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Poly(lactic acid) nanoparticles of the lead anticancer ruthenium compound KP1019 and its surfactant-mediated activation.
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PAPER
Cite this: Dalton Trans., 2014, 43,
1096
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Poly(lactic acid) nanoparticles of the lead
anticancer ruthenium compound KP1019
and its surfactant-mediated activation
Britta Fischer,a Petra Heffeter,b,c Kushtrim Kryeziu,b,c Lars Gille,d Samuel M. Meier,a,c
Walter Berger,b,c Christian R. Kowol*a,c and Bernhard K. Kepplera,c
Nanoparticle formulations offer besides the advantage of passive drug targeting also the opportunity to
increase the stability of drugs. KP1019 is a lead ruthenium(III) compound which has been successfully tested
in a clinical phase I trial. However, it is characterized by low stability in aqueous solution especially at physiological pH. To overcome this limitation, poly(lactic acid) (PLA) nanoparticles of KP1019 with two different
surfactants (Pluronic F68 and Tween 80) were prepared by a single oil-in-water (o/w) emulsion. Cytotoxicity measurements comparing different aged Tween 80 nanoparticles revealed that the color change
from brown to green was associated with an up to 20 fold increased activity compared to “free” KP1019.
Further investigations suggested that this is based on the formation of enhanced intracellular reactive
oxygen species levels. Additional studies revealed that the origin of the green color is a reaction between
KP1019 and Tween 80. Kinetic studies of this reaction mixture using UV-Vis, ESI-MS and ESR spec-
Received 29th August 2013,
Accepted 10th October 2013
DOI: 10.1039/c3dt52388h
www.rsc.org/dalton
troscopy indicated on the one hand a coordination of Tween 80 to KP1019, and on the other hand, the
color change was found to correlate with a reduction of the Ru(III) center by the surfactant. Together, the
results provide a first experimental approach to stabilize a biologically active Ru(II) species of KP1019 in
aqueous solution, which probably can be also used to selectively generate this activated species in the
tumor tissue via delivery of KP1019 using Tween 80 nanoparticles.
Introduction
Ruthenium compounds are the most promising non-platinum
candidates for metal-based cancer therapy due to their
multiple accessible oxidation states and slow ligand exchange
kinetics, which are similar to platinum.1,2 Currently, there are
two ruthenium drugs under clinical evaluation as anticancer
agents: NAMI-A (imidazolium trans-[tetrachlorido(1H-imidazole)(S-dimethylsulfoxide)-ruthenate(III)]) and KP1019/KP1339
(indazolium/sodium trans-[tetrachloridobis(1H-indazole)ruthenate(III)]) (Fig. 1).
Notably, NAMI-A was shown to exhibit mainly anti-metastatic potential, while being widely ineffective against primary
tumors.3 In contrast, KP1019 possesses excellent antitumor
a
Institute of Inorganic Chemistry, University of Vienna, Waehringer Str. 42, 1090
Vienna, Austria. E-mail: christian.kowol@univie.ac.at; Fax: +43-1-4277-52680;
Tel: +43-1-4277-52609
b
Institute for Cancer Research and Comprehensive Cancer Center, Medical University
Vienna, Borschkegasse 8a, 1090 Vienna, Austria
c
Research Platform “Translational Cancer Therapy Research”, University of Vienna
and Medical University of Vienna, Vienna, Austria
d
Molecular Pharmacology and Toxicology Unit, Department of Biomedical Sciences,
University of Veterinary Medicine Vienna, Veterinaerplatz 1, 1210 Vienna, Austria
1096 | Dalton Trans., 2014, 43, 1096–1104
Fig. 1
Chemical structures of KP1019 and NAMI-A.
activity against primary tumors. In a pilot phase I study treatment with KP1019 resulted in disease stabilization for 8–10
weeks in five of six patients with only mild treatment-related
toxicities.4,5 With regard to the mode of action of KP1019, it is
assumed that once administered intravenously the ruthenium
drug tightly binds to plasma proteins (albumin and transferrin)
which transport the drug into the solid tumor tissue. There it
is activated by reduction resulting in the active Ru(II)
species, which features a high reactivity towards biomolecules.6
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However, also in its +III oxidation state KP1019 possesses a
high general reactivity with regard to the M–Cl bond, which
results in low stability in aqueous solution, especially at
physiological pH. Consequently, it is of high interest to
develop new KP1019 formulations with improved stability.
Nanoparticle formulations offer besides high stability also
the advantage of facilitated uptake into cells by endocytosis
and passive targeting of the malignant tissue by the enhanced
permeability and retention (EPR) effect.7 This enhanced
accumulation of nanoparticles is based on leaky, defective, and
abnormal blood vessels originating from tumor cell-induced
angiogenesis together with an absent or defective lymphatic
drainage.8
The requirements for an ideal polymer-based drug carrier
are: biodegradability, biocompatibility, and the lack of toxicity.
