (Fig. 4B and C). Consistent with the observations with cyclophosphamide, its analogue ifosfamide (I) also elicited a significant reduction in tumor cell density, whereas no changes were observed with paclitaxel (P). Even though eribulin (E) did not have any effects on delivery, the tumor cell density of eribulin-treated tumors was markedly reduced. However, eribulin dramatically increased stromal cells density (∼8-fold; Fig. 4D). Eribulin induced similar changes in an additional xenograft model (Supplementary Fig. S3C). Cyclophosphamide, ifosfamide, and paclitaxel had no significant effects on stromal cell density. As a consequence, the overall total cell density was significantly reduced only in the cyclophosphamide- and ifosfamide-treated tumors but not in the eribulin or paclitaxel-treated tumors (Supplementary Fig. S3D). Similarly, increases in interstitial space area were observed with both cyclophosphamide and ifosfamide, but not with eribulin and paclitaxel (Supplementary Fig. S3E).

Effects of cyclophosphamide on liposome distribution and nuclear doxorubicin

To gain information on the effects of cyclophosphamide on the intratumoral distribution of HER2-tPLD, frozen tumor sections from DiI5-HER2-tPLD–injected BT474-M3 tumors were imaged (Fig. 5A). Predose with cyclophosphamide resulted in a significant increase in DiI5-liposome signal, which was proportional to the total doxorubicin determined by HPLC in matched tumors (linear regression fit, R2 = 0.8164; Supplementary Fig. S4A). Changes in the spatial distribution of liposomes relative to the vasculature were quantified. Perfused tumor blood vessels were identified on the basis of the lectin signal and were classified into “Low Delivering” (LD) or “High Delivering” (HD) vessels based on the DiI5-liposome MFI within the vessels as described in the Supplementary Materials and Methods. The relative percentages of LD and HD vessels in the control and the cyclophosphamide-treated groups were strikingly different. The HER2-tPLD alone group consisted of a majority of LD vessels (74.5% ± 15.4%) and only 25.5% ± 15.4% of HD vessels (Fig. 5B). Conversely, in the cyclophosphamide-treated group, these relative percentages were reversed, showing 81.7% ± 11.4% of HD vessels and 18.3% ± 11.4% of LD vessels (Fig. 5B). We next quantified the DiI5-liposome MFI in vessel-concentric objects starting from the signal within the actual blood vessels up to 100 μm away from the blood vessels (Fig. 5C). Cyclophosphamide induced a significant increase of DiI5-liposome MFI at each of the distances from blood vessels analyzed.

The percentage of doxorubicin-positive nuclei at 24 hours after liposome injection was quantified (Fig. 5D). The percentage of doxorubicin-positive nuclei increased 12-fold, from 4.4% ± 4.4% to 53.7% ± 18.8% for the cyclophosphamide-treated group. The peak in doxorubicin-positive nuclei accumulation (∼30 μm away from the nearest blood vessels) was unaffected by cyclophosphamide (Supplementary Fig. S4B). However, the magnitude of doxorubicin-positive nuclei away from the vasculature was significantly increased by cyclophosphamide (Supplementary Fig. S4B).

Cyclophosphamide-induced changes in HER2-tPLD doxorubicin delivery were associated with decreases in tumor cell density and enhanced nuclear delivery of doxorubicin in additional xenograft models, SUM190 and NCI-N87 (Supplementary Fig. S5). Interestingly, when no significant changes in delivery were observed, the tumor cell density and nuclear doxorubicin were also unaffected (Supplementary Fig. S5, MDA-MB-361). The MDA-MB-361 cell line was the least sensitive to cyclophosphamide in vitro (Supplementary Fig. S5D).

Predosing of cyclophosphamide in combination with HER2-tPLD results in increased apoptosis and antitumor activity

We next investigated whether the cyclophosphamide-induced increase in nuclear delivery of doxorubicin would result in enhanced activation of downstream markers of doxorubicin-induced cytotoxicity. BT474-M3 tumor sections that were either predosed with PBS or cyclophosphamide (for 4 days) before HER2-tPLD treatment (24 hours) were stained and analyzed to determine the percentage of γ-H2AX and cleaved caspase-3–positive cells (Fig. 6A, representative fields). The HER2-tPLD and cyclophosphamide combination group induced a greater DNA damage and apoptotic response compared with both the single-agent treatment groups (Fig. 6B and C).

