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Synthesis and in vivo anticancer evaluation of poly(organo)phosphazene-based metallodrug conjugates.
Dalton
Transactions
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Cite this: Dalton Trans., 2017, 46,
12114
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Synthesis and in vivo anticancer evaluation of
poly(organo)phosphazene-based metallodrug
conjugates†
Carmen M. Hackl,‡a Beatrix Schoenhacker-Alte,‡a,b,d Matthias H. M. Klose, a
Helena Henke, c Maria S. Legina,a Michael A. Jakupec, a,d Walter Berger, b,d
Bernhard K. Keppler,a,d Oliver Brüggemann,c Ian Teasdale, c Petra Heffeter*b,d and
Wolfgang Kandioller *a,d
Within this work we aimed to improve the pharmacodynamics and toxicity profile of organoruthenium
and -rhodium complexes which had previously been found to be highly potent in vitro but showed unselective activity in vivo. Different organometallic complexes were attached to a degradable poly(organo)phosphazene macromolecule, prepared via controlled polymerization techniques. The conjugation to
hydrophilic polymers was designed to increase the aqueous solubility of the typically poorly soluble
metal-based half-sandwich compounds with the aim of a controlled, pH-triggered release of the active
metallodrug. The synthesized conjugates and their characteristics have been thoroughly studied by
means of 31P NMR and UV-Vis spectroscopy, ICP-MS analyses and SEC coupled to ICP-MS. In order to
assess their potential as possible anticancer drug candidates, the complexes, as well as their respective
macromolecular prodrug formulations were tested against three different cancer cell lines in cell culture.
Received 15th May 2017,
Accepted 4th July 2017
Subsequently, the anticancer activity and organ distribution of the poly(organo)phosphazene drug conju-
DOI: 10.1039/c7dt01767g
gates were explored in vivo in mice bearing CT-26 colon carcinoma. Our investigations revealed a
beneficial influence of this macromolecular prodrug by a significant reduction of adverse effects com-
rsc.li/dalton
pared to the free metallodrugs.
Introduction
One of the most frequent reasons for premature discontinuation of clinical trials is the occurrence of unforeseen side
effects caused by the novel drug candidates.1–3 A promising
research branch sprouting from the intention to selectively
target solid tumors makes use of the enhanced permeability
and retention (EPR) effect. This effect describes the accumulation of macromolecules by passive diffusion into tumor
tissues which are usually characterized by an abnormal vascu-
a
Institute of Inorganic Chemistry, University of Vienna, Waehringer Str. 42,
1090 Wien, Austria. E-mail: wolfgang.kandioller@univie.ac.at
b
Institute of Cancer Research and Comprehensive Cancer Center, Department of
Medicine I, Medical University of Vienna, Borschkegasse 8a, 1090 Vienna, Austria.
E-mail: petra.heffeter@meduniwien.ac.at
c
Institute of Polymer Chemistry, Johannes Kepler University Linz (JKU), Altenberger
Straße 69, 4040 Linz, Austria
d
Research Cluster “Translational Cancer Therapy Research”, University of Vienna,
Waehringer Str. 42, 1090 Wien, Austria
† Electronic supplementary information (ESI) available. See DOI: 10.1039/
c7dt01767g
‡ These authors contributed equally.
12114 | Dalton Trans., 2017, 46, 12114–12124
lature and irregular architecture of cell layers.4–6 Leakages in
the endothelial layer of capillaries permit the infiltration of
the intercellular space of tumor tissues by macromolecules,
where they are retained due to deficient lymphatic drainage.
One of the leading and most elegant strategies to exploit this
effect is based on the utilization of human serum albumin
(HSA) as a natural transport vehicle.7–9 Approval was granted
to an albumin nanoformulation of the established drug paclitaxel (trade name: Abraxane®) for the treatment of different
cancer types, with especially high responses in breast cancer
therapy.7 The fundamental role of HSA is also reflected in the
minor side-effects of the first-in-class drug candidate IT-139
(NKP-1339; sodium trans-[tetrachloridobis(1H-indazole)ruthenate(III)]), which is attributed to its high affinity for human
serum albumin. In this special case, binding occurs non-covalently at hydrophobic domains of the protein, allowing for
the attachment of more than one drug unit per HSA molecule.8
As for synthetic macromolecules, next to fulfilling certain size
requirements to utilize the EPR effect (commonly
20–200 kDa),9 a potential drug carrier has to guarantee controlled release of the active load at the biological target.10
Hence, an exclusive trigger that can initiate drug release from
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Dalton Transactions
a macromolecular prodrug under the given circumstances
must be identified. In poly(organo)phosphazenes deliberate
selection of building blocks grants extensive control over
essential characteristics such as degradation rate and aqueous
solubility.11,12 Additionally, the degradable backbone, suitable
functional groups, and the degradation into physiologically
nonhazardous metabolites satisfy several of the conditions
required for polymer therapeutics.10 As previously shown for
platinum-based anticancer drugs coupled to polyphosphazene
structures, the cellular uptake and accumulation into tumor
tissue of such macromolecular drug formulations could be
significantly increased compared to the free drug. The in vivo
evaluation of polyphosphazenes equipped with established
platinum(II) drugs capable of assembling into either micelles
or nanoparticles of suitable diameters revealed pronounced
accumulation within the tumor, while only low platinum levels
were detected in healthy tissues.13–15 Furthermore, we recently
investigated the effect of polyphosphazene conjugation with
representatives of the supposedly more inert class of PtIV prodrugs. In this work we observed a 30-fold increase in cellular
uptake and at the same time an increase in cytotoxic activity
in vitro. While PtII compounds such as cisplatin or carboplatin
reign supreme in cytotoxic activity, these polymer–drug conjugates were shown to accumulate as well in tested cisplatinresistant cell lines, where they were nevertheless able to exert
their cytotoxic effect.16 The beneficial influence of macromolecular drug delivery on the pharmaceutical efficacy has been
adopted likewise for the conjugation of promising organometallic anticancer agents and several interesting approaches
are described in the literature.17
The extensive collection of organometallic half-sandwich
complexes comprises many representatives that have been
assessed in a variety of in vitro and in vivo studies where they
exhibited great potential as cytotoxic agents.18–20 The assumed
mode of action of this compound class is associated with an
aquation step wherein an aqua ligand replaces the leaving
group. In a prior attempt to stabilize highly cytotoxic thiomaltolato complexes in the presence of biomolecules the
N-donating ligand 1-methylimidazole was employed as leaving
group.21 Thus, the stability was significantly increased and
selective activation was possible at decreased pH levels, that
are frequently found in solid tumors.22 Hence, these promising results prompted us to develop polyphosphazene conjugates via coordination of the free amine linker group to
different organometallic compounds of known activity. The
Paper
pH-sensitivity of both polyphosphazene backbone and drug–
amine interaction are eligible characteristics for the application of the respective drug–polymer conjugates in targeted
therapy. In our approach, four promising organometallic complexes (Fig. 1) with small molecule ligands of known biological
activity were chosen in order to improve their in vivo activity
profile, which was shown to involve local adverse effects in a
previously performed test series.