Thus, the most frequently used synthetic polymers are poly(lactic acid) (PLA), poly(glycolic acid) (PGA) and their copolymer, poly(lactide-co-glycolide) (PLGA).9 In the body, PLA and
PGA are hydrolyzed and decomposed to their monomeric components lactic acid and glycolic acid. Since these monomers
occur also physiologically as by-products of several metabolic
pathways, there is no systemic toxicity associated with their
use as nanoparticulate drug delivery systems.10 As a consequence, both polymers have already been approved by the US
Food and Drug Administration (FDA) as therapeutic drug carriers.11 Additionally, a surfactant is frequently added to the
nanoparticle preparation to enhance its physical stability and
to provide specific size, geometrical control, and stabilization
of particulate assemblies.12 The most commonly used surfactants are poloxamers, polysorbates, and poly(vinyl alcohol)
(PVA). However, for PVA a potential carcinogenic activity has
been reported.13 Thus, poloxamers (Pluronic F68) and polysorbates (Tween 80) are currently considered the ideal surfactants
for nanoparticle preparations and are frequently used in food
and pharmaceutical preparations.14
Recently, we presented a first attempt to prepare a nanoformulation of KP1019 using PEGylated polymeric micelles,15
which distinctly enhanced the cellular uptake of KP1019 and,
consequently, its anticancer activity. However, due to the
preparation procedure these nanocarriers were characterized
by a rather high dimethylsulfoxide (DMSO) content and a low
KP1019/polymer ratio, which are both problematic for further
( pre)clinical development. Consequently, biodegradable PLA
nanoparticles of KP1019 with different surfactants (Tween 80
and Pluronic F68) were investigated in this study and the biological activity of the particles was evaluated.
Paper
Briefly, the encapsulation of KP1019 was carried out using
acetone solutions of PLA and KP1019, which were added to an
aqueous solution of the surfactants (Tween 80 or Pluronic
F68). After brief stirring the organic solvent was evaporated
under reduced pressure and the resulting suspensions were
concentrated. For both surfactants brown suspensions were
obtained, suggesting that KP1019 was kept in its original state.
For the Tween 80 nanoparticles (TWNP) no settling of particles
could be observed for 25 days at 4 °C, indicating stable nanoparticle formation without agglomeration. However, a distinct
change in color from brown to green was visible after about
7 days, indicating a chemical modification of KP1019. This color
change was not observed for Pluronic F68 nanoparticles [PLNP;
0.1% (w/v)]. However, a brown precipitate was already observed
after ∼15 h, indicating that KP1019 diffuses out of PLNP.
Increasing the amounts of surfactant [0.2–0.4% (w/v)] did not
result in significant improvements regarding color change or
drug encapsulation in the case of TWNP or PLNP, respectively.
Thus, all further investigations were done using 0.1% (w/v)
surfactant to keep the amount of organic material at a minimum.
Particle characterization
The mean particle size obtained for TWNP was 164 ± 6 nm and
for PLNP was 163 ± 1 nm. This is ideal as particles <300 nm
have a prolonged plasma half-life and are characterized by
enhanced tumor accumulation via the EPR effect.17 The polydispersity indices (PDI) of all particles were <0.15 indicating a
mono-disperse size distribution.
The electrostatic repulsion of the particle surfaces (zeta
potential) was determined in order to gain insights into the
surface charge of the new nanoparticles. In the case of TWNP,
values around −39 ± 1 mV were found, whereas PLNP possessed surface charges of −24 ± 1 mV. Notably, for PLA nanoparticles prepared without a surfactant a zeta potential of
−49 mV was reported.18 The decreased surface charge of
TWNP and PLNP can be explained by capping of the terminal
carboxylic acid groups of PLA by the surfactants.
Transmission electron microscopy (TEM) measurements
were carried out to investigate the morphology of the particles
and whether KP1019 is effectively encapsulated in the
Results and discussion
Synthesis of nanoparticles
In order to produce KP1019-loaded particles in the nanometer
scale by oil-in-water (o/w) emulsions the nanoprecipitation
method was used, which is highly convenient for encapsulation of lipophilic drugs.16 Tween 80 and Pluronic F68 were
used as surfactants to generate a stable nano-suspension.
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Fig. 2 Transmission electron microscopy (TEM) image of KP1019loaded (A) TWNP and (B) PLNP (the red squares indicate non-encapsulated KP1019).
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Fig. 3
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Reproducibility of the size distribution of TWNP by preparation of three independent batches, each measured three times.
nanoparticles. Fig. 2 shows two representative micrographs of
TWNP and PLNP, revealing that both particle types have a
spherical shape. The TWNP has a high contrast throughout
the whole particle, suggesting that KP1019 is encapsulated in
the polymer matrix. However, the TEM-images of PLNP displayed only low contrast and several small black dots with
high contrast (<1 nm size, red squares in Fig. 2B) were found
in the surroundings, which very likely result from the ruthenium signal of the non-encapsulated KP1019. Thus, the TEM
images indicated a higher encapsulation efficiency of KP1019
in TWNP compared to PLNP, which in turn also seem to leak
KP1019. Consequently, all further investigations were performed with TWNP.