Finally, we investigated whether the increases in cytotoxicity in the HER2-tPLD and cyclophosphamide combination group would translate into increased antitumor activity. BT474-M3 tumor–bearing mice were dosed with PBS, HER2-tPLD alone (3 mg/kg), cyclophosphamide alone (170 mg/kg), or HER2-tPLD (3 mg/kg), and cyclophosphamide (170 mg/kg, given 4 days before HER2-tPLD; Fig. 6D). The combination group was more effective in inhibiting tumor growth than either cyclophosphamide or HER2-tPLD alone (Fig. 6D). The combination group that received cyclophosphamide before HER2-tPLD showed a significantly higher TGI than a combination group that simultaneously received HER2-tPLD and cyclophosphamide (Fig. 6E). The effects of the novel sequential combination of cyclophosphamide with HER2-tPLD on TGI were compared to that expected by Bliss independence (i.e., assuming the drugs have nonoverlapping mechanisms of action; ref. 38). TGI at day 55 was 46.6% greater-than-additive, indicating synergy between cyclophosphamide and HER2-tPLD (Supplementary Fig. S6A).

In this work, we address one of the most significant barriers to effective treatment with nanotherapeutics, namely, tumor delivery and penetration. This work is presented in the context of HER2-tPLD, an antibody–liposomal drug conjugate, currently being evaluated in a randomized phase II trial in combination with trastuzumab in HER2-positive MBC (39, 40). In this clinical context, cyclophosphamide is an important candidate among possible combination partners because of its well-established effectiveness in combination with the free drug doxorubicin for the treatment of early-stage as well as metastatic breast cancer, both in HER2-positive and in HER2-negative disease (41, 42). More recently, cyclophosphamide has also shown promising clinical responses when combined with PLD in HER2-negative patients with metastatic breast cancer (30) as well as in HER2-positive patients with metastatic breast cancer in combination with PLD and trastuzumab (28, 29).

Because of their large size, tumor delivery of nanotherapeutics, including liposomes, is restricted. This is a result of the tumor pathophysiology, characterized by elevated IFP that interferes with drug extravasation and penetration. For this reason, methods to enhance nanoparticle deposition within tumors are of great clinical value. Data presented here illustrate that, when administered in a novel “predose” regimen, cyclophosphamide significantly improved the tumor delivery of HER2-tPLD in multiple preclinical models. The effect of cyclophosphamide was specific to HER2-tPLD tumor delivery and left the delivery of free doxorubicin unaffected, suggesting that a cyclophosphamide plus HER2-tPLD combination would result in a synergistic improvement beyond that expected by the cyclophosphamide plus doxorubicin combination currently in clinical use. Importantly, the improvement in delivery was shown to be tumor-specific. Heart tissue and skin, two off-target organs of safety concern for doxorubicin as a free drug and in liposomal form, were unaffected by the predose with cyclophosphamide. The improvement in delivery of HER2-tPLD by cyclophosphamide was detected by PET/CT imaging studies on multiple subsequent cycles of treatment and was shown to translate into improved antitumor activity.

The timing of cyclophosphamide administration was critical to its activity as deposition-enhancing agent. For example, co-injection of cyclophosphamide induced a nonsignificant increase in liposome delivery. Conversely, statistically significant increases in HER2-tPLD tumor delivery were observed in multiple models when cyclophosphamide was predosed 2 to 7 days before HER2-tPLD administration. These results are consistent with our proposed mechanism of reduction of tumor cell density and lowering of IFP. Our data are in slight contrast with previous reports showing that a coinjection of cyclophosphamide was able to induce a change in delivery of liposomal doxorubicin (27). Diverse sensitivities of the tumor models to cyclophosphamide, variations in tumor volumes on the day of the experiment, and distinct administration modalities could account for the observed differences. Our results showed variable times required for the different models to respond to cyclophosphamide. BT474-M3 tumors responded quite rapidly to the cyclophosphamide treatment, with changes in delivery detectable as early as 2 days post-cyclophosphamide; other models required longer times for cyclophosphamide to exert an effect. In general, the window of activity for the predose peaked between 4 and 7 days, and it is expected that a similar timeframe may apply to human tumors.