Experimental
Materials
Menadione (2-methylnaphthalene-1,4-dione, 98%, Acros),
sodium methoxide (ca. 95%, Fluka), α-terpinene (90%, Acros),
RuCl3·H2O (Johnson Matthey), trifluoroacetic acid (99%,
Sigma-Aldrich), triethylamine (99%, Acros), ammonium
acetate (≥98%, Fluka), citric acid anhydrous (99.6%, Acros), trisodium citrate dihydrate (min. 99.5%, Sigma-Aldrich) were
used without further purification. Other chemicals and solvents were purchased from commercial suppliers (Sigma
Aldrich, Merck, Acros, Fluka and Fisher Scientific). Methanol
and dichloromethane were distilled prior to use. Dialysis membranes (Spectra/Por 1, 6000–8000 Da) were purchased from
SpectrumLabs. NMR spectra were recorded at 25 °C on a
Bruker Avance III™ 500 MHz FT-NMR spectrometer. 1H NMR
spectra were measured at 500.10 MHz, 13C NMR spectra at
125.75 MHz and {1H}31P NMR spectra at 202.44 MHz from
solutions in deuterated dimethyl sulfoxide, methanol, chloroform, and water. Milli-Q water (18.2 MΩ cm, Milli-Q
Advantage, Darmstadt, Germany) was used for all dilutions for
ICP-MS
measurements.
Nitric
acid
(≥69%,
p.a.,
TraceSELECT®, Fluka, Buchs, Switzerland) was used without
further purification. Ruthenium, rhodium and indium standards for ICP-MS measurements were derived from CPI
International (Amsterdam, The Netherlands). Bovine serum
albumin (BSA) (>98%, Sigma) and Uracil (99%, Fluka) for
calibration of the column for SEC-ICP-MS studies were
used without further purification. CHNS elemental
analyses were carried out on a Eurovector EA3000 elemental
analyzer in the microanalytical laboratory of the University of
Vienna.
A detailed description of the synthetic procedures for the
ligands, complex 1 as well as for the used polymer is given in
the ESI.†
General synthetic procedures
Fig. 1
Complexes 1–4 prepared for macromolecular conjugation.
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General procedure for the synthesis of ruthenium and
rhodium complexes. Syntheses of complexes 1–4 were performed according to the well-established protocol using
sodium methoxide in absolute methanol to deprotonate the
respective chelating ligand followed by the addition of the
dimeric metal precursor complex [(η6-p-cymene)RuIICl2]2 or
[(η5-1,2,3,4,5-pentamethylcyclopentadien)RhIIICl2]2. After stirring at ambient temperature for a varying reaction time
ranging from 1.5 to 24 h, the solvent was removed under
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reduced pressure, the crude product was extracted with dichloromethane and insoluble by-products were removed by filtration. The mixture was then concentrated and the addition
of n-hexane afforded the desired complexes in good to excellent yields. Detailed reaction conditions for complexes 2–4 are
described elsewhere.21,23,24
General procedure for deprotection and loading of polyphosphazenes. For the removal of the tert-butyloxycarbonyl (Boc)
protecting group, the poly(organo)phosphazene was dissolved
in a dry CH2Cl2/TFA mixture (2 : 1 ratio, 2 mL per 100 mg
polymer) and stirred under argon atmosphere for 1 h. After
evaporation of the solvent mixture under reduced pressure, the
deprotected polyphosphazene was dried in vacuo. In order to
form drug-loaded polymer conjugates, the deprotected polyphosphazene was dissolved in dry methanol and Et3N was
added to the mixture. The methanolic solution of the respective complex was carefully added to the polymer and the coupling reaction was stirred at room temperature and under argon
atmosphere for 24 h. Conjugates were then purified by dialysis
against methanol for 5 days.
Conjugate 1a: Deprotected polymer (300 mg, 0.016 mmol),
complex 1 (150 mg, 0.33 mmol), Et3N (55 µL, 0.40 mmol);
yield: 187 mg; 1H NMR (500.10 MHz, D2O): δ 1.11 (m, 6H),
1.37 (m, 4H), 3.17 (s, 6H), 3.31 (bs, 6H), 3.63 (s, 154H) ppm.
{1H}31P NMR (202.44 MHz, D2O): δ 0.21 ppm. DLS (H2O): dh =
16.5 nm; ξ = 1.75 mV. Conjugate 2a: Deprotected polymer
(300 mg, 0.016 mmol), complex 2 (150 mg, 0.36 mmol), Et3N
(55 µL, 0.40 mmol); yield: 205 mg; 1H NMR (500.10 MHz,
D2O): δ 1.02 (m, 6H), 1.12 (m, 4H), 3.19 (s, 6H), 3.23 (bs, 6H),
3.55 (s, 156 H) ppm. {1H}31P NMR (202.44 MHz, D2O):
δ 0.16 ppm. DLS (H2O): dh = 11.7 nm; ξ = 5.92 mV. Conjugate
3a: Deprotected polymer (300 mg, 0.014 mmol), complex 3
(150 mg, 0.36 mmol), Et3N (55 µL, 0.40 mmol); yield: 161 mg;
1
H NMR (500.10 MHz, D2O): 1.07 (m, 6H), 1.20 (m, 4H), 3.13
(s, 6H), 3.29 (bs, 6H), 3.61 (s, 151H) ppm. {1H}31P NMR
(202.44 MHz, D2O): δ 0.86 ppm. DLS (H2O): dh = 11.9 nm; ξ =
2.85 mV. Conjugate 4a: Deprotected polymer (300 mg,
0.016 mmol), complex 4 (150 mg, 0.28 mmol), Et3N (55 µL,
0.40 mmol); yield: 216 mg; 1H NMR (500.10 MHz, D2O): 1.03
(m, 6H), 1.18 (m, 4H), 3.17 (s, 6H), 3.33 (bs, 3H), 3.57 (s, 160H)
ppm. {1H}31P NMR (202.44 MHz, D2O): δ 0.93 ppm. DLS (H2O):
dh = 13.1 nm; ξ = 0.58 mV.
