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Luminescent ruffled iridium(iii) porphyrin complexes containing N-heterocyclic carbene ligands: structures, spectroscopies and potent antitumor activities under dark and light irradiation conditions.
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Luminescent ruffled iridium(III) porphyrin
complexes containing N-heterocyclic carbene
ligands: structures, spectroscopies and potent
antitumor activities under dark and light irradiation
conditions†
Tsz-Lung Lam, a Ka-Chung Tong,a Chen Yang, ab Wai-Lun Kwong,a
Xiangguo Guan,ab Ming-De Li, a Vanessa Kar-Yan Lo,a Sharon Lai-Fung Chan,‡c
David Lee Phillips,a Chun-Nam Lok*a and Chi-Ming Che*ab
A panel of iridium(III) porphyrin complexes containing axial N-heterocyclic carbene (NHC) ligand(s) were
synthesized and characterized. X-ray crystal structures of the bis-NHC complexes [IrIII(ttp)(IMe)2]+ (2a),
[IrIII(oep)(BIMe)2]+ (2d), [IrIII(oep)(IiPr)2]+ (2e) and [IrIII(F20tpp)(IMe)2]+ (2f) display ruffled porphyrin rings
with mesocarbon displacements of 0.483–0.594 Å and long Ir–CNHC bonds of 2.100–2.152 Å. Variabletemperature 1H NMR analysis of 2a reveals that the macrocycle porphyrin ring inversion takes place in
solution with an activation barrier of 40 � 1 kJ mol�1. The UV-vis absorption spectra of IrIII(por)–NHC
complexes display split Soret bands. TD-DFT calculations and resonance Raman experiments show that
the higher-energy Soret band is derived from the 1MLCT dp(Ir) / p*(por) transition. The near-infrared
phosphorescence of IrIII(por)–NHC complexes from the porphyrin-based 3(p, p*) state features broad
emission bands at 701–754 nm with low emission quantum yields and short lifetimes (Fem < 0.01; s < 4
ms). [IrIII(por)(IMe)2]+ complexes (por ¼ ttp and oep) are efficient photosensitizers for 1O2 generation (Fso
¼ 0.64 and 0.88) and are catalytically active in the light-induced aerobic oxidation of secondary amines
and arylboronic acid. The bis-NHC complexes exhibit potent dark cytotoxicity towards a panel of cancer
cells with IC50 values at submicromolar levels. The cytotoxicity of these complexes could be further
Received 3rd July 2018
Accepted 27th September 2018
enhanced upon light irradiation with IC50 values as low as nanomolar levels in association with the lightinduced generation of reactive oxygen species (ROS). Bioimaging of [IrIII(oep)(IMe)2]+ (2c) treated cells
indicates that this Ir complex mainly targets the endoplasmic reticulum. [IrIII(oep)(IMe)2]+ catalyzes the
photoinduced generation of singlet oxygen and triggers protein oxidation, cell cycle arrest, apoptosis
DOI: 10.1039/c8sc02920b
and the inhibition of angiogenesis. It also causes pronounced photoinduced inhibition of tumor growth
rsc.li/chemical-science
in a mouse model of human cancer.
Introduction
The recent years have witnessed a bloom in the applications of
metal–N-heterocyclic carbene (NHC) complexes in catalysis,1
materials science2 and medicine.3 These burgeoning research
a
State Key Laboratory of Synthetic Chemistry, Institute of Molecular Functional
Materials, HKU-CAS Joint Laboratory on New Materials and Department of
Chemistry, The University of Hong Kong, Pokfulam Road, Hong Kong, China.
E-mail: cmche@hku.hk
b
HKU Shenzhen Institute of Research and Innovation, Shenzhen, China
c
Department of Applied Biology and Chemical Technology, The Hong Kong Polytechnic
University, Hung Hom, Hong Kong, China
† Electronic supplementary information (ESI) available: Experimental procedures,
Tables S1–S8, Fig S1–S27. CCDC 1846458–1846461. For ESI and crystallographic
data in CIF or other electronic format see DOI: 10.1039/c8sc02920b
‡ Deceased 16 July 2017.
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activities have beneted greatly from improved knowledge
regarding the coordination chemistry of metal–NHC
complexes.4 Nonetheless, there are only a handful of examples
of metalloporphyrins bearing NHC ligand(s) thus far. In this
regard, the groups of Albrecht,5 Woo6 and Che7 have contributed to the synthesis and investigation of the spectroscopic
properties and/or catalytic activities of d6 metalloporphyrin
complexes of CoIII, RhIII, IrIII and RuII ions bearing axial NHC
ligand(s). Several characteristics of these metalloporphyrins
have been noted, including (1) gentle dearomatization of the
porphyrin ligand; (2) elongation of the axial metal–ligand bond
trans to the NHC ligand; and (3) pronounced ruffling of the
porphyrin ligand scaffold.5,6 The last feature, namely, NHCinduced ruffling deformation, is particularly intriguing
because the out-of-plane deformation of metalloporphyrin is
recognized to have a profound impact on its photophysical (e.g.,
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electronic absorption, emission, excited state dynamics) and
physiochemical properties (e.g., axial ligand affinity, electron
transfer rate), both of which have important implications in
biological processes involving the ubiquitous tetrapyrrole
compounds.8 While many studies on nonplanar metalloporphyrins have focused on metal ions of relatively small size,
such as NiII8a,9 and ZnII,10 and those with MnIII11 and FeIII,12 in
which nonplanarity is primarily induced by the peripheral
substituents of the porphyrin, fewer studies have been performed on axial ligand-induced porphyrin ring deformation in
d6 metalloporphyrins.5,6,13
The Soret and Q bands in the electronic absorption spectra of
metalloporphyrins of d6 RuII, OsII, RhIII and IrIII generally display
marked hypsochromic shis with respect to their free base
porphyrins due to dp(M)–p*(por) interaction.14 Axial ligand(s)
can also perturb the absorption spectra by modulating the
electronic properties of the metal ion and hence the metal–
porphyrin bonding interaction (cis-effect).14 The literature
reports that d6 metalloporphyrins display red to infrared phosphorescence derived from the 3(p, p*) IL state of the porphyrin
ligand or the 3(dp, p*) metal-to-ligand charge transfer (MLCT)
state upon photoexcitation.15 Nevertheless, only IrIII–porphyrin
complexes emit strong red to near-infrared (NIR) phosphorescence in solution at room temperature, with emission quantum
yields up to 0.30 and emission lifetimes up to 97 ms.16a–c Due to
these advantageous luminescence properties, the use of cationic
IrIII-oep-derived bioconjugates for cellular imaging and as
phosphorescent probes for intracellular oxygen sensing has
been reported by Papkovsky and co-workers.16b On the other
hand, two near-IR-absorbing BODIPY assemblies of IrIII–
porphyrin, recently reported by Shen, Chan, Mack and coworkers,16d have been shown to display excellent photostability
and efficiency in photosensitized singlet oxygen generation with
a quantum yield of up to 0.85.16d These encouraging ndings
have shed light on the potential photobiological uses of IrIII–
porphyrin complexes, which remain unexplored.