After successful determination of the optimal formulation
parameters for TWNP, the reproducibility of the preparation
concerning particles size and drug loading efficiency was investigated by analyzing three independent batches. The mean particle size distributions are depicted in Fig. 3 indicating a high
size reproducibility with a mean diameter of 164 ± 10 nm (all
PDI values were <0.15). In addition, the size-dependent long
term stability (25 days) of TWNP was investigated by DLS
measurements, revealing no significant size changes during
one month regardless of the particle color (data not shown).
ICP-MS experiments were performed to evaluate the drug
loading efficiency by determination of the absolute ruthenium
content (Table 1). In the above described batches, the amount
of encapsulated ruthenium ranged from 92 to 95% with
respect to the initial total amount, indicating very high reproducibility and drug loading efficiency.
Fig. 4 Nanoparticles used to evaluate the antitumor activity: (A)
TWNP_3 (5 days, 4 °C); (B) TWNP_2 (24 h, 4 °C); (C) TWNP_4 (24 h,
25 °C); (D) TWNP_1 (2 h, 25 °C); (E) blank TWNP.
Cytotoxicity in human cancer cell lines
In order to evaluate the antitumor activity of TWNP, the
growth inhibitory effects were studied in comparison to “free”
KP1019 and blank nanoparticles (blank TWNP). The cell viability was assessed by MTT assay in the colon carcinoma SW480
and the hepatoma Hep3B cell line after 72 h of drug incubation.
Table 1
Reproducibility of the drug loading efficiency of TWNP
Initial amount of
KP1019 [µmol]
Detected amount of
ruthenium [µmol]
Entrapment
efficiency [%]
2.5
2.5
2.5
2.3
2.4
2.4
92
95
95
1098 | Dalton Trans., 2014, 43, 1096–1104
TWNP (brown and green) at different storage times (ranging from
2 h to 5 days) and temperatures [stored either at 4 °C or at room
temperature (∼25 °C)] were investigated (Fig. 4 and Table 2).
The experiments revealed that the nanoparticle formulations of KP1019 in general showed higher cytotoxicity than
“free” KP1019 (Table 2, Fig. 5). Surprisingly, longer storage
especially at room temperature distinctly increased the activity
of the KP1019-loaded particles. This effect was most pronounced for the green TWNP_4 (24 h, 25 °C), where a 20-fold
increased activity was found in comparison to “free” KP1019.
In contrast, the brown TWNP_1 (2 h, 25 °C) displayed only a
slightly higher cytotoxicity than “free” KP1019. This suggests
that the reaction leading to green color of the nanoparticles is
associated with drastic increase in activity. These effects are
not based on the particles itself as the blank TWNP was inactive in these experiments (Fig. 5). Moreover, no enhanced
cellular ruthenium uptake of TWNP_1 and TWNP_4 was
detected by ICP-MS measurements (data not shown), which is
in contrast to the higher uptake of the previously published
KP1019-containing polymeric micelles.15
Table 2
IC50 values of the different nanoparticle formulations
Storage conditions
KP1019
TWNP_1
TWNP_2
TWNP_3
TWNP_4
Blank
TWNP_1
Blank
TWNP_2
IC50 [µM]
Time
Temperature
Color
SW480
Hep3B
2h
24 h
5d
24 h
1 month
25 °C
4 °C
4 °C
25 °C
4 °C
Brown
Brown
Brown
Brown
Green
White
101.1 ± 4.9
82.9 ± 4.1
41.5 ± 4.8
19.8 ± 0.1
5.2 ± 0.4
≫100
141.8 ± 8.1
≫100
67.3 ± 0.3
38.7 ± 1.7
5.5 ± 0.3
n.a.
2h
25 °C
White
≫100
≫100
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change to green color comparable to TWNP after 24 h at room
temperature. Subsequent MTT assays showed that the cytotoxicity of the green TW1019 (IC50 value of 3.0 ± 0.1 µM in SW480
cells) was comparable to green TWNP_4. These results suggest
that the higher cytotoxic activity of TWNP_4 originates from a
reaction of KP1019 with Tween 80.
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Production of intracellular reactive oxygen species (ROS)
Fig. 5 Impact of different storage times and temperatures on the anticancer activity of TWNP. Dose–response curves of SW480 and Hep3B
cells with the indicated drugs were determined by MTT assay after 72 h
treatment. Values are normalized relative to the untreated controls and
represent means and S.D. of two independent experiments performed in
triplicates.
To evaluate whether this increased activity of TWNP_4 is
based on reactions of KP1019 with single nanoparticle components, KP1019 was mixed with PLA or Tween 80 separately.