ICP-MS analyses
Quantification of metal content of conjugates 1a–4a as well as
the determination of the ruthenium/rhodium content in tissue
and blood samples from in vivo experiments was carried out
with an ICP-MS instrument Agilent 7500ce. The ICP-MS
Agilent 7500ce (Agilent Technologies, Waldbronn, Germany)
was equipped with a CETAC ASX-520 autosampler (Nebraska,
USA) and a MicroMist nebulizer at a sample uptake rate of
approx. 0.25 mL min−1. The Agilent MassHunter software
package (Workstation Software, version B.01.01, Build 123.11,
Patch 4, 2012) was used for data processing. The experimental
parameters for ICP-MS analyses are summarized in Table S1†
12116 | Dalton Trans., 2017, 46, 12114–12124
Dalton Transactions
and detailed description of sample preparation procedures can
be found in the section S2.4 in the ESI.†
General procedures for biological studies
Animals and xenograft experiments. Eight-week-old Balb/c or
C57/B6JRj mice were purchased from Harlan Laboratories (San
Pietro al Natisone, Italy). The animals were kept in a pathogenfree environment and every procedure was done in a laminar
airflow cabinet. The experiments were done according to the
regulations of the Ethics Committee for the Care and Use of
Laboratory Animals at the Medical University Vienna (proposal
number BMWF-66.009/0084-II/3b/2013), the U.S. Public Health
Service Policy on Human Care and Use of Laboratory Animals
as well as the United Kingdom Coordinating Committee on
Cancer Prevention Research’s Guidelines for the Welfare of
Animals in Experimental Neoplasia.
For the evaluation of tolerability and 24 h organ distribution, non-tumor bearing C57/B6JRj mice were treated with a
single dose of the drug conjugates 1a, 2a or 3a via intravenous
administration. The doses used were 100 mg kg−1 for 1a, 25,
50 and 100 mg kg−1 for 2a and 50 and 100 mg kg−1 for 3a.
Animals were sacrificed 24 h after administration of the
compounds.
For the testing of in vivo anticancer activity, CT-26 (5 × 105)
were injected subcutaneously into the right flank of Balb/c
mice. When tumor nodules reached a mean size of 25 mm3
(day 3), animals were treated twice for five consecutive days (day
3–7 and 10–15) in groups of four with 1 (30 mg kg−1 in 10%
DMSO in water), 2 (10 mg kg−1 in 10% DMSO in water) and 3
(10 mg kg−1 in 10% PG in water) by intraperitoneal injection.
Compounds 1a–3a were dissolved in 0.9% NaCl solution and
sterile filtered afterwards. Animals were treated intravenously
with compound 1a, 3a (both 50 mg kg−1) and 2a (25 mg kg−1)
on days 3, 5, 7, 10, 12 and 14 after the injection of tumor cells.
The tumor size was assessed by caliper measurement and
tumor volume was calculated using the formula: (length ×
width2)/2. Animals were sacrificed upon tumor ulceration or
when a tumor length >20 mm was reached.
Cell culture. In the presented study, the following cell lines
were used: the human cell line CH1 (identified via STR profiling as PA-1 ovarian teratocarcinoma cells by Multiplexion; see
also ref. 25) was kindly provided by Lloyd R. Kelland (CRC
Centre for Cancer Therapeutics, Institute of Cancer Research,
Sutton, UK), and the colon cancer cell line SW480 was purchased from American Tissue Culture Collection (ATCC).
These two cell lines were grown in MEM (supplemented with
1% L-glutamine, 1% sodium pyruvate, and 1% non-essential
amino acids solution (all from Sigma Aldrich, Austria, Vienna)
and 10% FCS (Gibco™, ThermoFisher)). The non-small cell
lung carcinoma cell line A549 was purchased from ATCC and
grown in RPMI 1640 supplemented with 10% FCS. The murine
colon cancer cell line CT-26 ( purchased from ATCC) was grown
in DMEM/F12 medium (Sigma-Aldrich) supplemented with
10% FCS. FCS was purchased from PAA (Linz, Austria). All cultures were grown in humidified air with 5% CO2 at 37 °C and
were regularly checked for mycoplasma contamination.
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Cell viability assay (MTT). 96 h cytotoxicity was determined
by the colorimetric MTT assay (MTT = 3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2H-tetrazolium bromide). Briefly, cells were
harvested by trypsinisation and seeded in medium (vide supra)
into 96-well plates in 100 μL per well. The following densities
were used to ensure exponential growth of untreated controls
throughout the experiment: 1.0 × 103 (CH1/PA-1), 2.0 × 103
(SW480), 3.0 × 103 (A549) cells per well. For 24 h, cells were
allowed to settle and resume exponential growth. Then the test
compounds were dissolved and serially diluted in medium
with 100 μL per well. After 96 h at 37 °C, the medium was
replaced with 100 μL per well RPMI 1640 medium (supplemented with 10% FCS and 4 mM L-glutamine) and MTT
solution (MTT reagent in phosphate-buffered saline, 5
mg mL−1) in a ratio of 6 : 1, and plates were incubated for
further 4 h. Then medium/MTT was removed, and the formed
formazan was dissolved in DMSO (150 μL per well). Optical
densities at 550 nm were measured (reference wavelength:
690 nm) with a microplate reader (ELX880, BioTek). The quantity of viable cells was expressed relative to untreated controls,
and 50% inhibitory concentrations (IC50) were interpolated. At
least three independent experiments were performed, each
with triplicates per concentration level.