Here, we describe the synthesis and characterization of a panel
of luminescent ruffled iridium(III) porphyrin complexes containing
mono-NHC and bis-NHC ligand(s), namely, [IrIII(por)(NHC)Cl] (1a–
1d) and [IrIII(por)(NHC)2]+ (2a–2f), respectively. Steady-state and
time-resolved spectroscopic studies and theoretical calculations in
conjunction with resonance Raman spectroscopy were undertaken
to examine the effects of NHC ligation on the photophysical
properties and electronic structures of the IrIII–porphyrin
complexes. In addition, the photochemical reactivity via the lightinduced generation of singlet oxygen as well as the cytotoxicity and
phototoxicity of these bis-NHC iridium(III) porphyrin complexes
were investigated both in vitro and in vivo.
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porphyrin was accomplished by reacting bis(NHC)silver(I)
complex17 with [IrIII(por)Cl(CO)] via transmetalation. This
synthetic protocol offers the advantage that the reaction can be
conducted under mild, aerobic conditions. Mono-NHC
complexes [IrIII(por)(NHC)Cl] (1a–1d) were prepared by stirring a mixture of [IrIII(por)Cl(CO)] with half equivalents of the
respective bis(NHC)silver(I) complexes in CH2Cl2 at room
temperature for 12 h (Scheme 1). Aer the removal of AgCl salt by
ltration through a short plug of Celite (when por ¼ tmp, where
H2tmp ¼ meso-tetramesitylporphyrin) or a silica gel column
(when por ¼ F20tpp, where H2F20tpp ¼ meso-tetrakis(pentauorophenyl)porphyrin), the desired complexes were recrystallized from CH2Cl2/hexane and obtained in 60–74% isolated
yields. Bis-NHC complexes 2a–2f were similarly synthesized by
reacting stoichiometric amounts of bis(NHC)silver(I) complexes
with [IrIII(por)Cl(CO)] in CH2Cl2 at room temperature or at 40 � C
for 12 h to 4 days (Scheme 2). The complexes were then puried
by ash column chromatography on a silica gel column using
CH2Cl2/EtOAc as the eluent and were obtained in 70–96% isolated yields. [IrIII(oep)(CNPhOMe)2]+ (3) and [IrIII(oep)(py)2]+ (4)
were also prepared for comparative study (see (ESI†)).
The number of coordinated NHC ligands was revealed by the
1
H NMR and FAB-MS analyses of the complexes and is dependent
on the steric bulk of the porphyrin ligand. Specically, whereas
Scheme 1
Synthesis of [IrIII(por)(NHC)Cl] complexes 1a–1d.
Scheme 2
Synthesis of [IrIII(por)(NHC)2]+ complexes 2a–2f.
Results
Synthesis
The reported synthetic approaches to metalloporphyrin-NHC
complexes include the thermal decarboxylation of imidazolium carboxylate,5 deprotonation of the imidazolium salt with
a strong base7 and incorporation of the free imidazoylidene.6 In
this work, the coordination of NHC ligands to iridium(III)
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a 1 : 1 bis(NHC)silver(I) complex with [IrIII(por)Cl(CO)] (por ¼ ttp
or oep) recipe gave solely [IrIII(por)(NHC)2]+ complexes, the same
stoichiometry furnished only [IrIII(tmp)(NHC)Cl] and trace
[IrIII(tmp)(NHC)]+ complexes in the case of [IrIII(tmp)Cl(CO)]. The
reaction of bis(NHC)silver(I) complex with [IrIII(F20tpp)Cl(CO)] to
give [IrIII(F20tpp)(IMe)2]+ (2f) was completed at elevated temperature with extended reaction time (reuxing CH2Cl2 for 4 days).
The FAB-MS spectra of complexes 1a–1d all show peaks attributed to [M � Cl]+ fragments, suggesting that the Ir–Cl bond is
weakened by the trans-axial NHC ligand. The IR oxidation-state
marker bands of all complexes 1a–1d and 2a–2f fall into the
range of 1018–1022 cm�1, which is comparable to that of their
parental complexes [IrIII(por)Cl(CO)] and consistent with the iridium(III) oxidation state.18 Mono-NHC complexes 1a, 1b and 1d
are stable in the solid state and in CDCl3 solution for 1 week with
the exception of 1c, which decomposes within 1 day under
ambient conditions. Bis-NHC complexes 2a–2e are remarkably
air-stable in the solid state and in CDCl3 solution in the dark for 1
month, as revealed by 1H NMR spectroscopy and UV-vis absorption spectroscopy, except for 2f, which gradually deteriorates in
CDCl3 in 3 days.
X-ray crystal structures
The structures of 2a, 2d, 2e and 2f were determined by X-ray
diffraction analysis, and their perspective views are depicted
in Fig. 1. Selected bond distances and angles are summarized in
Table 1. All complexes adopt a slightly distorted octahedral
geometry, with the porphyrin ring exhibiting a signicant
ruffling deformation. The mean deviations of the mesocarbon
atom from the least square plane of the porphyrin ring in 2a, 2d,
2e and 2f are 0.483, 0.557, 0.561 and 0.594 Å, respectively. The
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Table 1
Selected bond lengths (Å) and bond angles (� ) of 2a, 2d, 2e
and 2f
Ir–CNHC1
Ir–CNHC2
Ir–Nmeana
CNHC1–Ir–CNHC2
a
2a
2d
2e
2f
2.140(17)
2.164(18)
2.027(11)
177.9(16)
2.128(3)
2.128(3)
2.023(3)
177.62(15)
2.151(5)
2.143(5)
2.147(16)
179.4(16)
2.080(3)
2.120(3)
1.985(17)
174.5(10)
Ir–Nmean is the average bond distance of four Ir–Npor bonds.
planes of the NHC ligands are slightly to moderately tilted with
respect to the Ir–CNHC axis. The mean pitch angles of the NHC
ligands (measurement of out-of-plane tilting) of 2a, 2d, 2e and
2f are 7.5� , 4.6� , 1.4� and 5.1� respectively. The pitch angle of 2a
is slightly larger than that of [IrIII(ttp)(IBuMe)Me] (6.4� ).6 The
ruffling deformation of the porphyrin ring combined with the
tilting of NHC ligands is considered to be a means to relieve the
unfavorable steric repulsion caused by the close proximity of the
NHC ligands and porphyrin ring. Ruffling deformation of
porphyrin rings has also been observed in other NHC-bearing
metalloporphyrin complexes.5,6 In all the X-ray crystal structures, the planes of the NHC ligands are approximately
orthogonal to each other, with an interplanar angle of 84.8� for
2a, 69.2� for 2d, 87.7� for 2e and 80.9� for 2f. The orientation of
NHC ligands with respect to Ir–Npor, described by the torsional
angle of NNHC–CNHC–Ir–Npor, has an average value of 40.3� for
2a, 35.0� for 2d, 43.5� for 2e and 37.0� for 2f. The near-staggered
orientation of the NHC ligands with respect to Ir–Npor suggests
minimal Ir–CNHC p bonding interaction.5a Evidently, the
arrangement of NHC ligands is related to the structural
requirement for ruffling deformation of porphyrin ligands.