In the case of PLA, no color change was observable upon incubation with KP1019, even after longer time periods. In contrast, the KP1019/Tween 80 solution (TW1019) showed a
Microscopical examinations indicated that the new nanoparticles lead to very rapid cell death induction within several
hours. Therefore, we hypothesized that increased ROS production might be involved in the enhanced activity of the new
nanoparticles, in particular TWNP_4. The cell-permeable, fluorescent dye DCF-DA (2′,7′-dichlorofluorescein diacetate) was
used for the detection of intracellular H2O2, and other ROS
such as OH• and ROO•.19 Fig. 6A shows the changes in intracellular ROS levels after 30 min drug treatment. In accordance
with previously published data,20 treatment with KP1019 as well
as with the positive control H2O2 led to a distinct increase in
the intracellular fluorescence levels. Notably, the ROS production of the strongly cytotoxic TWNP_4 was even higher than
that of KP1019, while brown TWNP_1 was distinctly less active.
To assess whether the nanoparticle formulation also leads
to generation of superoxide radicals (O2•−), DHE assays were
performed. Interestingly, again treatment with green TWNP_4
resulted in increased levels of intracellular superoxide radicals
(Fig. 6B), while both, “free” KP1019 and brown TWNP_1,
reduced the spontaneous intracellular O2•− amount. The blank
TWNP had only minor effects in both ROS assays. Together
these results reveal that TWNP_4 generated enhanced levels of
oxidative stress (compared to TWNP_1 and “free” KP1019),
which might explain its pronounced effects on the cell viability
observed in MTT assays.
Together, the biological data strongly suggest that the color
change is accompanied by the formation of ROS in the biological environment, which are responsible for the high
cytotoxicity of green TWNP_4. Moreover, the high activity of
Fig. 6 ROS production of TWNP in SW480 cells. (A) Intracellular production of ROS by the indicated concentrations of the tested compounds was
determined after 30 min of incubation using DCF-DA. (B) Production of intracellular superoxide after 1 h of incubation with the indicated drug concentrations was determined using DHE. Antimycin A (AMA) was used as a positive control. Fluorescence was measured by flow cytometry. One
representative experiment out of three is shown delivering comparable results.
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TW1019 indicates that this effect originates from a reaction
between KP1019 and Tween 80.
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Characterization of the interaction between KP1019 and
Tween 80
To gain further insights into the interaction of KP1019 and
Tween 80, we carried out kinetic studies on TW1019 using
UV-Vis and electrospray ionization mass spectrometry (ESI-MS)
as well as ESR spectroscopy experiments after incubation at
37 °C. The UV-Vis absorption spectra of TW1019 revealed the
first changes already after 4 h (Fig. 7) indicating the formation
of a new species of KP1019. The color change from brown to
green was clearly visible after ∼24 h of incubation indicated by
the appearance of a new signal at 645 nm (Fig. 7). In addition,
the solutions were also investigated by ESI MS, since mass
spectrometry has proven to be a powerful tool to analyze the
reactions of metal complexes in aqueous solution on the molecular level.21 The freshly prepared TW1019 revealed only one
signal in the negative ion mode corresponding to [RuCl4(Hind)2]− (m/z 479.98, mtheor = 479.88; Hind = indazole)
proving the presence of unreacted KP1019 (Fig. 8A). Chloride
adducts of Tween 80 with n = 14–33 (n is the number of ethylene glycol units) were detected only after 4 h of incubation in
the negative ion mode. This is of interest as such non-specific
adducts can only be generated after a Ru–Cl dissociation reaction. In addition, a small population of KP1019–Tween 80
adducts was detected (Fig. 8B).
After 25 h of incubation the mass signals corresponding to
KP1019 vanished completely (Fig. 8A). However, in these
measurements the KP1019–Tween 80 signals were not
increased and no additional signals could be detected in the
positive ion mode. This suggested that the color change from
brown to green is not a result of the simple exchange of one
chlorido ligand of KP1019 by Tween 80 and it can be assumed
that a non-ionizable molecule is formed, which is not suitable
for ESI-MS detection, probably due to a change in the oxidation state of the metal center.
Thus, the TW1019 solution was additionally investigated by
ESR spectroscopy simultaneously with UV-Vis. TW1019
Fig. 7 Time-dependent UV-Vis absorption spectra of 0.2 mM TW1019
at 37 °C.