Viability assay (EZ4U). For the 72 h viability experiments,
cells were plated in 100 µL per well in 96-well plates. The
number of cells per well was A549 (2 × 103), CH1/PA-1 (3 × 103),
SW480 (2 × 103), and CT-26 (3 × 103). Cells were allowed
to recover for 24 h, then drugs were added in another 100 µL
growth medium and cells were exposed for the time indicated.
Cell survival was determined by the EZ4U assay following
the manufacturer’s recommendations (Biomedica, Vienna,
Austria). Cytotoxicity was evaluated using the Graph Pad Prism
software (La Jolla, USA) (using a point-to-point function) and
was expressed as IC50 values calculated from full dose–
response curves (drug concentrations resulting in 50%
reduction of viable cells compared to untreated control cells
cultured in parallel).
Cellular drug uptake studies. Sample preparation from cell
culture: 3 × 105 cells per well were seeded in 6-well-plates and
allowed to recover for 24 h, then the cells were treated with
10 µM solution of compounds 1–4 or an equimolar amount of
conjugates 1a–4a, respectively. All compounds were added in
culture medium with 10% FCS and incubated for 3 h at 37 °C.
Cells were washed twice with PBS. Then, the pellet was lysed in
500 µL of 69% HNO3 at room temperature for 1.5 h. 400 µL of
the resulting lysates were diluted in 8 mL Milli-Q water and
measured by ICP-MS instrument Agilent 7500ce as described
above (see ref. 26).
Results and discussion
II
III
Synthesis and biological characterization of the Ru and Rh
organometallic complexes
For the synthesis of complexes 1–4, the respective ligands
2-hydroxy-3-methyl-1,4-naphthoquinone, 2-hydroxy-3-methyl-
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pyran-4(1H)-thione
and
3-hydroxy-2-(4-chlorophenyl)-4Hchromen-4(1H)-one were synthesized according to established,
straightforward procedures (Schemes S1–S3†). The synthesis of
the naphthoquinone derivative started from the commercially
available menadione (2-methyl-1,4-naphthoquinone) which
was converted into the corresponding epoxide by reaction with
sodium hydroxide and hydrogen peroxide in a methanol/water
mixture, followed by acid catalyzed ring opening on silica.27
Commercially available maltol represented the starting point
for the synthesis of the second ligand, thiomaltol. Lawessons’s
reagent, a standard compound for thionation reactions, was
applied to convert the carbonyl group into the respective thiocarbonyl via the replacement of the oxygen by sulfur.28 Finally,
in order to synthesize the desired flavone ligand, 2-hydroxyacetophenone and 4-chlorobenzaldehyde were reacted in a
classic aldol condensation to give the hydroxychalcone intermediate with subsequent ring closing under Algar–Flynn–Oyamada
reaction conditions to afford the flavonol ligand.29 Complexes
1–4 (Fig. 1) were synthesized by deprotonation of the ligands’
hydroxyl group by sodium methoxide in methanol followed by
the addition of the respective dimeric metal precursor as has
been reported previously for compounds 2, 3, and 4.21,23,24 The
synthesis of the thiomaltolato-based ruthenium(II) and
rhodium(III) complexes required exclusion of water and oxygen
from the reaction vessel in order to circumvent side reactions.
Hence, reactions were performed in dry methanol using
Schlenk techniques. Standard analytical methods including
1
H and 13C NMR, elemental analysis, and X-ray diffraction analysis were performed and the obtained data was compared to
the respective literature data to confirm purity and formation
of the desired organometallics (reaction scheme and NMR
spectra of complex 1 are shown in the ESI, Scheme S4 and
Fig. S1 and S2†). The compounds were then tested for their
anticancer activity in an MTT assay in three human cancer cell
lines with an exposure time of 96 h, where they displayed
varying cytotoxic potencies depending on the cell line
(Table 1). Cytotoxicity decreases in the following order: 3 ≥ 4 >
2 > 1. Even compound 1 displaying the highest IC50 values can
still be considered a valid candidate for in vivo assessment, as
its IC50 values are lower than those of the clinically active
investigational ruthenium drug IT-139.
Subsequently, complexes 1–3 were evaluated for their in vivo
anticancer activity against murine CT-26 colon carcinoma cells.
Unfortunately, the poor solubility of complex 4 precluded
Table 1 Comparison of IC50 values of compounds 1–4 after 96 h of
incubation
IC50 [µM]
A549
CH1/PA-1
SW480
1
2
3a
4b
IT-139c
47 ± 4
12 ± 4
5.9 ± 0.8
9.5 ± 0.5
156 ± 11
31 ± 10
2.9 ± 0.7
0.97 ± 0.11
0.86 ± 0.06
62 ± 9
15 ± 3
3.7 ± 1.0
1.0 ± 0.1
3.8 ± 0.5
88 ± 19
IC50 data taken from a Ref. 21. b Ref. 24. c Ref. 30.
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further in vivo investigations with this compound. For the
experiments Balb/c mice bearing the syngeneic tumor cells
were treated intraperitoneally with the drugs applied at their
maximal tolerated dose of 30 mg kg−1 for compound 1 and
10 mg kg−1 for compound 2 and 3. In these experiments, only
compound 1 exerted significant activity ( p < 0.01 by two-wayANOVA and Bonferroni posttest) (Fig. 2) and lowered the tumor
burden of the treated animals on the final day of the experiment (data not shown). In contrast, compound 2 and 3 were
widely inactive. Remarkably, the dissection of the animals
revealed strong local adverse effects at multiple organs in the
abdominal cavity, e.g., stiff and swollen intestine, lesions on
the liver, and spleen grown together with liver and stomach
(Fig. S9†) for complexes 1–3. Consequently, we hypothesized
that the compounds exerted excessive local reactivity, which
prevented sufficient amounts of drug to be delivered to the
malignant tissue. Thus, a nanoformulation approach using
polymer conjugates to avoid local reactions and facilitate drug
transport into the tumor nodules was chosen as the next step.