The studies presented in this work indicate that the mechanism of the deposition enhancement of cyclophosphamide involves reduction of tumor cell density via apoptosis, lowering of IFP, and increase in interstitial space. Further support of this mechanism is the fact that in the MDA-MB-361 model, where the deposition of HER2-tPLD remained unchanged by cyclophosphamide, the tumor cell density was likewise unaffected. Of note, among all models tested, the MDA-MB-361 cell line was the least sensitive to cyclophosphamide in vitro. The alleviation of solid stress was accompanied by a modest increase in vascular perfusion, more pronounced on small blood vessel, which is in concordance with previous observations (16, 24, 43, 44).

The changes in delivery of HER2-tPLD were not mediated by changes in HER2 expression at the tumor site. Furthermore, beside HER2-tPLD, cyclophosphamide also increased delivery of PLD in the HER2-positive tumor models analyzed. Taken together, these observations support a mechanism of action for cyclophosphamide-induced changes in delivery that is independent of HER2 targeting. Hence, our data suggest that cyclophosphamide would have similar effects on HER2-tPLD or PLD also on HER2-negative models, as long as the models would respond to cyclophosphamide with the microenvironment changes described herein.

On the basis of the data thus far and proposed mechanism(s), it is likely that the effects of cyclophosphamide would extend to diverse nanoparticle types carrying different payloads (chemotherapies, siRNAs, etc.). Indeed, cyclophosphamide also increased tumor delivery of PLD. Hence, timed preadministration of cyclophosphamide may provide a general means to improve nanoparticle delivery to solid tumors.

Our analysis was expanded on other chemotherapeutic agents, well reported to have significant cell killing effects. Ifosfamide, a structural analogue of cyclophosphamide, behaved similarly to cyclophosphamide and induced a significant increase in HER2-tPLD delivery. Treatment with microtubule inhibitors, such as paclitaxel or eribulin, resulted in no increase in nanoparticle deposition in the models tested. It should be acknowledged that a portion of our data are in contrast with previously reported results that showed that paclitaxel was able to elicit a reduction in cell density and an increase in delivery of PLD (26). In our studies, using different tumor models than the one reported by Lu and colleagues (26), paclitaxel significantly reduced HER2-tPLD delivery and did not reduce tumor cell density. Importantly, the baseline delivery of HER2-tPLD was not restored up to 3 weeks following paclitaxel administration. In the two xenograft models tested, eribulin induced a nonsignificant reduction in delivery of HER2-tPLD. In both models, eribulin dramatically increased the stromal cell density, which could explain the negative trends on delivery. The observations on paclitaxel and eribulin predoses on HER2-tPLD delivery require further investigation and suggest that attention be paid in the clinical setting to the sequential dosing and timing of these agents relative to nanotherapeutics to avoid undesirable antagonism.

Platinum-based agents share with cyclophosphamide a DNA-damage mechanism, and they have been associated with high response rates when sequentially combined with PLD for the treatment of ovarian cancer (45). Ongoing research is being performed to evaluate whether an increase in HER2-tPLD or PLD delivery upon platinum-based agents treatment might be among the mechanisms underlying the high response rates in the clinic.

Delays in clearance of PLD have been observed clinically when PLD was combined with taxanes (46–48). Cyclophosphamide, particularly at high doses, is known to have also immunologic effects and therefore could alter the pharmacokinetics of subsequently administered agents. Our results indicated that cyclophosphamide had no observable effect on HER2-tPLD pharmacokinetics, thus confirming that the measured changes in delivery are associated with modifications in the tumor microenvironment, rather than with a delay in clearance of HER2-tPLD. Our data are consistent with clinical data showing that cyclophosphamide and its analogue ifosfamide have no influence on the pharmacokinetics of PLD (49, 50). In addition, the animal models used in these studies are partially immunocompromised mice, further suggesting a nonimmunologic-based mechanism of tumor deposition enhancement.

In conclusion, our data showed that carefully timed preadministration of cyclophosphamide has the unique property of enhancing HER2-tPLD delivery and subsequent antitumor activity in preclinical models. This combination strategy is readily translatable into standard clinical regimens and the clinical utility of cyclophosphamide predosing for enhancing tumor deposition of HER2-tPLD is currently being tested as part of an ongoing clinical trial. Tumor deposition, assessed by 64Cu-labeled-MM-302 and PET/CT imaging, is being measured in patients with and without pretreatment with cyclophosphamide. The extent of tumor deposition will then be related to clinical measures of response at the individual lesion and patient level.