Fig. 1 Perspective views of (A) [IrIII(ttp)(IMe)2]+ 2a, (B) [IrIII(oep)(BIMe)2]+ 2d, (C) [IrIII(oep)(IiPr)2]+ 2e and (D) [IrIII(F20tpp)(IMe)2]+ 2f at 30% probability of the thermal ellipsoid. Hydrogen atoms, cocrystallized solvent molecules and counteranions are omitted for clarity. Insets show the side
views of the porphyrin cores and the average mesocarbon displacements (Å) from the mean porphyrin planes.
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The average Ir–N distances of 2a, 2d, 2e and 2f are 2.027,
2.023, 2.017 and 1.985 Å, respectively, which are comparable to
those of other organoiridium(III) porphyrin complexes.16,19 The
mean Ir–CNHC distances of 2a, 2d, 2e and 2f are 2.152, 2.128,
2.147 and 2.100 Å, respectively, which are longer than those of
non-porphyrin-type Ir–NHC complexes reported in the literature.20 The elongated Ir–CNHC bond in the [IrIII(por)(NHC)2]+
complexes is a consequence of the combination of (1) the strong
trans inuence of the NHC ligands and (2) the unfavorable
steric interactions between the N-alkyl substituents on the NHC
ligands and the porphyrin ring. While the inuence of the Nalkyl groups of the NHC ligand on the Ir–CNHC distance is
marginal (cf. 2d vs. 2e), the change of the porphyrin from tpp to
F20tpp ligand reduces the Ir–CNHC distance by 0.052 Å (cf. 2a vs.
2f). In comparison, the Ir–CNHC distances in [IrIII(ttp)(IMe)2]+
(2a) are discernibly shorter than that reported in [IrIII(ttp)
(IBuMe)Me] (2.194(4)Å).6 This nding indicates that the methyl
ligand has a stronger trans inuence than NHC. In addition, the
extensive intermolecular p–p stacking interactions between the
molecules of 2d to form 1D polymeric chains are worth noting
(Fig. 2A). The neighboring BIMe ligands are parallel to one
another with an interplanar angle of 0� and a short interplanar
distance of 3.398 Å. Intriguingly, the intermolecular interactions have presumably led to the self-assembled brous structure of 2d observed by TEM upon precipitating the complex in
a THF/H2O (1 : 90, v/v) mixture (Fig. 2B).
NMR study
The 1H NMR spectra of all [IrIII(por)(NHC)Cl] and
[IrIII(por)(NHC)2]+ complexes show upeld signals of the N-alkyl
substituents on the NHC ligands at <0 ppm (TMS reference),
revealing the anisotropic effect of the porphyrin ring current
upon these alkyl groups. The static crystal structures of 2a, 2d,
2e, and 2f have two-fold symmetry due to the ruffling deformation of the porphyrin ligand. However, all iridium(III)
porphyrin complexes in this work display a pseudo-four-fold
symmetry in solution; both Hb (when por ¼ tmp, F20tpp or
ttp) and Hmeso (when por ¼ oep) appear to be singlet.
Metalloporphyrins are known to exhibit a variety of conformational dynamics in solution, and the dynamic processes
associated with porphyrin ligands include macrocyclic inversion, meso- and b-substituent rotation.21 For the related
[RhIII(tpp)(IMe)Cl] and [M(ttp)(IBuMe)Me] (M ¼ RhIII or IrIII)
Fig. 2 (A) The crystal packing diagram of 2b viewed along the b-axis
and an enlarged image of a pair of 2b molecules with an interplanar
distance of 3.398 Å. (B) TEM image obtained from THF/H2O (1 : 90, v/v)
mixture.
296 | Chem. Sci., 2019, 10, 293–309
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complexes, meso-aryl ring rotation about the Cmeso–CAr bond
was suggested to occur with the corresponding DGǂROT, which
measured 59–63 kJ mol�1.5b,6 In this work, the 1H NMR spectra
of 2a from 298 K to 193 K were recorded (Fig. 3) to study its
uxional behavior in solution. At 298 K, the Ho and Hm signals
of the meso-tolyl rings appear as two well-resolved doublets,
indicating that these nuclei are at their fast exchange limits. As
the temperature is lowered, the Ho signal broadens and
completely collapses (coalesces) at 223 K. Meanwhile, the Hm
signal broadens and coalesces at 208 K. At 193 K, four new sets
of signals from Ho and Hm have developed, though they are not
well resolved. Notably, the two Ho signals are anomalously split
by 1.4 ppm, with one of the Ho signals being farther upeld than
the Hm signals. With reference to the related VT 1H NMR study
of ruffled NiII–por complexes,9a the observed splitting of the Ho
signal at the low-temperature limit reveals a situation in which
half of Ho lies above the shielding region of the relatively
“frozen” porphyrin ring, which is in a ruffled conformation. The
chemical equivalence of Hb of ttp as well as of Ha and N–Me
from two IMe ligands is conserved, as these signals remain
singlets throughout the experiment. Considering the symmetric
bis-ligation and symmetry of the IMe ligand and the meso-tolyl
group, the observed temperature-dependent NMR behavior of
2a is associated with a single dynamic process in which
macrocyclic inversion is preferred over axial ligand rotation or
meso-tolyl ring rotation.22 From the coalescence temperature
and coalescence exchange rate (kexch) of the Ho and Hm signals,
the activation barrier of the ring inversion (DGǂROT) of 2a is
estimated to be 40 � 1 kJ mol�1. In addition, the reversible
binding of NHC ligand(s) to IrIII ion is suggested not to take
place at room temperature because the 1H signals from the
NHC ligand(s) (i.e., Ha and N–Me) remained unaltered
Fig. 3 Selected region of 1H NMR spectra (500 MHz) of
[IrIII(ttp)(IMe)2]+ 2a in CD2Cl2 from 298 K to 193 K. Asterisks (*) denote
residual CHDCl2 signal.