1100 | Dalton Trans., 2014, 43, 1096–1104
Fig. 8 (A) Time-dependent ESI mass spectra in the negative ion mode of
TW1019 after 10 min, 4 h and 25 h. (B) Excerpt of ESI mass spectra:
besides non-specific chloride adducts of Tween 80 (n = 26–31), low
abundant KP1019-Tween 80 adducts (n = 19–25) were observed after
4 h (brown solution). However, subsequently no significant changes
were observed up to 25 h of incubation (green solution).
exhibited a broad unresolved ESR signal centered at g = 2.5
(Fig. 9B), which is in the expected range for Ru(III) d5 low spin
complexes.22 The time-dependent measurements (Fig. 9)
revealed a strong decrease of the overall ESR signal intensity
within 24 h accompanied with a continuous increase of the
UV-Vis signal at 645 nm. The distinct decrease in the ESR
intensity suggests that the oxidation state of the paramagnetic
Ru(III) metal center in KP1019 changed to a diamagnetic Ru(II)
center.23 This can presumably be explained by the well-known
autoxidation of polysorbates like Tween 80, which can be catalyzed by transition metals under simultaneous reduction of
the metal ion.24 In comparison, no decrease in the ESR signal
intensity (centered around g = 2.5) for 24 h was observed for a
Tween 80 solution containing KP418 (imidazolium trans[RuCl4(1H-imidazole)2]) the imidazole analogue of KP1019.
This difference can be explained by the distinctly lower
reduction potential of KP418 (−0.25 V vs. NHE) compared to
KP1019 (+0.03 V vs. NHE)25 and further supports the assumption of reduction of TW1019 by Tween 80.
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which can be visually determined by the appearance of the
deep green color.
Besides its possible implication on the functionality of
TWNP, these results are also of interest with regard to the
KP1019 chemistry. Due to the instability and insolubility of
reaction products in aqueous solutions, the investigation and
the proof of the proposed ruthenium(II) species, which is
widely accepted as the active species of ruthenium(III) complexes, were difficult so far. Consequently, this study might
represent the first description of a stabilized ruthenium(II)
species in aqueous solution of KP1019 and its enhanced cytotoxic activity against cancer cells. However, there are still many
open questions. For example, the appearance of the green
color was not affected by argon or pure oxygen atmosphere. In
addition, it was not possible to characterize the exact nature of
the newly formed ruthenium(II) species. Nevertheless, our
study proves that nanoparticle formulation of KP1019 is a valuable tool to modify the behavior and stability of KP1019 in
aqueous solutions. Thus, in vivo analyses regarding the tolerability and tumor-targeting effects of the new KP1019-containing particle are currently ongoing, which will also clarify
whether the additional activation of KP1019 by Tween 80 is
also reflected by enhanced anticancer activity in vivo.
Experimental procedures
Fig. 9 (A) Time-dependent ESR and UV-Vis (400–800 nm) spectra of
TW1019 each normalized to the highest measured value. (B) ESR and
UV-Vis spectra measured at 0 h (left side) and after 24 h (right side).
Conclusion
Nanoparticle formulations offer the opportunity to enhance
the stability and tumor-targeting effects of anticancer drugs.
However, there are several parameters which have to be considered for successful clinical development. Besides reproducibility and biocompatibility, also the use of appropriate
solvents and polymer/drug ratios has to be optimized. Consequently, the here presented study aimed at developing a new
nanoparticle formulation of KP1019 with improved properties
with regard to in vivo applicability. Our studies revealed that
the choice of the surfactant directly influences the encapsulation efficiency and nanoparticle retention of KP1019. In contrast to Pluronic F68, Tween 80 was able to prevent drug
precipitation at drug doses necessary for in vivo application
and allowed reproducible preparation of KP1019-containing
nanoparticles. Interestingly, when stored at room temperature
(or at storage times >1 week at 4 °C), a distinct color change of
the particles from brown to green was observed, which was
accompanied by a greatly enhanced cytotoxicity (∼20-fold).
Subsequent spectroscopic analyses revealed that this is based
on interactions of KP1019 with Tween 80. The reaction is
characterized by conjugation of Tween 80 to KP1019 by replacement of one chlorido ligand after 4 h at 37 °C. On the other
hand, reduction of the ruthenium(III) center occurs within 24 h
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Chemicals
KP1019 was synthesized according to published procedures.26
PLA (MW 75 000–120 000; Sigma Aldrich), Pluronic F68 (MW
8400; Sigma Aldrich, Austria), Tween 80 (MW 1310; Fisher
Scientific, Austria) and methanol (HPLC grade, Fisher Scientific, Austria) were used as supplied. MilliQ water was obtained
from a Millipore Advantage A10 185 UV Ultrapure Water
System (18.2 MΩ; Molsheim, France). All other chemicals were
of analytical grade and used without further purification.
Preparation of KP1019-loaded nanoparticles by the
nanoprecipitation method
For the preparation of the nanoparticles the nanoprecipitation
method was used.27 First, 20 mg of PLA (∼0.22 µmol) and
1.5 mg of KP1019 (2.5 µmol) were dissolved in 1.95 mL
acetone followed by addition of 0.05 mL dichloromethane.
This solution was poured under stirring into 5 mL of an
aqueous phase prepared by dissolving different amounts of
Tween 80 or Pluronic F68 in the range of 0.1% (w/v) to 0.4%
(w/v) and stirred for 30 min at room temperature. The organic
solvents were evaporated under reduced pressure at 35 °C and
the volume was adjusted to 1 mL. The nanoparticles were
stored at 4 °C. Drug-free blank nanoparticles were prepared by
the same procedure.