D.A. Jaffray has received a commercial research grant from Merrimack Pharmaceuticals. V. Moyo, U.B. Nielsen, T.J. Wickham, and B.S. Hendriks have ownership interest (including patents) in Merrimack Pharmaceuticals. No potential conflicts of interest were disclosed by the other authors.

Conception and design: E. Geretti, H. Lee, C.W. Espelin, V. Moyo, U.B. Nielsen, T.J. Wickham, B.S. Hendriks

Development of methodology: E. Geretti, H. Lee, J. Zheng, D.A. Jaffray, V. Moyo, B.S. Hendriks

Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): E. Geretti, S.C. Leonard, N. Dumont, H. Lee, J. Zheng, R. De Souza

Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): E. Geretti, S.C. Leonard, N. Dumont, H. Lee, J. Zheng, R. De Souza, D.A. Jaffray

Writing, review, and/or revision of the manuscript: E. Geretti, S.C. Leonard, H. Lee, J. Zheng, C.W. Espelin, D.A. Jaffray, U.B. Nielsen, T.J. Wickham, B.S. Hendriks

Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): E. Geretti, S.C. Leonard, H. Lee, D.F. Gaddy

Study supervision: E. Geretti, H. Lee, D.A. Jaffray, T.J. Wickham

The authors thank Walid Kamoun, Jitendra Kanodia, Johanna Lahdenranta, Violette Paragas, and Joseph Reynolds for constructive discussions, Michael Dunne for technical assistance, Sergio Iadevaia and Jeffrey Kearns for assistance in data analysis, Daniel Kirouac and Ty McClure for insights into the statistical analysis, and Daryl Drummond and Dmitri Kirpotin for helpful comments.

This study was sponsored by Merrimack Pharmaceuticals.