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throughout the VT 1H NMR experiment.6 The chemical shis of
Hb and Hmeso as well as of carbene CNHC are summarized in
Table 2. The chemical shi of Hb or Hmeso is a useful parameter
to assess the donor strength of the axial ligands.15c,23 For
instance, replacing a p-accepting CO ligand with a s-donating
NHC ligand in [IrIII(tmp)(L)Cl] and [IrIII(F20tpp)(L)Cl] results in
an upeld shi of the Hb signal by 0.30–0.43 ppm. The Hmeso
signals for the [IrIII(oep)(L)2]+ complexes differ by �0.9 ppm
for L ¼ isocyanide ligand (3) and �0.8 ppm for L ¼ pyridine
ligand (4) versus L ¼ NHC ligand (2c–2e). The Hb or Hmeso
signals for [IrIII(por)(NHC)Cl] and [IrIII(por)(NHC)2]+ complexes
bearing axial BIMe ligands are shied downeld by 0.04–
0.08 ppm compared to those of the IMe analogs, showing that
the latter is a stronger donor. The effect of the N-alkyl substituent on the NHC ligand was found to be insignicant, as
revealed by the Hmeso signals of 2c and 2e.
Table 3
Electrochemical data of 1–4a
Complex
[IrIII(tmp)(IMe)Cl]
[IrIII(tmp)(BIMe)Cl]
[IrIII(F20tpp)(BIMe)Cl]
[IrIII(ttp)(IMe)2]+
[IrIII(ttp)(BIMe)2]+
[IrIII(oep)(IMe)2]+
[IrIII(oep)(BIMe)2]+
[IrIII(oep)(IiPr)2]+
[IrIII(F20tpp)(IMe)2]+
[Ir(oep)(CNPhOMe)2]+
[Ir(oep)(py)2]+
1a
1b
1d
2a
2b
2c
2d
2e
2f
3
4
Ered (V)
Eox (V)
Eox � Eredc (V)
�1.91
�1.87
�1.31
�1.60
�1.48
�1.80
�1.78
�1.82
�1.77, �1.11
�1.86
�1.81
+0.51, +1.15
+0.54, +1.19
+1.12, +1.39
+0.73, +1.37b
+0.85,+1.45b
+0.72, +1.25
+0.79, +1.24b
+0.75, +1.29
+1.31
+0.72, +1.39b
+0.80, +1.44b
2.42
2.41
2.43
2.33
2.33
2.52
2.57
2.57
2.42
2.58
2.61
a
E1/2 (V vs. Ag/AgNO3, scan rate ¼ 100 mV s�1) in CH2Cl2 with 0.1 M
[nBu4N]PF6 as electrolyte at r.t.; E1/2 (Cp2Fe+/0) ¼ 0.14 V. b Epa of
irreversible wave. c Potential difference between the rst oxidation
and rst reduction.
Electrochemistry
The electrochemical data and cyclic voltammograms of
complexes 2a, 2e and 2f are displayed in Table 3 and Fig. 4,
respectively. The quasireversible/irreversible reduction waves of
these complexes appear at E1/2 ¼ �1.31–2.01 V (vs. Ag/AgNO3).
The rst reversible oxidation couple occurs at E1/2 ¼ +0.51–
+1.12 V, while the second quasireversible/irreversible oxidation
takes place at E1/2 ¼ +1.15–+1.45 V. To identify the site of the
rst oxidation and reduction of 2a, the spectroelectrochemistry
was studied. The UV-vis absorption spectra of 2a recorded at
various time intervals in the rst oxidation and reduction
display similar spectral characteristics; the intensity of the Soret
bands decrease considerably with the concomitant development of a broad IR-range absorption in the Q bands, ca.
700–1000 nm (Fig. 5). These spectral features are typical of the
p-radical cation or anion of the porphyrin ring.24 On the other
hand, the Eox � Ered values for the rst oxidation and rst
reduction of the [IrIII(por)(NHC)Cl] and [IrIII(por)(NHC)2]+
Table 2
Fig. 4 Cyclic voltammograms of 2a, 2e and 2f in CH2Cl2 (scan rate ¼
100 mV s�1).
Chemical shifts of Hb and Hmeso in CDCl3
Complex
dHba (ppm)
dHmesoa (ppm)
[IrIII(ttp)Cl(CO)]
[IrIII(tmp)Cl(CO)]
[IrIII(oep)Cl(CO)]
[IrIII(F20tpp)Cl(CO)]
[IrIII(tmp)(IMe)Cl]
[IrIII(tmp)(BIMe)Cl]
[IrIII(F20tpp)(IMe)Cl]
[IrIII(F20tpp)(BIMe)Cl]
[IrIII(ttp)(IMe)2]+
[IrIII(ttp)(BIMe)2]+
[IrIII(oep)(IMe)2]+
[IrIII(oep)(BIMe)2]+
[IrIII(oep)(IiPr)2]+
[IrIII(F20tpp)(IMe)2]+b
[IrIII(oep)(CNPhOMe)2]+
[IrIII(oep)(py)2]+
8.96
8.66
—
9.01
8.32
8.36
8.58
8.62
8.61
8.69
—
—
—
8.70
—
—
—
—
10.31
—
—
—
—
—
—
—
9.39
9.45
9.40
—
10.31
10.21
1a
1b
1c
1d
2a
2b
2c
2d
2e
2f
3
4
a
Values reported with reference to dH(Si(CH3)4) ¼ 0 ppm. b Measured
in CD2Cl2.
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UV-vis absorption spectral changes of 2a containing 0.1 M
[nBu4N]PF6 during the first oxidation (top) and first reduction (bottom).
Asterisk denotes an instrumental artifact.
Fig. 5
complexes fall in the range of 2.33–2.61 V, which are comparable to the conventional HOMO–LUMO gap of metalloporphyrin complexes.25 Thus, both the rst oxidation and rst
reduction are assigned to porphyrin-center processes. The E1/2
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values for the IMe complexes (1a, 2a and 2c) are less anodic
compared to the corresponding BIMe analogs (1b, 2b and 2d,
respectively; Table 5). This difference suggests that IMe is
a stronger donor ligand than BIMe, which is similar to the
ndings from the 1H NMR analysis. Nonplanarity of metalloporphyrins is known to engender cathodic shi of redox
potential.9b,d,10a,26 However, the effect of ruffling on redox
potential is negligible for 2c–2e because the redox potentials of
these complexes are comparable to those of the analogous bisisocyanide complex (3) and bis-pyridine complex (4), with DE
being less than 0.08 V.
Fig. 6 UV-vis absorption spectra of 2c, 3, 4 and [Ir(oep)Cl(CO)] in
CHCl3 (1 � 10�5 M).
UV-visible absorption spectroscopy
The UV-visible spectral data and photophysical data of 1–4 and
their parental [IrIII(por)Cl(CO)] complexes are summarized in
Table 4. The UV-vis absorption spectra of complexes 1a–1d,
which bear mono-NHC ligands, exhibit a moderately intense
absorption band at 367–371 nm in addition to a Soret band at
431 nm (1a and 1b, por ¼ tmp) or 426 nm (1c and 1d, por ¼
F20tpp) with one or two Q band(s) at 530–595 nm (Table 4). All
bis(NHC)iridium(III) porphyrin complexes 2 display two intense
Soret bands with peaks at 372–375 nm and 428–440 nm,
respectively, with lmax of the Q band spanning from 532 to
620 nm (Table 4). The separation of the two Soret bands of 1 and
2 is 54–66 nm. This type of absorption spectrum featuring two
Soret bands is classically termed a ‘hyperspectrum’.14,15c Fig. 6
compares a representative hyperspectrum from 2c to ‘normal’
spectra from [IrIII(oep)Cl(CO)], 3 and 4. The degree of ‘hyper
character’ can be evaluated by Dlog 3 between the two Soret
bands (i.e., the larger Dlog 3, the greater the ‘hyper character’
is). Thus, the hyper character of the bis-NHC complexes 2 is
generally stronger than that of the mono-NHC complexes 1.