Synthesis and characterization of the polyphosphazene
conjugates
Star-branched polyphosphazenes were utilized as macromolecular drug carriers due to their excellent aqueous solubility and highly branched architecture.31,32 Polymers were synthesized via living cationic polymerization providing control
over chain length and molecular weight.33,34 In a successive
two-step post-polymerization substitution the chlorine atoms
of the poly(dichlorophosphazene) [NPCl2]n were partially substituted with mono-Boc-protected 2,2′-(ethylenedioxy)-bis
(ethylamine) introducing the reaction sites, which were used
for coordination to the organometallic complexes after deprotection. In the next step complete substitution of the
remaining chlorine atoms with Jeffamine, a mono-amine
PPO-PEO random copolymer (Mn = 1000) was performed,
resulting in highly branched and water-soluble polymers
(Scheme S5†). The percentage of reactive sites was determined
via 1H NMR spectroscopy by calculating the ratio of the integrated Boc-group signal to the OCH3 end group peak of the
Jeffamine moieties (29% Boc-groups). 1H and 31P NMR spectra
are shown in the ESI (Fig. S3 and S4†). The Boc-protecting
Dalton Transactions
group was cleaved under dry, acidic conditions yielding free
amino groups which were subsequently used to form coordinative bonds with the organometallic complexes 1–4 in methanolic solution, affording the desired conjugates after purification
via dialysis. The obtained products were dried under reduced
pressure, dissolved in water and lyophilized. For subsequent
investigations, conjugates were dissolved in a 0.9% sodium
chloride solution and stored at −80 °C.
In order to evaluate the degradation behavior of conjugates
during storage in 0.9% sodium chloride solution, 31P NMR
spectra were periodically measured over four weeks. The collected spectra confirmed the suitable stability of all prepared
conjugates after several weeks in aqueous solution (Fig. S5†).
The rate of degradation of polyphosphazenes can be readily
tailored and these polymers were chosen from previous
studies to have a relatively slow degradation rate to simplify
these preliminary drug conjugation studies.35 The extent of
drug loading was determined by measurement of the metal
content via ICP-MS analyses. Sample preparation involved the
microwave-assisted digestion of the poly(organo)phosphazene
backbone in nitric acid (20%) to guarantee complete release of
the metal. The samples were then diluted with Milli-Q water
resulting in nitric acid concentrations below 4% and ruthenium or rhodium concentrations below 15 µg kg−1, suitable
for ICP-MS analysis. Conjugates 2a and 3a, both bearing thiomaltolato-based complexes, show a high drug loading with
73.68 mg g−1 ruthenium and 34.21 mg g−1 rhodium (corresponds to an amine linker conversion of 85 and 40%, respectively), while lower ruthenium levels were detected for conjugates 1a and 4a (15 and 7% conversion; Table 2). Conjugate 4a
was deemed not suitable for in vivo investigations due to its
insufficient drug loading. As application of the conjugates
in vivo requires sterile filtration through 0.2 µm cellulose
acetate filters prior to the administration, the metal content
was determined both before and after sterile filtration and
showed no discernable effect of the filtration process on the
metal contents of the samples.
Drug-release studies. One fundamental prerequisite for polymeric prodrugs is the controlled release of the active moiety in
proximity to the biological target. There are several possible
triggers to initiate the liberation of the drug. The hypoxic
Fig. 2 Anticancer activity of compounds 1–3 in vivo. CT-26 allografts were grown in Balb/c mice (four animals per group) and treated with (a) 1
(30 mg kg−1 i.p.; male animals), (b) 2 (10 mg kg−1 i.p.; male animals), and (c) 3 (10 mg kg−1 i.p.; female animals) on days 3–7 and 10–15. **p < 0.01
statistically different from solvent control by two-way ANOVA and Bonferroni post test.
12118 | Dalton Trans., 2017, 46, 12114–12124
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Table 2 Ruthenium and rhodium concentrations of analyzed aqueous
polymer solutions acquired with ICP-MS measurements before and after
sterile-filtration
Conjugate
Metal
content
[mg g−1]
Metal concentration
before filtration
[mg mL−1]
Metal concentration
after filtration
[mg mL−1]
1a
2a
3a
4a
12.08
73.68
34.21
5.74
0.23
1.49
0.63
0.15
0.24
1.49
0.65
0.16
milieu in solid tumors induces a pH drop by up to 1 unit,
which has been exploited for the development of pH sensitive
macromolecules or linkers for drug-delivery systems.36,37
Another common tactic is intracellular targeting by use of the
lower pH of the endosomal and lysosomal environment.38 The
amine bond to the metal center is proposed to be sensitive to
acidic cleavage (Fig. 3) as was demonstrated in our recently
reported work on 1-methylimidazole substituted organometallic complexes.30 Preliminary UV-Vis spectroscopic investigations indicated that the conjugates underwent the same
transformation under acidic conditions (Fig. S6†). Complex 1
and conjugate 1a were diluted with citric acid buffer (50 mM,
pH 3, 4, 5, and 6) and measured in 1 h intervals over a period
of 24 h. While spectra recorded at pH 6 and 5 remained nearly
unchanged during the monitored time frame, the acidic
milieu of pH 4 and 3 caused changes in the spectrum of 1a
where the absorption at 280 nm increased similar to the free
complex 1. Similar results were found for 2 and 2a under
neutral and acidic conditions (data not shown). To confirm
transformations of the conjugate at lower pH levels further
studies using SEC-ICP-MS were performed using conjugate 2a.
Again, the sensitivity of the conjugate to variations in the pH
level became apparent in a different experimental setup using
a mobile phase with 0.1 vol% formic acid. The acidic milieu
(∼pH 3) of the mobile phase led to the rapid decomposition of
the conjugate and different ruthenium containing species
were detected (Fig. S7†). The degradation process of the
polymer was circumvented by use of an ammonium acetate
buffered eluent (Fig. S8†). These experiments confirm that
intracellular transformation of the conjugate under acidic conditions is possibly enabling the release of the attached metallodrug (free and/or attached to linker). Further investigations on
the exact transformation and release processes at lowered pH
levels are necessary and will be subject of further research.