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.
Folkman
J
. 
Tumor angiogenesis
.
Adv Cancer Res
1985
;
43
:
175
203
.
2.
Jain
RK
. 
Vascular and interstitial barriers to delivery of therapeutic agents in tumors
.
Cancer Metastasis Rev
1990
;
9
:
253
66
.
3.
Peer
D
,
Karp
JM
,
Hong
S
,
Farokhzad
OC
,
Margalit
R
,
Langer
R
. 
Nanocarriers as an emerging platform for cancer therapy
.
Nat Nanotechnol
2007
;
2
:
751
60
.
4.
Heldin
C-H
,
Rubin
K
,
Pietras
K
,
Ostman
A
. 
High interstitial fluid pressure - an obstacle in cancer therapy
.
Nat Rev Cancer
2004
;
4
:
806
13
.
5.
Padera
TP
,
Kadambi
A
,
di Tomaso
E
,
Carreira
CM
,
Brown
EB
,
Boucher
Y
, et al
Lymphatic metastasis in the absence of functional intratumor lymphatics
.
Science
2002
;
296
:
1883
6
.
6.
Boucher
Y
,
Kirkwood
JM
,
Opacic
D
,
Desantis
M
,
Jain
RK
. 
Interstitial hypertension in superficial metastatic melanomas in humans
.
Cancer Res
1991
;
51
:
6691
4
.
7.
Gutmann
R
,
Leunig
M
,
Feyh
J
,
Goetz
AE
,
Messmer
K
,
Kastenbauer
E
, et al
Interstitial hypertension in head and neck tumors in patients: correlation with tumor size
.
Cancer Res
1992
;
52
:
1993
5
.
8.
Less
JR
,
Posner
MC
,
Boucher
Y
,
Borochovitz
D
,
Wolmark
N
,
Jain
RK
. 
Interstitial hypertension in human breast and colorectal tumors
.
Cancer Res
1992
;
52
:
6371
4
.
9.
Jain
RK
. 
Transport of molecules in the tumor interstitium: a review
.
Cancer Res
1987
;
47
:
3039
51
.
10.
Chauhan
VP
,
Stylianopoulos
T
,
Boucher
Y
,
Jain
RK
. 
Delivery of molecular and nanoscale medicine to tumors: transport barriers and strategies
.
Annu Rev Chem Biomol Eng
2011
;
2
:
281
98
.
11.
Heine
M
,
Freund
B
,
Nielsen
P
,
Jung
C
,
Reimer
R
,
Hohenberg
H
, et al
High interstitial fluid pressure is associated with low tumour penetration of diagnostic monoclonal antibodies applied for molecular imaging purposes
.
PLoS One
2012
;
7
:
e36258
.
12.
Dickson
PV
,
Hamner
JB
,
Sims
TL
,
Fraga
CH
,
Ng
CYC
,
Rajasekeran
S
, et al
Bevacizumab-induced transient remodeling of the vasculature in neuroblastoma xenografts results in improved delivery and efficacy of systemically administered chemotherapy
.
Clin cancer Res
2007
;
13
:
3942
50
.
13.
Kłosowska-Wardega
A
,
Hasumi
Y
,
Burmakin
M
,
Ahgren
A
,
Stuhr
L
,
Moen
I
, et al
Combined anti-angiogenic therapy targeting PDGF and VEGF receptors lowers the interstitial fluid pressure in a murine experimental carcinoma
.
PLoS One
2009
;
4
:
e8149
.
14.
Willett
CG
,
Boucher
Y
,
di Tomaso
E
,
Duda
DG
,
Munn
LL
,
Tong
RT
, et al
Direct evidence that the VEGF-specific antibody bevacizumab has antivascular effects in human rectal cancer
.
Nat Med
2004
;
10
:
145
7
.
15.
Tailor
TD
,
Hanna
G
,
Yarmolenko
PS
,
Dreher
MR
,
Betof
AS
,
Nixon
AB
. 
Effect of pazopanib on tumor microenvironment and liposome delivery
.
Mol Cancer Ther
2010
;
159
:
1798
808
.
16.
Chauhan
VP
,
Stylianopoulos
T
,
Martin
JD
,
Popović
Z
,
Chen
O
,
Kamoun
WS
, et al
Normalization of tumour blood vessels improves the delivery of nanomedicines in a size-dependent manner
.
Nat Nanotechnol
2012
;7:3
83
8
.
17.
Diop-Frimpong
B
,
Chauhan
VP
,
Krane
S
,
Boucher
Y
,
Jain
RK
. 
Losartan inhibits collagen I synthesis and improves the distribution and efficacy of nanotherapeutics in tumors
.
PNAS
2011
;
108
:
2909
14
.
18.
Liu
J
,
Liao
S
,
Diop-Frimpong
B
,
Chen
W
,
Goel
S
,
Naxerova
K
, et al
TGF-β blockade improves the distribution and efficacy of therapeutics in breast carcinoma by normalizing the tumor stroma
.
PNAS
2012
;
109
:
16618
23
.
19.
Provenzano
PP
,
Cuevas
C
,
Chang
AE
,
Goel
VK
,
Von Hoff
DD
,
Hingorani
SR
. 
Enzymatic targeting of the stroma ablates physical barriers to treatment of pancreatic ductal adenocarcinoma