Particles size and surface charge (zeta-potential)
The nanoparticle sizes and the polydispersity indices (PDI)
were determined by dynamic light scattering (DLS) using a
Malvern ZetaSizer Nano ZS (Malvern Instruments Ltd,
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Malvern, UK) equipped with a 4 mW He–Ne, 632.8 nm laser
beam at 25 °C at a scattering angle of 173°. Prior to the particle
size measurement, the nanoparticles were diluted (1 : 10 v/v)
with MilliQ water and measured in disposable cuvettes (UVcuvette micro, Brand GmbH+Co KG, Germany). The zetapotential of the nanoparticles was determined using the same
instrument in disposable capillary cells. The instrument performs Laser Doppler Velocimetry (LDV) in order to obtain the
electrophoretic mobility and convert this to the zeta potential
by the usage of the Henry equation.
Nanoparticle morphology: TEM analysis
Transmission electron microscopy (TEM; Zeiss TEM 902) was
used to evaluate the shape and size of the nanoparticles. One
drop (approximately 10 µL) of the diluted nanoparticles (1 : 3
v/v, with Millipore water) was placed on a carbon-coated 100mesh copper grid. Any excess fluid was removed with a filter
paper. The grid was allowed to dry overnight and analyzed
under the electron microscope.
Determination of the encapsulated KP1019 content
The amount of encapsulated drug was determined by inductively coupled plasma mass spectrometry (ICP-MS) after microwave assisted digestion following a modified method from
Ratzinger et al.28 The microwave digestion was used to reduce
matrix effects during ICP-MS measurements caused by the
organic material. A 250 µL aliquot of freshly prepared nanoparticles was digested with 2 mL nitric acid (32% w/w, subboiled).
An established microwave program was used (microwave:
MLS-Ethos 1600, MLS, Germany), which is summarized in
Table 3.
The digested samples were diluted and the concentration of
ruthenium was determined using an Agilent 7500ce ICP-MS
(Agilent Technologies, Waldbronn, Germany) equipped with a
Cetac ASX-520 autosampler, a MicroMist nebulizer and nickel
cones. Samples were prepared by dilution to ppb-ranges with
2% HNO3 and the addition of an internal standard (In). The
ICP-MS parameters are given in Table 4. The average concentrations and standard deviation were calculated from the
different measured isotopes of Ru.
Stability and reproducibility of particle size
Three batches of freshly prepared Tween 80 nanoparticles were
investigated to determine the reproducibility in size and drug
loading. Reproducibility in nanoparticle size was determined
by measurement of the mean diameter and PDI by DLS. Furthermore, long-term stability studies, concerning size, were
Table 3 Microwave program used for digestion to determine the drug
content of the nanoparticles
Time [min]
Power [W]
Temperature [°C]
2
5
4
12
700
700
1000
1000
85
135
180
180
1102 | Dalton Trans., 2014, 43, 1096–1104
Table 4 ICP-MS parameters used to determine the Ru content of the
nanoparticles
Rf power [W]
Carrier gas [L min−1]
Make up gas [L min−1]
Plasma gas [L min−1]
Monitored isotopes of Ru [m/z]
Isotopes of internal standards In
Integration time/mass
Replicates
1500
0.88–0.93
0.19–0.21
15
100, 101, 102, 104
115
0.3
10
carried out in duplicate by the determination of the particle
sizes over a time period of 25 days.
Cell culture
The hepatocellular carcinoma cell line Hep3B and the colon
carcinoma cell line SW480 (both from American Type Culture
Collection, Manassas, VA) were used. SW480 were grown in
minimal essential medium (MEM) and Hep3B cells in RPMI
1640 medium. Both media were supplemented with 10% fetal
bovine serum. Cultures were regularly checked for Mycoplasma
contamination.
For cytotoxicity tests, cells were plated (2 × 104 cells per mL)
in 100 µL per well in 96-well plates and allowed to attach for
24 h. Drugs were added in another 100 µL growth medium
and cells exposed for 72 h. The proportion of viable cells was
determined by MTT assay following the manufacturer’s recommendations (EZ4U, Biomedica, Vienna, Austria). The cytotoxicity was expressed as IC50 values calculated from full dose–
response curves (drug concentrations inducing a 50%
reduction of cell survival in comparison to the control cultured
in parallel without drugs).