Recent studies have unveiled a certain affinity of albumin
for ruthenium compounds. For this reason conjugate 2a was
co-incubated with a 10-fold excess of bovine serum albumin
(BSA) at 37 °C and analyzed by size-exclusion chromatography
coupled ICP-MS measurements to rule out possible transfer
processes of the ruthenium complex. The obtained results
indicate that the metallodrug remains attached to the polymer
in the presence of albumin under the given conditions. The
chromatogram showed an undiminished ruthenium peak at
the retention time corresponding to the polymer conjugate
even after 24 h of incubation (Fig. S8†). To appraise the relative
retention time of the conjugate when eluted in a mobile phase
containing an ammonium acetate buffer (10 mm), size-exclusion chromatography (SEC) with a UV-Vis detector (λ =
240 nm) were performed prior to SEC-coupled ICP-MS studies
for the determination of the 101Ru content.
Evaluation of anticancer activity and drug uptake in cell
culture. Compounds 1–4 and their corresponding polymerbound equivalents (conjugates 1a–4a) were analyzed in cell
culture after 72 h of incubation (Table 3). These experiments
revealed that the polymer formulation effectively protected the
cells from the reactivity of the organometallic complexes,
Table 3 Comparison of IC50 values for free complexes 1–4 and conjugates 1a–4a after 72 h of incubation
Fig. 3 Chemical structure of the macromolecular carriers and their
proposed drug release mechanism at lowered pH shown for conjugate
1a.
This journal is © The Royal Society of Chemistry 2017
IC50 [µM]
A549
CH1/PA-1
SW480
CT-26
1
1a
2
2a
3
3a
4
4a
33 ± 3.3
>50
16 ± 2.0
>50
14 ± 5.5
25 ± 8.0
13 ± 1.0
>50
32 ± 6.0
>50
6.2 ± 0.8
>50
2 ± 1.5
11 ± 1.5
2 ± 0.4
>50
15 ± 6.2
>50
15 ± 6.6
>50
10 ± 4.1
11 ± 7.1
7 ± 2.0
>50
>50
>50
14 ± 0.4
>50
9 ± 2.3
>50
7 ± 2.4
>50
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Dalton Transactions
especially in case of conjugates 1a, 2a and 4a. Only conjugate
3a still displayed some activity in the µM range.
We have previously shown that the use of polyphosphazene
nanocarriers can lead to increased drug uptake of metallodrugs into cancer cells due to endocytosis.16 Consequently,
intracellular accumulation of all compounds was determined
in two cell lines (Table 4). For this purpose, cells were treated
with 1–4 (10 µM) or equimolar amounts of 1a–4a for 3 h. After
lysis with HNO3 (69%), the samples were diluted and analyzed
with ICP-MS for the determination of the metal content.26
Surprisingly, the impact of the coupling to the phosphazene
carrier differed between the tested compounds. Thus, in line
with our previous publication on PtIV–polyphosphazene conjugates,16 the intracellular accumulation of 2a and 3a was distinctly enhanced by the nanoformulation. This effect was
especially pronounced with conjugate 2a, which showed
15-fold and 11-fold higher intracellular accumulation compared to complex 2 in SW480 cells and in CT-26 cells, respectively. In contrast, the intracellular accumulation of 1a and 4a
was significantly decreased compared to the free complexes.
This observation already indicated that, despite the use of the
same polyphosphazene nanocarrier, the individual polymer
conjugates behaved markedly different in the performed biological assessments.
Organ distribution. In order to evaluate tolerability and
organ distribution of the polymer-coupled complexes in vivo,
studies in non-tumor bearing C57/B6JRj mice were carried out.
In these experiments, the animals received a single dose of the
drug conjugates 1a, 2a or 3a via intravenous administration,
while the biological investigation of 4a was discontinued due
to its insufficient metal-content as mentioned above. These
experiments revealed that polymer-conjugate concentrations
above 50 mg kg−1 were associated with severe (transient)
fatigue. Consequently, for all subsequently performed in vivo
experiments, concentrations of 50 mg kg−1 for 1a and 3a, and
(due to the high drug loading) 25 mg kg−1 for 2a were administered. The mice used for the tolerability tests were then sacrificed after 24 h and samples of blood, kidney, liver, lung, and,
where possible, urine were collected. After microwave-assisted
digestion of the tissue samples (25–50 mg) in half-concentrated nitric acid, the samples were diluted and the ruthenium
or rhodium content was measured with ICP-MS. Conjugate 2a
was administered in three different concentrations (100
mg kg−1, 50 mg kg−1 and 25 mg kg−1 containing 7.5 mg kg−1,
3.75 mg kg−1 and 1.9 mg kg−1 ruthenium, respectively), while
the conjugate 3a was tested in two different concentrations
(100 mg kg−1 and 50 mg kg−1 containing 3.25 mg kg−1 and
1.6 mg kg−1 rhodium, respectively). In case of conjugate 1a, a
concentration of 100 mg kg−1 containing 1.2 mg kg−1 of ruthenium was used. An overview of all tested schemes is given in
the ESI (Table S2†). Each concentration and conjugate was
tested in parallel in two mice to assess the reproducibility of
the measured metal concentration in all analyzed tissues.
Overall, the highest metal contents were found in the liver and
kidneys, while only low concentrations were observed in the
remaining samples (Fig. 4 and Table S3†). In general, the
determined metal concentrations met the expected distribution profile well, since the administered conjugates prefer-
Table 4 Comparison of intracellular accumulation of ruthenium and
rhodium after treatment with compounds 1–4 and 1–4a
pg metal/104 cells
SW480
CT-26
1
1a
2
2a
3
3a
4
4a
215 ± 89
72 ± 12
<LODa
24 ± 6
62 ± 13
932 ± 14
302 ± 24
<LOD
90 ± 34
7±1
<LOD
23 ± 11
55 ± 3
635 ± 13
187 ± 10
<LOD
a
LOD: limit of detection.