.
Cancer Cell
2012
;
21
:
418
29
.
20.
Yu
M
,
Tannock
IF
. 
Targeting tumor architecture to favor drug penetration: a new weapon to combat chemoresistance in pancreatic cancer?
Cancer Cell
2012
;
21
:
327
9
.
21.
Eikenes
L
,
Tari
M
,
Tufto
I
,
Bruland
OS
,
de Lange Davies
C
. 
Hyaluronidase induces a transcapillary pressure gradient and improves the distribution and uptake of liposomal doxorubicin (Caelyx) in human osteosarcoma xenografts
.
Br J Cancer
2005
;
93
:
81
8
.
22.
Kohli
AG
,
Kivimäe
S
,
Tiffany
MR
,
Szoka
FC
. 
Improving the distribution of Doxil® in the tumor matrix by depletion of tumor hyaluronan
.
J Control Release
2014
;
191
:
105
14
.
23.
Padera
TP
,
Stoll
BR
,
Tooredman
JB
,
Capen
D
,
di Tomaso
E
,
Jain
RK
. 
Pathology: cancer cells compress intratumour vessels
.
Nature
2004
;
427
:
695
.
24.
Stylianopoulos
T
,
Jain
RK
. 
Combining two strategies to improve perfusion and drug delivery in solid tumors
.
Proc Natl Acad Sci U S A
2013
;
110
:
18632
7
.
25.
Griffon-Etienne
G
,
Boucher
Y
,
Brekken
C
,
Suit
HD
,
Jain
RK
. 
Taxane-induced apoptosis decompresses blood vessels and lowers interstitial fluid pressure in solid tumors: clinical implications
.
Cancer Res
1999
;
59
:
3776
82
.
26.
Lu
D
,
Wientjes
MG
,
Lu
Z
,
Au
JL-S
. 
Tumor priming enhances delivery and efficacy of nanomedicines
.
J Pharmacol Exp Ther
2007
;
322
:
80
8
.
27.
Ishida
T
,
Shiraga
E
,
Kiwada
H
. 
Synergistic antitumor activity of metronomic dosing of cyclophosphamide in combination with doxorubicin-containing PEGylated liposomes in a murine solid tumor model
.
J Control Release
2009
;
134
:
194
200
.
28.
Martín
M
,
Sánchez-Rovira
P
,
Muñoz
M
,
Baena-Cañada
JM
,
Mel
JR
,
Margeli
M
, et al
Pegylated liposomal doxorubicin in combination with cyclophosphamide and trastuzumab in HER2-positive metastatic breast cancer patients: efficacy and cardiac safety from the GEICAM/2004-05 study
.
Ann Oncol
2011
;
22
:
2591
6
.
29.
Rayson
D
,
Suter
TM
,
Jackisch
C
,
van der Vegt
S
,
Bermejo
B
,
van den Bosch
J
, et al
Cardiac safety of adjuvant pegylated liposomal doxorubicin with concurrent trastuzumab: a randomized phase II trial
.
Ann Oncol
2012
;
23
:
1780
8
.
30.
Trudeau
ME
,
Clemons
MJ
,
Provencher
L
,
Panasci
L
,
Yelle
L
,
Rayson
D
, et al
Phase II multicenter trial of anthracycline rechallenge with pegylated liposomal doxorubicin plus cyclophosphamide for first-line therapy of metastatic breast cancer previously treated with adjuvant anthracyclines
.
J Clin Oncol
2009
;
27
:
5906
10
.
31.
Hendriks
BS
,
Reynolds
JG
,
Klinz
SG
,
Geretti
E
,
Lee
H
,
Leonard
SC
, et al
Multiscale kinetic modeling of liposomal doxorubicin delivery quantifies the role of tumor and drug-specific parameters in local delivery to tumors
.
CPT Pharmacometrics Syst Pharmacol
2012
;
1
:
e15
.
32.
Reynolds
JG
,
Geretti
E
,
Hendriks
BS
,
Lee
H
,
Leonard
SC
,
Klinz
SG
, et al
HER2-targeted liposomal doxorubicin displays enhanced anti-tumorigenic effects without associated cardiotoxicity
.
Toxicol Appl Pharmacol
2012
;
262
:
1
10
.
33.
Kirpotin
DB
,
Drummond
DC
,
Shao
Y
,
Shalaby
MR
,
Hong
K
,
Nielsen
UB
, et al
Antibody targeting of long-circulating lipidic nanoparticles does not increase tumor localization but does increase internalization in animal models
.
Cancer Res
2006
;
66
:
6732
40
.
34.
Ozerdem
U
,
Hargens
AR
. 
A simple method for measuring interstitial fluid pressure in cancer tissues
.
Microvasc Res
2005
;
70
:
116
20
.
35.
Lee
H
,
Zheng
J
,
Gaddy
D
,
Orcutt
KD
,
Leonard
S
,
Geretti
E
, et al
A gradient-loadable (64)Cu-chelator for quantifying tumor deposition kinetics of nanoliposomal therapeutics by positron emission tomography