Moreover, the hyper character appears to be a function of the
porphyrin ligand; Dlog 3 ranges from 0.36 for 2a and 2b (por ¼
ttp) to 0.11 for 2f (por ¼ F20ttp) and 0–0.06 for 2c–2e (por ¼ oep).
In addition to the presence of an extra Soret band, the Soret
and Q bands of the NHC complexes are broadened compared to
those of their parental [IrIII(por)Cl(CO)]. Moreover, a sizable
redshi of the low-energy Soret band is noted. For example, in
the oep series, the low-energy Soret band of 2c is redshied by
26, 34 and 41 nm versus those of [IrIII(oep)Cl(CO)], 3 and 4,
respectively. The same trend holds for the cases of 1c, 1d and 2f
versus their parental [IrIII(F20tpp)Cl(CO)] complex, where Dlmax
(redshi) are 12, 12 and 26 nm, respectively (Fig. S14†).
Complexes 1b, 1d, 2b and 2d, which contain BIMe ligand(s),
display an exclusive absorption of moderate intensity (log 3 ¼
4.41–4.63) at lmax ¼ 296–301 nm, which can be attributed to p
Table 4 UV-visible absorption and emission data of [IrIII(por)Cl(CO)] and 1–4
UV-vis absorption dataa
Emission dataa
Solution at 298 K
Complex
[IrIII(ttp)Cl(CO)]
[IrIII(tmp)Cl(CO)]
[IrIII(oep)Cl(CO)]
[IrIII(F20tpp)Cl(CO)]
[IrIII(tmp)(IMe)Cl]
[IrIII(tmp)(BIMe)Cl]
[IrIII(F20tpp)(IMe)Cl]
[IrIII(F20tpp)(BIMe)Cl]
[IrIII(ttp)(IMe)2]+
[IrIII(ttp)(BIMe)2]+
[IrIII(oep)(IMe)2]+
[IrIII(oep)(BIMe)2]+
[IrIII(oep)(IiPr)2]+
[IrIII(F20tpp)(IMe)2]+
[IrIII(oep)(CNPhOMe)2]+
[IrIII(oep)(py)2]+
�1
lmax nm
1a
1b
1c
1d
2a
2b
2c
2d
2e
2fd
3
4
(log 3)
309 (4.50), 422 (5.58), 533 (4.41), 567 (3.89)
311 (4.43), 422 (5.58), 533 (4.42), 564 (3.60)
342 (4.44), 403 (5.38), 518 (4.30), 549 (4.62)
329 (4.40), 414 (5.42), 526 (4.45), 557 (3.94)
345 (sh) (4.29), 368 (4.56), 431 (5.18), 542 (4.06), 593 (3.40)
301 (4.55), 367 (4.61), 431 (5.23), 545 (4.13), 592 (3.92)
346 (sh) (4.44), 371 (4.62), 426 (5.10), 533 (4.12)
296 (4.41), 346 (sh) (4.39), 369 (4.55), 426 (5.10), 535 (4.12)
374 (4.76), 438 (5.12), 547 (3.87), 620 (3.82) (br)c
297 (4.63), 372 (4.63), 437 (4.99), 564 (3.85) (br)d, 611 (3.87) (br)c
351 (sh) (4.52), 372 (4.86), 429 (4.89), 532 (4.10), 556 (4.01)
297 (4.42), 373, (4.76), 428 (4.82), 533 (4.03), 557 (3.95)
353 (sh) (4.49), 375 (4.82), 432 (4.82), 537 (4.09), 560 (4.02)
355 (sh) (4.63), 374 (4.89), 418 (sh) (4.72), 440 (5.00), 537 (4.13)
266 (4.70), 344(sh) (4.36), 395 (5.20), 515 (4.17), 547 (4.50)
388 (5.25), 507 (4.11), 539 (4.54)
lmax/nm (s/ms)
Fem [�10�2]
724 (47.2), 808 (sh)
721 (77.2), 800 (sh)
666 (83.3), 722 (sh)
676 (101.0), 746 (sh)
773 (1.8)
775 (2.3)
—b
729 (1.7), 811 (sh)
Nonemissive
Nonemissive
701 (2.7), 766 (sh)
701 (3.6), 765 (sh)
701 (1.9), 763 (sh)
754 (0.5), 829 (sh)
663 (124.7), 717(sh)
651(55.2), 711(sh)
0.16
0.22
5.03
2.92
0.05
0.06
—b
0.29
—
—
0.41
0.66
0.03
0.08
6.40
12.30
a
Measurements were performed in degassed CHCl3. b Complex 1d was unstable for emission measurements. c Broad absorption band spans from
ca. 510 to 670 nm. d Measurements were performed in degassed CH2Cl2.
298 | Chem. Sci., 2019, 10, 293–309
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/ p* transition of the BIMe ligand. The absorption lmax of the
Soret band is relatively insensitive to the NHC ligand (i.e., IMe,
BIMe, IPr), and Dlmax is less than 4 nm in all cases for
complexes with the same porphyrin scaffold. In addition, solvatochromism was found to be negligible for 2e (Table S2 and
Fig. S15†). The variation in lmax of the Soret and Q bands in
various solvents is less than 3 nm. These ndings indicate
predominantly porphyrin-based frontier molecular orbitals
(FMOs) for IrIII(por)–NHC complexes despite the nonplanarity
of the porphyrin ring.
TD-DFT calculations on split Soret bands
To unveil the nature of the split Soret bands, time-dependent
density functional theory (TD-DFT) calculations on the electronic transitions of 2a were performed. The geometry of the
ground-state singlet (S0) was optimized, and vertically excited
states were obtained via TD-DFT calculations. Notably, the
composition and spin density distribution of the FMOs of 2a are
in excellent agreement with the classical four-orbital model
proposed by Gouterman;14 the contributions from the
porphyrin ligand to HOMO�1, HOMO, LUMO and LUMO+1
amount to 99.8%, 95.5%, 97.5% and 97.7%, respectively
(Fig. 7A). The simulated UV-vis absorption spectrum of 2a,
which shows high resemblance to the one obtained experimentally, is depicted in Fig. 7B. The calculations show that the
Q bands at 565 nm originated mainly from HOMO / LUMO
(S1, 79%) and HOMO / LUMO+1 (S2, 79%), which can be
categorized as IL p / p* transitions of porphyrin. Nevertheless, assigning the nature of the transitions that constitute the
low-energy (412 nm, S7/S8) and high-energy Soret bands
(377 nm, S9/S10) is not straightforward, as both Soret bands
consist of several vertical transitions involving 4 to 6 pairs of
molecular orbitals. Accordingly, we examined the naturaltransition orbitals (NTOs), which can provide a much more
compact description of the excitations than the MOs. As listed
in Table S3,† the excitation S7/S8, which relates to the lowenergy Soret band, can be described as 68% porphyrin-based
p–p* transition and 32% MLCT, while S9/S10, in association
with the higher-energy Soret band, are attributed to MLCT
transition mixed with intraligand charge transfer (ILCT)
character.