12120 | Dalton Trans., 2017, 46, 12114–12124
Fig. 4 Organ distribution of 1a–3a 24 h after treatment. Female C57/
B6JRj mice were intravenously injected with 100 mg kg−1 of 1a (containing 1.2 mg kg−1 Ru), 25, 50 and 100 mg kg−1 2a (containing 1.9, 3.8 and
7.5 mg kg−1 Ru, respectively) and 50 and 100 mg kg−1 3a (containing1.6
and 3.2 mg kg−1 Rh, respectively). After 24 h, mice were anesthetized
and blood as well as urine was collected by heart and bladder punctuation, respectively, and together with liver, lung and kidney samples were
analyzed with ICP-MS to determine the metal content. Abbreviations:
CBC, cellular blood compartment.
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entially accumulate in organs responsible for clearance and
excretion.
Conjugates 2a and 3a containing thiomaltolato-coordinated
RuII and RhIII metal centers, respectively, exhibited very
similar distribution profiles despite their different metal
centers. Both accumulated preferentially in the liver with
metal concentrations more than five times higher than in
kidney samples. Contrary to the distribution profile of conjugates 2a and 3a, mice treated with the ruthenium(II) naphthoquinone conjugate 1a exhibited ruthenium levels twice as high
in kidney tissue compared to liver samples. The obtained data
suggests that the metal content in all examined organs scales
linearly with the applied dose and is almost identical after normalization of the metal content in reference to the dosage
(Fig. 4). Furthermore, it can be seen that organ distribution of
the tested conjugates is mainly affected by the coordinated
ligand systems, whereas the different metal centers appear to
have no discernable effect.
Subsequently, a second drug distribution experiment was
conducted on CT-26 tumor-bearing animals 3 h after intravenous drug treatment (at concentrations which were subsequently used for the anticancer activity experiments in the
same tumor model). Again, each concentration and conjugate
was tested in parallel in two mice. Comparable to the experiments performed 24 h after therapy, 1a-treated animals again
showed highest drug levels in the kidney, while after application of 2a and 3a the highest concentrations were found in
the liver tissue (Fig. 5). The high drug levels in the urine
(especially in case of 1a and 3a) compared to the animals
investigated after 24 h, indicate a surprisingly high drug
excretion during the first hours after treatment. As this effect
Fig. 5 Tissue distribution of 1a–3a 3 h after treatment. Murine CT-26
cells (5 × 105) were injected subcutaneously into the right flank of
female Balb/c mice (n = 2 per group). Animals were treated once intravenously with the indicated concentrations of compounds 1a, 2a and 3a
on day 10 after tumor inoculation, when the tumors reached a size of
∼250 mm3. After 3 h, mice were anesthetized and blood as well as urine
was collected by heart and bladder punctuation, respectively, and
together with liver, lung, kidney and tumor samples were analyzed with
ICP-MS to determine the metal content. Abbreviations: CBC cellular
blood compartment.
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Paper
cannot be explained by simple chemical reasons, it is assumed
to be based on biological transformation or metabolism of the
conjugates, which need to be further investigated in depth in
subsequent studies. Interestingly, in case of compound 2a the
ruthenium levels in the liver (in contrast to all other tissues)
were approximately twice as high in the animals investigated
after 24 h as of those examined after 3 h. This fact could indicate a time-dependent (maybe metabolism-associated)
accumulation of 2a in this tissue. The effect was weaker for 1a
and 3a, where the hepatic levels after 3 h and 24 h were very
similar. With regard to the drug accumulation in the tumor,
the metal content of 2a and 3a was higher than of conjugate
1a, which is in line with the higher drug loading of these two
polymers.
Anticancer activity in vivo. With the intriguing organ distribution profile at hand, the antineoplastic effect of conjugates
1a, 2a, and 3a was next assessed by treatment of tumorbearing Balb/c mice using the syngeneic murine tumor model
CT-26 comparable to the experiments on complexes 1–3
described above. The animals were treated with the respective
drugs intravenously on days 3, 5, 7, 10, 12 and 14.
The applied doses were 50 mg kg−1, 25 mg kg−1 and 50
mg kg−1 (containing 2.7 mg kg−1, 7.7 mg kg−1 and 6.5 mg kg−1
of the particular active metal complex, respectively) for conjugates 1a, 2a, and 3a, respectively. During the first week of treatment, tumor growth curves for single mice revealed that
administration of the macromolecular prodrugs induced
drastic tumor shrinkage in some animals (Fig. 6 and Fig. S9†).
Within the tested series, this effect was most pronounced for
the naphthoquinone-based RuII conjugate 1a. In contrast, no
comparable tumor shrinkage was induced in the control group
treated with 0.9% sodium chloride solution. However, this
beneficial effect of our conjugates was only of a transient
nature and diminished over the course of the treatment resulting in rapid tumor regrowth in most of the animals.
Consequently, only in the case of conjugate 3a, a trend
towards improved overall survival was found (Fig. 6h). In
addition, one of the animals treated with conjugate 1a, experienced a long lasting tumor stabilization and thus an >100%
increase in life span (Fig. 6d). With regard to the unloaded
polymer, we observed (compared to the 0.9% NaCl-treated
group) an increase of tumor ulceration, which necessitated an
earlier sacrifice of the animals. Notably, the final dissection of
the animals revealed no indications of severe organ damage
comparable to the treatment with the free complexes 1–3
(Fig. S10 and S11†).
In order to get insights into the impact of repeated polymer
application on the tissue distribution, samples from two mice
that had to be sacrificed on day 17 (three days after the last
treatment) were analyzed by ICP-MS (Fig. 7). One of these
animals had been treated with compound 1a, the other with
compound 2a. Overall, the metal content in the analyzed
organs of these mice largely resembled the distribution profiles determined 3 h and 24 h after single dose administration.