Measurement of intracellular oxidants
2′,7′-Dichlorofluorescein diacetate (DCF-DA) was used for the
detection of intracellular H2O2 and ROS such as OH• and
ROO•. DCF-DA stock solutions (33.4 mM) in DMSO were stored
at −20 °C. SW480 (2.5 × 105 cells per sample in phenol-free
Hanks balanced salt solution) were incubated with DCF-DA for
30 min. Subsequently, the nanoparticles were added at the
indicated concentrations. After incubation for another 30 min,
the mean fluorescence intensity was measured by flow cytometry using a BD LSR Fortessa Cytometer (Becton Dickinson
and Company, Franklin Lakes, New Jersey, USA). A concentration of 2 mM H2O2 was used as a positive control. Intracellular superoxide radical (O2•−) production was determined by
flow cytometry using the cell permeable dihydroxyethidium
(DHE).29 DHE enters the cells where it is oxidized by O2•− and
other intracellular components to form 2-hydroxyethidium
and ethidium both showing a red fluorescence.30 Cells (2.5 ×
105 per sample) were incubated for 1 h with the indicated drug
concentrations at 37 °C in phosphate buffered saline. After
30 min of drug treatment, 10 µM DHE were added and incubated for another 30 min at 37 °C. Antimycin A (10 µM) was
used as a positive control. Subsequently, the DHE fluorescence
(535/617 nm) was measured using a BD LSR Fortessa
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Cytometer (Becton Dickinson and Company, Franklin Lakes,
New Jersey, USA). The resulting histograms were quantified
using the Flowing Software (University of Turku, Finland).
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Electrospray ionization mass spectrometry (ESI-MS) studies
A stock solution was prepared by dissolving KP1019
(15 mg, 5.0 mM) in 9.75 mL acetone followed by the addition
of 0.25 mL dichloromethane. This solution was poured
under stirring into an aqueous phase prepared by dissolving
Tween 80 (50 mg, 7.6 mM) in MilliQ water (50 mL) and stirred
for 30 min at room temperature. The organic solvents were
evaporated under reduced pressure at 35 °C and the volume
was adjusted to 5 mL. The solution was incubated at 37 °C.
Samples were taken after 10 min, 4 h, and 25 h and diluted to
40 µM of KP1019 using MilliQ water–methanol (1 : 1) prior to
infusion into the mass spectrometer. The mass spectra were
recorded on an AmaZon SL ion trap instrument (Bruker Daltonics GmbH, Bremen, Germany) using the following parameters: flow 4 µL min−1, 126% RF level, trap drive 115.8, dry
temperature 220 °C, nebulizer 8 psi, dry gas 6 L min−1, capillary ±4.5 kV and average accumulation time 177 µs.
UV-Vis spectroscopy
UV-Vis spectra were recorded on an Agilent 8453 UV-Visible
spectroscopy system (Agilent Technologies, Germany) using the
same stock solution as for the ESI-MS studies. Aliquots of
100 µL were withdrawn after the following time points: 10 min,
4 h, and 25 h and diluted to 0.2 mM using MilliQ water. The
samples were measured in 10 mm path length quartz cuvettes.
Simultaneous electron spin resonance (ESR) and UV-Vis
spectroscopy
A stock solution of KP1019 (15 mg, 5.0 mM) and Tween 80
(50 mg, 7.6 mM) was prepared as the one used for ESI-MS
measurements. Volumes of 1.5 mL stock solution were incubated at 37 °C for 0 h, 4 h, 6 h, 15 h, 19 h and 24 h. After incubation, aliquots of 1 mL were used for UV-Vis spectroscopy
and 500 µL for ESR spectroscopy. UV-Vis spectra were recorded
in 1 cm quartz cuvettes on a Shimadzu Multispec MS1501. Aliquots for ESR spectroscopy were transferred in 1 mL syringes
(Braun Omnifix) with the Luer connector removed and frozen
at 77 K. Pellets of the frozen aliquots were transferred to a
quartz finger dewar for ESR analysis at 77 K. ESR spectra were
recorded on a Bruker EMX instrument and a TE102 cavity
using the following instrument settings: 9.453 GHz microwave
frequency, 50 mW microwave power, 2700 G center field,
3500 G sweep, 5 G modulation amplitude, 100 kHz modulation
frequency, 1 × 105 receiver gain, 626 G min−1 scan rate, 0.327 s
time constant, and one scan.
Acknowledgements
We thank Irene Herbacek for flow cytometry measurements,
Irena Pashkunova-Martic for helpful discussions, Sarah
Theiner for introduction to ICP-MS measurements and
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Paper
Daniela Gruber of the Core Facility Cell Imaging and Ultrastructure Research of the University of Vienna for the introduction and the usage of the TEM. This work was supported by
the exploratory focus “Functionalized Materials and Nanostructures” of the University of Vienna and performed with the
help of COST action CM1105 and the “PLACEBO” project
within the Genome Austria program.
References
1 A. Bergamo, C. Gaiddon, J. H. M. Schellens, J. H. Beijin
and G. Sava, J. Inorg. Biochem., 2012, 106, 90.
2 E. S. Antonarakis and A. Emadi, Cancer Chemother. Pharmacol., 2010, 66, 1.
3 N. Graf and S. J. Lippard, Adv. Drug Delivery Rev., 2012, 64,
993.