Fig. 7 (A) Frontier molecular orbitals (HOMO�1, HOMO, LUMO and
LUMO+1), (B) simulated (solid line) and experimental (dashed line) UVvis absorption spectra of 2a (number in parenthesis is the experimental
abs lmax).
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Resonance Raman spectroscopy
Resonance Raman (RR) spectroscopy is an effective method to
probe the nature of an electronic transition because the vibrations associated with the resonant chromophore can be selectively enhanced.27 To help verify the parentage of the split Soret
bands, the RR spectra of 2a were recorded using excitation at
368.9 and 435.7 nm in MeCN. The former excitation wavelength
is within the higher-energy Soret band, while the latter excitation wavelength is covered by the lower-energy Soret band. The
experimental RR spectra and simulated ground-state Raman
spectrum of 2a from 1100–1800 cm�1 are shown in Fig. 8, and
the assignment of vibrational bands is listed in Table S4.† The
calculated Raman frequencies match well with the experimental
ones. The RR spectra exhibit different intensity enhancements
in response to excitation at 435.7 and 368.9 nm. The band at
1607 cm�1, which results from C–C bond stretching within the
tolyl rings and rocking of their hydrogen atoms without any
contribution from the pyrrole rings, appears only under excitation at 435.7 nm. The other two enhancements at 1240 and
1206 cm�1 also result largely from the vibrational modes of the
tolyl rings. The resonance in the excited state associated with
the low-energy Soret band (435.7 nm) enhances the vibrational
modes associated with tolyl rings more than those associated
with pyrrole rings. In the case of excitation at 368.9 nm, four
vibrational bands are relatively enhanced, namely, those at
1172, 1281, 1437 and 1521 cm�1. Vibrational mode analysis
shows that these four Raman bands all contain major components of the vibrational modes within the pyrrole rings. For
example, the Raman band at 1437 cm�1 is mainly from
symmetric stretching of the Ca–Cmeso–Ca bonds and bending
deformation of pyrrole rings, including rocking of the hydrogen
atoms within the pyrrole rings. Thus, the resonance in the
excited state associated with the higher-energy Soret band
enhances the vibrational modes in pyrrole rings more than
those in tolyl rings. The Raman bands that appear at 1356 and
1473 cm�1 under both excitation wavelengths (435.7 nm and
368.9 nm) are attributed to vibrational modes from both tolyl
rings and pyrrole rings.
Fig. 8 Resonance Raman spectra of 2a with excitation wavelengths of
(a) 435.7 nm and (b) 368.9 nm; (c) Raman spectrum of 2a calculated by
DFT.
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Nanosecond time-resolved absorption spectroscopy
The nanosecond time-resolved absorption difference (ns-TA)
spectrum of 2c, as a representative of bis-NHC complexes, is
examined, and the following spectral features are noted (Fig. 9,
top): (1) there are two intense positive absorption peaks at 388
and 468 nm, respectively, which are redshied from the groundstate double Soret bands; (2) a broad, moderately intense
positive absorption lies from ca. 550 nm to 800 nm. Indeed,
despite a marked redshi of the excited-state Soret band by over
30 nm and a shorter-lived triplet state decay (s468nm ¼ 2.6 ms),
the ns-TA spectrum of 2c resembles the spectral prole of its
counterparts 3, 4, and [IrIII(oep)Cl(CO)] (Fig. 9, bottom).
Normalized emission spectra of 2c, 3, 4 and [IrIII(oep)Cl(CO)] in
degassed CHCl3.
Fig. 10
Emission spectroscopy
Upon photoexcitation, complexes 1 and 2 (except 2a and 2b)
produce NIR emission with lmax spanning from 701 to 775 nm
in degassed CHCl3 solution (degassed CH2Cl2 for 2f) at room
temperature. The emission is assigned to the 3(p, p*) state of
porphyrin; the emission spectra generally feature a broad
though indistinct vibronic shoulder, akin to that of typical
phosphorescent metalloporphyrins.16,28 Several characteristics
can be noted for the emissions of complexes 1 and 2. (1) Their
emission bands are much broader and are redshied with
respect to those of their counterparts. For instance, the FullWidth-at-Half-Maximum (FWHM) for 2c is two to three times
greater than those of [IrIII(oep)Cl(CO)], 3 and 4 (i.e., 66 nm vs.
26, 19 and 20 nm, respectively). In addition, the emission lmax
of 2c is 701 nm, which is redshied by more than 35 nm
compared to those of its counterparts (Fig. 10). (2) The solution
emission quantum yields and lifetimes at room temperature are
substantially lower and shorter, respectively. For example, the
Fem values of 2c–2e supported by an oep ligand are only 0.03–
0.66%, and s ranges from 1.9 to 3.6 ms. This result is in stark
contrast to the observations of [IrIII(oep)Cl(CO)] and of the bisligand counterparts 3 and 4, all of which show long-lived (s ¼
55.2–124.7 ms) and strongly emissive 3(p, p*) states of porphyrin
(Fem ¼ 5.03–12.30%). Likewise, these observations hold for
complexes supported by F20tpp ligands 1d and 2f versus their
parent (Fem ¼ 0.08–0.29% vs. 2.92%; s ¼ 0.5–1.7 vs. 101.0 ms). (3)
Modication of NHC ligand exerts a negligible effect on both
the emission prole and emission lmax, as demonstrated for
2c–2e (Fig. S16†). (4) Increasing the number of NHC ligands, as
shown in the case of [IrIII(F20tpp)Cl(CO)], 1d and 2f, results in
a progressive redshi in the emission lmax from 676 to 754 nm
(Fig. S17†). (5) Varying the porphyrin ligand causes the emission
lmax to range from 701 to 775 nm, and lmax was found to
increase in the order oep < F20tpp < ttp z tmp. Similar ndings
have previously been reported for PdII- and PtII-porphyrin
complexes.28
Photochemistry
Recently, a panel of IrIII–porphyrin16d and IrIII–corrole29
complexes were found to be efficient singlet oxygen photosensitizers (Table 5).