.
Nanomedicine
2015
;
11
:
155
65
.
36.
Onsum
MD
,
Geretti
E
,
Paragas
V
,
Kudla
AJ
,
Moulis
SP
,
Luus
L
, et al
Single-cell quantitative HER2 measurement identifies heterogeneity and distinct subgroups within traditionally defined HER2-positive patients
.
Am J Pathol
2013
;
183
:
1446
60
.
37.
Reed
RK
,
Berg
A
,
Gjerde
EA
,
Rubin
K
. 
Control of interstitial fluid pressure: role of beta1-integrins
.
Semin Nephrol
2001
;
21
:
222
30
.
38.
Fitzgerald
JB
,
Schoeberl
B
,
Nielsen
UB
,
Sorger
PK
. 
Systems biology and combination therapy in the quest for clinical efficacy
.
Nat Chem Biol
2006
;
2
:
458
66
.
39.
Wickham
T FK
. 
A phase i study of MM-302, a HER2-targeted liposomal doxorubicin, in patients with advanced, HER2- positive breast cancer
.
J Clin Oncol
30
, 
2012
(
suppl; abstr TPS663
).
40.
Munster
P
,
Krop
IE
,
Miller
K
,
Dhindsa
N
,
Niyijiza
C
,
Nielsen
U
, et al
Assessment of safety and activity in an expanded phase 1 study of MM-302, a HER2-targeted liposomal doxorubicin, in patients with advanced HER2-positive (HER2+) breast cancer
.
San Antonio Breast Cancer Symposium, Dec 10-14, 2013
.
Poster P4-12-29 SABCS
2013
.
41.
Amos
KD
,
Adamo
B
,
Anders
CK
. 
Triple-negative breast cancer: an update on neoadjuvant clinical trials
.
Int J Breast Cancer
2012
;
2012
:
385978
.
42.
Cortazar
P
,
Justice
R
,
Johnson
J
,
Sridhara
R
,
Keegan
P
,
Pazdur
R
. 
US Food and Drug Administration approval overview in metastatic breast cancer
.
J Clin Oncol
2012
;
30
:
1705
11
.
43.
Olive
KP
,
Jacobetz
MA
,
Davidson
CJ
,
Gopinathan
A
,
McIntyre
D
,
Honess
D
, et al
Inhibition of Hedgehog signaling enhances delivery of chemotherapy in a mouse model of pancreatic cancer
.
Science
2009
;
324
:
1457
61
.
44.
Stylianopoulos
T
,
Martin
JD
,
Chauhan
VP
,
Jain
SR
,
Diop-Frimpong
B
,
Bardeesy
N
, et al
Causes, consequences, and remedies for growth-induced solid stress in murine and human tumors
.
PNAS
2012
;
109
:
15101
8
.
45.
Potamianou
A
,
Androulakis
N
,
Papakotoulas
P
,
Toufexi
H
,
Latoufis
C
,
Kouroussis
C
, et al
Sequential combination of paclitaxel-carboplatin and paclitaxel-liposomal doxorubicin as a first-line treatment in patients with ovarian cancer: a multicenter phase II trial
.
Oncology
2005
;
69
:
348
53
.
46.
Briasoulis
E
,
Karavasilis
V
,
Tzamakou
E
,
Rammou
D
,
Soulti
K
,
Piperidou
C
, et al
Interaction pharmacokinetics of pegylated liposomal doxorubicin (Caelyx) on coadministration with paclitaxel or docetaxel
.
Cancer Chemother Pharmacol
2004
;
53
:
452
7
.
47.
De la Fouchardière
C
,
Largillier
R
,
Goubely
Y
,
Hardy-Bessard
A-C
,
Slama
B
,
Cretin
J
, et al
Docetaxel and pegylated liposomal doxorubicin combination as first-line therapy for metastatic breast cancer patients: results of the phase II GINECO trial CAPYTTOLE
.
Ann Oncol
2009
;
20
:
1959
63
.
48.
Gabizon
AA
,
Shmeeda
H
,
Grenader
T
. 
Pharmacological basis of pegylated liposomal doxorubicin: impact on cancer therapy
.
Eur J Pharm Sci
2012
;
45
:
388
98
.
49.
Fan
Y
,
Lin
N
,
Luo
L
,
Fang
L
,
Huang
Z
,
Yu
H
, et al
Pharmacodynamic and pharmacokinetic study of pegylated liposomal doxorubicin combination (CCOP) chemotherapy in patients with peripheral T-cell lymphomas
.
Acta Pharmacol Sin
2011
;
32
:
408
14
.
50.
Nielsen
OS
,
Reichardt
P
,
Christensen
TB
,
Pink
D
,
Daugaard
S
,
Hermans
C
, et al
Phase 1 European Organisation for Research and Treatment of Cancer study determining safety of pegylated liposomal doxorubicin (Caelyx) in combination with ifosfamide in previously untreated adult patients with advanced or metastatic soft tissue sarcomas
.
Eur J Cancer
2006
;
42
:
2303
9
.

Supplementary data