Interestingly, in case of 2a, the ruthenium levels of serum and
urine were 5- and 25-fold higher than in the animals investi-
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Fig. 6 Anticancer activity of 1a–3a. Murine CT-26 cells (5 × 105) were
injected subcutaneously into the right flank of female Balb/c mice (n = 4
per group). Animals were treated intravenously with 1a, 2a and 3a. The
applied doses were 50 mg kg−1 for 1a and 3a, and 25 mg kg−1 for 2a on
day 3, 5, 7, 10, 12, and 14. Tumor growth curves of single CT-26-bearing
animals under treatment with (a) 0.9% NaCl, (b) unloaded polymer, (c)
1a, (e) 2a and (g) 3a are shown. Figures (d), (f) and (h) display the overall
survival of CT-26-bearing animals upon the indicated drug treatment.
Dalton Transactions
gated 24 h after single dose application. Unfortunately, we
did not succeed in collecting blood and urine samples of the
animal treated with 1a. The values found in blood and urine
samples of 2a indicate a distinctly prolonged plasma half-life
time along with slow drug release from the macromolecule.
This assumption is also supported by the observation that,
although the sample collection happened 3 days after the last
drug application, the ruthenium levels in kidney and liver of
the repeatedly treated animals still were significantly above
the ones observed 3 h after a single dose application of the
two different drugs. The effect was especially pronounced for
2a, where the liver levels were about 6-fold higher than the
ones detected 24 h after a single application, which supports
the hypothesis that this polymer slowly accumulates over
time in the hepatic tissue with only limited elimination.
Since such a strong drug accumulation in the liver could lead
to drug-induced tissue damage, a histological evaluation of
the collected samples was performed. For this purpose, the
organs of all animals that had received therapy over a period
of two weeks were embedded in paraffin, stained with
hematoxylin/eosin and were microscopically investigated.
Representative pictures for 0.9% NaCl, unconjugated
polymer, as well as for conjugates 1a, 2a and 3a are shown in
the ESI (Fig. S11†).
Overall, no major organ injury was found, thus confirming
the protective nature of our approach. Solely Bowman’s space
in kidney tissue showed some reduction upon treatment with
2a and 3a. Taken together, our drug distribution data indicate
that despite the use of the same polymer for all three organometallic complexes, the organ distribution pattern as well as
kinetics strongly differed. Moreover, the drug accumulation
levels in the malignant tissue were not predictive for the in vivo
anticancer activity, as 1a (with the lowest tumor accumulation)
was the only drug resulting in distinct life prolongation of an
animal, while 2a (with the highest tumor levels) had no visible
impact on overall survival of the animals.
Conclusions
Fig. 7 Tissue distribution of conjugates in two animals after 2 weeks of
drug treatment. Two animals of the experiment depicted in Fig. 6 were
sacrificed on day 17 (3 days after the last application) due to tumor
ulceration. Mice (one treated with 1a and one with 2a) were anesthetized
and blood as well as urine was collected by heart and bladder punctuation, respectively, together with tissue samples for ICP-MS analyses.
12122 | Dalton Trans., 2017, 46, 12114–12124
Within this work organometallic complexes have been
attached to polyphosphazene macromolecules to obtain
metallodrug conjugates. The extent of drug loading of the
polymers was determined by measurement of the metal
content via ICP-MS analysis after microwave-assisted digestion. Highest metal levels were detected for conjugates 2a and
3a, both bearing thiomaltolate as chelating ligand. The
obtained macromolecular prodrugs were found to be highly
stable in neutral aqueous solution as confirmed by 31P NMR
spectroscopy and UV-Vis kinetic studies. The free drug was
observed to be released under acidic conditions potentially
enabling selective intracellular lysosomal release. The antiproliferative potency of the free complexes was determined in
different human cancer cell lines and compared to the
respective polymer adduct. Thereby, we found that conjugation of the free organometallics to polyphosphazenes sig-
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nificantly diminished the activity in vitro compared to the
parent small molecule complexes. The potential of the developed polymer adducts as anticancer agents was elucidated
in vivo and compared to the respective complexes. In contrast
to the unconjugated drugs no morphological changes of the
animals’ organs were observed, confirming the stabilization of
the highly active organometallics. Furthermore, pronounced
tumor shrinkage after administration of the first dose of
loaded polymer was observed for all tested conjugates and
especially in the case of 1a, the beneficial effect was evident as
one mouse experienced increased survival time by more than
100%. However, this effect cannot be explained by increased
drug accumulation, because 1a showed both lowest polymer
drug loading and cellular accumulation in CT-26 in vitro and
in vivo. In addition, tissue distribution analysis revealed a
totally different accumulation profile of 1a compared to 2a or
3a which contrasts their respective anticancer activity.
Conjugates 2a and 3a preferably accumulated in the liver,
while 1a caused highest metal levels in the kidneys. To preclude that the conjugates have a detrimental effect on organs
with the highest accumulation level, liver and kidney tissues
were evaluated histologically and microscopic images revealed
no severe drug induced tissue damage. Overall 2a and 3a
showed similar results in all biological studies and therefore
an impact of the metal center (Ru and Rh) on the anticancer
potential in vivo can be excluded. It appears more likely that
the coordinated bioactive ligand scaffold is the main activity
determining factor in this class of organometallics, since
investigated conjugates do not show differences in size or drug
release behavior. Overall, the conjugation of metallodrugs to
poly(organo)phosphazenes is a promising approach for drug
delivery. Stabilization of the reactive organometallics by this
macromolecular drug formulation tremendously reduced the
observed local adverse effects such as the deformation of
organs. Based on the obtained results presented herein, the
naphthoquinone-containing complex 1 is a promising candidate for further research regarding lead optimization and
mode of action studies. Improvement of the poly(organo)phosphazenes concerning drug loading efficacy, and in particular
the drug release kinetics, as well as an optimization of the
hydrodynamic volume with the aim of extending blood retention times and exploiting the EPR effect might be promising
approaches to further enhance the very positive in vivo effects
of our conjugates.
Acknowledgements
The authors acknowledge financial support from the Austrian
Science Fund (FWF) (Grant No. P24659-N28) and the Fellinger
Krebsforschungsverein. We are grateful to Sushilla van
Schoonhoven for the skillful handling of cell cultures, to Anita
Brandstetter and the team of the Histology Core Facility of the
Institute of Cancer Research for competent technical assistance and Gerhard Zeitler for devoted animal care.
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Paper
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