In particular, the quantum yield of singlet oxygen production
(Fso) by BODIPY conjugates of IrIII-ttp upon excitation at 690 nm
is up to 0.85. In this work, [IrIII(por)(NHC)2]+ complexes were
also found to be highly efficient photosensitizers for singlet
oxygen production. With reference to the 1O2 emission intensity
(lmax ¼ 1270 nm) of H2tpp (Fso ¼ 0.55 in CHCl3),30 the Fso
values of oxygen-saturated CHCl3 solutions of 2a and 2c were
found to be 0.64 and 0.88, respectively, upon excitation at their
Soret bands (Fig. 11). As described in the previous section, upon
bis-ligation of the NHC ligand to iridium porphyrin, complexes
2 show redshied and broadened Soret and Q bands, resulting
in broad coverage of the visible light spectral region. This
Table 5 The quantum yield of singlet oxygen production (Fso) by 2a,
2c and reported IrIII–porphyrin and corrole complexes
(Top) The ns-TA spectra of 2c evolved from 0 to 7 ms; inset:
Decay kinetics of absorption difference at 468 nm. (Bottom) Overlaid
ns-TA spectra of 2c, 3, 4, and [Ir(oep)Cl(CO)] recorded at 0 ms.
Fig. 9
300 | Chem. Sci., 2019, 10, 293–309
Complex
Fso
2a
2c
[IrIII(corrole)(pyridine)2]
[IrIII(ttp)(aza-BODIPY)]
0.64a
0.88a
0.09–0.15a29
0.79–0.85b16d
a
Measured in CHCl3 with reference to the 1O2 emission intensity of
H2tpp. b Measured in CH2Cl2 with reference to the photooxidation of
1,3-diphenylisobenzofuran by methylene blue.
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Table 7 Light-induced aerobic oxidation of arylboronic acid catalyzed
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by 2ca
Fig. 11 Singlet oxygen emission spectra of H2tpp, 2a and 2c in
O2-saturated CHCl3.
spectral feature and the high singlet oxygen quantum yield
enable 2 to act as a photosensitizer for catalytic aerobic oxidation reactions and prompted us to examine the aerobic oxidation of secondary amines and arylboronic acids. When
a solution of dibenzylamine treated with 0.1 mol% of 2a was
bubbled with O2 under light irradiation (l > 400 nm) at room
temperature for 5 h, the corresponding imine was produced in
92% yield with complete substrate conversion (entry 1, Table 6).
Changing the photosensitizer to 2c led to a higher product yield
of 99% (entry 2, Table 6). The reaction also worked for
substrates with halogen/methyl substituted benzyl groups and
tert-butyl groups, furnishing the respective imine products in
96–99% yields (entry 3–5, Table 6). In another reaction, irradiating (l > 400 nm) solutions of para-substituted arylboronic
acids in the presence of diisopropylamine and 0.5 mol% of 2c
for 3 h at room temperature gave rise to the corresponding aryl
alcohols in yields of 82 to 99% (Table 7). The control experiments indicated the necessity of 2a or 2c for both reactions
(entry 6, Table 6; entry 6, Table 7). The mechanisms of the
photochemical reactions were investigated by experiments on
Entry
R
Convn. (%)c
Yield (%)d
1
2
3
4
5
6b
Cl
Br
CHO
Ph
CN
Br
100
100
100
100
100
<5%
92%
98%
98%
82%
99%
n.d.e
a
Reaction conditions: arylboronic acid (0.1 mmol), diisopropylamine
(0.4 mmol) and 2c (0.5 mmol) in DMF (1.5 mL), O2 bubbling, xenon
lamp (>400 nm). b No 2c added. c Determined by 1H NMR analysis of
the crude reaction mixture. d Determined by 1H NMR analysis using
1,1-diphenylethylene as an internal standard. e n.d. ¼ not determined.
the quenching of 2a or 2c. The presence of a large excess (1000
equiv.) of amine (i.e., dibenzylamine and diisopropylamine) or
arylboronicacid (i.e., 4-chlorophenylboronic acid) did not have
signicant effect on the lifetimes of the photogenerated 2a* and
2c* under degassed conditions (Fig. S19†). Nevertheless, the
lifetimes of 2a* and 2c* were considerably reduced to 0.16 ms
and 0.09 ms in oxygen-saturated solution, respectively (Fig. 12).
On the basis of these ndings, both photoinduced aerobic
amine oxidation and arylboronic acid oxidation reactions begin
with the oxygen quenching of photogenerated 2a*/2c* by energy
transfer to give 1O2, which subsequently oxidizes the secondary
amines to imines or the arylboronic acids to aryl alcohols.
Anticancer properties
We have previously reported various cationic metalloporphyrins,
particularly gold(III) porphyrins, and metal–NHC complexes that
Table 6 Light-induced aerobic oxidation of secondary amine to
imine, catalyzed by 2a or 2ca
Entry
PS
X/R
Convn.b (%)
Yieldc (%)
1
2
3
4
5
6
2a
2c
2c
2c
2c
—
H/Bn
H/Bn
Cl/tBu
Br/tBu
Me/tBu
H/Bn
100
100
100
100
100
<5%
92%
99%
99%
99%
96%
n.d.d
a
Reaction conditions: dibenzylamine (0.1 mmol) and catalyst
(0.1 mmol) in MeCN (1.5 mL), O2 bubbling, xenon lamp (>400 nm).
b
Determined by 1H NMR analysis of the crude reaction mixture.
c
Determined by 1H NMR analysis using 1,1-diphenylethylene as an
internal standard. d n.d. ¼ not determined.
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Nanosecond time-resolved absorption difference spectra of
2a in O2-saturated MeCN (top) and 2c in O2-saturated DMF (bottom).
Inset: decay kinetic of absorption difference at 490 nm (top) and
470 nm (bottom).
Fig. 12
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exhibit promising anticancer and antitumor activities.31 In this
work, iridium(III) porphyrin complexes bearing NHC ligand(s)
were found to be stable against ligand exchange with DMSO
or glutathione up to an 24 h incubation, as determined by UPLCQTOF mass spectrometry (Fig. S21 and S22†). DMSO-substituted
forms (ca. 8%) were found for 3 (Fig. S21f†). All of the cationic
iridium(III) complexes exhibit potent cytotoxicity towards a panel
of human cancer cell lines with submicromolar IC50 values, while
3 shows generally reduced cytotoxicity (Table 8). Among the bisNHC complexes, the higher cellular uptake of 2c (with octaethylporphyrin) than that of 2a (with meso-tetratolylporphyrin)
and 2f (with meso-tetrakis(pentauorophenyl)porphyrin) results
in higher cytotoxicity towards different cancer cell lines. In
addition, the charge-neutral [IrIII(oep)Cl(CO)], which showed the
lowest cellular uptake and lipophilicity, is relatively noncytotoxic,
with an IC50 value >50 mM to all the cancer cell lines. These
ndings highlight that the cationic character and porphyrin
scaffold of iridium(III) bis-NHC complexes are crucial for facilitating efficient accumulation in cells for anticancer activities. On
the basis of the potent in vitro cytotoxicity of 2c, its in vivo antitumor properties were examined. Nude mice bearing NCI-H460
human non-small cell lung cancer xenogras were administered 2c (3 mg kg�1) via intravenous injection thrice weekly. The
tumor size was reduced by 41% aer a 16 day treatment without
apparent toxicity, including body weight loss and death (Fig. 13).