4 C. G. Hartinger, S. Zorbas-Seifried, M. A. Jakupec,
B. Kynast, H. Zorbas and B. K. Keppler, J. Inorg. Biochem.,
2006, 100, 891.
5 U. Jungwirth, C. R. Kowol, B. K. Keppler, C. G. Hartinger,
W. Berger and P. Heffeter, Antioxid. Redox Signaling, 2011,
15, 1085.
6 E. Reisner, V. B. Arion, B. K. Keppler and A. J. L. Pombeiro,
Inorg. Chim. Acta, 2008, 361, 1569.
7 L. Brannon-Peppas and J. O. Blanchette, Adv. Drug Delivery
Rev., 2012, 64, 206.
8 H. Maeda, H. Nakamura and J. Fang, Adv. Drug Delivery
Rev., 2013, 65, 71.
9 M. Hans and A. Lowman, Curr. Opin. Solid State Mater. Sci.,
2002, 6, 319.
10 O. Pillai and R. Panchagnula, Curr. Opin. Chem. Biol., 2001,
5, 447.
11 B. Mishra, B. B. Patel and S. Tiwari, Nanomed.: Nanotechnol.
Biol. Med., 2010, 6, 9.
12 S. G. Dixit, A. R. Mahadeshwar and S. K. Haram, Colloids
Surf., A, 1998, 133, 69.
13 J. U. Menon, S. Kona, A. S. Wadajkar, F. Desai, A. Vadla and
K. T. Nguyen, J. Biomed. Mater. Res., Part A, 2012, 100, 1998.
14 D. T. Birnbaum, J. D. Kosmala and L. Brannon-Peppas,
J. Nanopart. Res., 2000, 2, 173.
15 P. Heffeter, A. Riabtseva, Y. Senkiv, C. R. Kowol, W. Körner,
U. Jungwith, N. Mitina, B. K. Keppler, T. Konstantinova,
I. Yanchuk, R. Stoika, A. Zaichenko and W. Berger,
J. Biomed. Nanotechnol., 2013, 9, 1.
16 H. Fessi, F. Puisieux, J. P. Devissaguet, N. Ammoury and
S. Benita, Int. J. Pharm., 1989, 55, R1.
17 N. G. Portney and M. Ozkan, Anal. Bioanal. Chem., 2006,
384, 620.
18 T. Riley, T. Govender, S. Stolnik, C. Xiong, M. Garnett and
L. Illum, Colloids Surf., B, 1999, 16, 147.
19 A. Gomes, E. Fernandes and J. L. Lima, J. Biochem. Biophys.
Methods, 2005, 65, 45.
20 C. Bartel, A. E. Egger, M. A. Jakupec, P. Heffeter,
M. Galanski, W. Berger and B. K. Keppler, J. Biol. Inorg.
Chem., 2011, 16, 1205.
Dalton Trans., 2014, 43, 1096–1104 | 1103
�View Article Online
Open Access Article. Published on 11 October 2013. Downloaded on 5/2/2026 2:05:36 AM.
This article is licensed under a Creative Commons Attribution 3.0 Unported Licence.
Paper
21 V. Pichler, S. Göschl, S. M. Meier, A. Roller, M. A. Jakupec,
M. Galanski and B. K. Keppler, Inorg. Chem., 2013, 52,
8151.
22 Q. A. de Paula, A. A. Batista, O. R. Nascimento, A. J. da
Costa, M. S. Schultz, M. R. Bonfadini and G. Oliva, J. Braz.
Chem. Soc., 2000, 11, 530.
23 N. Cetinbas, M. I. Webb, J. A. Dubland and C. J. Walsby,
J. Biol. Inorg. Chem., 2010, 15, 131.
24 B. A. Kerwin, J. Pharm. Sci., 2008, 97, 2924.
25 P. Schluga, C. G. Hartinger, A. E. Egger, E. Reisner,
M. Galanski, M. A. Jakupec and B. K. Keppler, Dalton
Trans., 2006, 1796.
1104 | Dalton Trans., 2014, 43, 1096–1104
Dalton Transactions
26 K. Lipponer, E. Vogel and B. K. Keppler, Met.-Based Drugs,
1996, 3, 243.
27 C. E. Mora-Huertas, H. Fessi and A. Elaissari, Int. J. Pharm.,
2010, 385, 113.
28 G. Ratzinger, P. Agrawal, W. Körner, J. Lonkai,
H. M. Sanders, E. Terreno, M. Wirth, G. J. Strijkers,
K. Nicolay and F. Gabor, Biomaterials, 2010, 31, 8716.
29 N. M. Mustapha, J. M. Tarr, E. M. Kohner and R. Chibber,
J. Ophthalmol., 2010, 2010.
30 D. C. Fernandes, J. Wosniak Jr., L. A. Pescatore,
M. A. Bertoline, M. Liberman, F. R. Laurindo and
C. X. Santos, Am. J. Physiol.: Cell Physiol., 2007, 292, C413.
This journal is © The Royal Society of Chemistry 2014
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