In view of the advantageous photophysical properties (including
high emission quantum yield and long-lived electronic excited
state) of 2c among the bis-NHC iridium(III) complexes, cellular
imaging of 2c was performed to examine its subcellular localization in NCI-H460 cells. As shown in Fig. 14A, the resulting
images clearly revealed that the red-emitting 2c mainly colocalized with the green-emitting stain of the endoplasmic reticulum (ER-Tracker) with a high Pearson's correlation coefficient
(R) of 0.903. In contrast, a relatively poor overlap was observed
between the uorescence images of the complex and MitoTracker green or Lyso-Tracker green, with an R-value of 0.548
and 0.210. These ndings indicated that 2c accumulated mainly
In vivo antitumor activity of complex 2c in nude mouse model
bearing NCI-H460 xenograft. (A) Tumor volume and (B) body weight
of mice. Data are expressed as the mean � standard error; *p < 0.05.
Fig. 13
in the ER and only somewhat in the mitochondria or lysosome in
NCI-H460 cells. We therefore examined if 2c induced ER stress to
the NCI-H460 cells.32 By the western blot analysis, the ER stressassociated proteins including CHOP and phosphorylated eIF2a
were found to be dose- and time-dependently upregulated upon
treatment with 2c compared to the DMSO vehicle (Fig. 14B),
conrming the induction of ER stress. The impact of 2c on
mitochondria was also examined by monitoring the changes in
mitochondrial membrane potential (MMP, DJm). With the use
of a MMP-dependent ratiometric uorescence probe (JC-1), timedependent decrease in MMP of NCI-H460 cells was shown upon
the treatment of 2c, as indicated by the progressive change in
uorescence from red to green compared with DMSO vehicle
(Fig. 14C).
Photocytotoxicity
Prompted by the nding that the iridium(III) porphyrin
complexes are excellent singlet oxygen photosensitizers, we
examined their photocytotoxicity. NCI-H460 lung cancer cells
incubated with the complexes were exposed to a low dose of
visible light irradiation (2.8 mW cm�2) for 1 h. The cytotoxicity
of the iridium(III) porphyrin complexes increased markedly by
10- to 27-fold upon irradiation, and [IrIII(oep)(IiPr)2]+ (2e)
Table 8 In vitro cytotoxicity of the selected iridium(III) porphyrin complexes against a panel of human cancer cell linesabc
IC50 (mM)b
1d0
2a
2c
2e
2f
3
4
[IrIII(oep)Cl(CO)]
Cisplatin
IC50 (mM)
HeLa
HepG2
MCF-7
HCT116
HCC827
NCI-H460
(dark)
NCI-H460
(light)
PIc
Uptaked
Log Pe
0.37 � 0.10
0.17 � 0.1
0.03 � 0.01
0.10 � 0.1
0.10 � 0.1
7.9 � 0.5
0.10 � 0.01
>50
3.80 � 0.51
1.60 � 0.21
2.1 � 0.3
0.93 � 0.1
2.4 � 0.2
0.94 � 0.1
>100
1.32 � 0.10
>50
6.18 � 0.82
0.71 � 0.04
0.65 � 0.2
0.16 � 0.1
0.73 � 0.5
0.26 � 0.1
>100
0.12 � 0.02
>50
13.20 � 1.03
0.42 � 0.06
0.14 � 0.04
0.14 � 0.1
0.11 � 0.03.
0.4 � 0.2
23 � 3.3
0.25 � 0.08
>50
6.94 � 0.54
0.55 � 0.11
2.29 � 0.50
1.1 � 0.3
0.69 � 0.01.
1.23 � 0.10
50 � 3.6
1.27 � 0.32
>50
9.61 � 0.81
0.46 � 0.10
1.22 � 0.03
0.15 � 0.05
0.16 � 0.04
0.31 � 0.04
2.9 � 0.02
0.11 � 0.005
>50
3.96 � 0.48
0.04 � 0.003
0.11 � 0.08
0.009 � 0.004
0.006 � 0.002
0.03 � 0.002
0.12 � 0.02
0.005 � 0.001
19.70 � 1.0
4.61 � 0.31
11.5
11.1
16.7
26.7
10.3
24.2
23.1
>2.5
0.86
235.9 � 9.81
147.6 � 6.4
309.7 � 46.7
158.7 � 29.5
131.3 � 10.2
116.2 � 20.6
305.1 � 57.2
34.1 � 2.8
—
2.67
3.03
2.96
3.23
2.76
3.11
2.83
2.38
—
a
HeLa, cervical epithelial carcinoma; HepG2, hepatocellular carcinoma; MCF-7, breast carcinoma; HCT-116, colorectal carcinoma; HCC827, nonsmall cell lung carcinoma; NCI-H460, non-small cell lung carcinoma. b IC50 values were examined by MTT assay aer incubation of drugs for 72 h.
PI ¼ IC50(dark)/IC50(light). d Cellular uptake was determined by the iridium content (mg) in the cellular proteins (g) aer treatment of the NCIH460 cells with each complex (1 mM) for 2 h. e Lipophilicity was determined by measuring the ratio of the amount of iridium (mg) in each
complex partitioned in n-octanol and saline solution (0.9%, w/v).
c
302 | Chem. Sci., 2019, 10, 293–309
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Fig. 14 (A) Confocal microscopy imaging of NCI-H460 cells treated
with complex 2c (1 mM; lex ¼ 555 nm, lem ¼ 650–750 nm) for 2 h and
organelle trackers, including ER-Tracker green, Mito-Tracker green
and Lyso-Tracker green (50 nM, lex ¼ 488 nm, lem ¼ 500–530 nm) for
15 min. The merged images of red and green channels, and the bright
field were also shown. Scale bar: 20 mm. (B) Western blot analysis of ER
stress protein markers in NCI-H460 cells after treatment with 2c in
time- and dose-dependent manner. (C) Effect of 2c (1 mM) on mitochondrial membrane potential (MMP) analyzed by the fluorescence
ratio of NCI-H460 cells stained with JC-1 (lex ¼ 488 nm, lem ¼ 530 nm
(green) and 585 nm (red)). Treatments with carbonylcyanide
m-chlorophenylhydrazone (CCCP, 50 mM, 10 min) and DMSO were
served as positive and vehicle controls, respectively.
showed the largest enhancement among the complexes examined (Table 8 and Fig. S23†). [IrIII(oep)(IMe)2]+ (2c),
[IrIII(oep)(IiPr)2]+ (2e) and [IrIII(oep)(py)2]+ (4) exhibited very
potent cytotoxicity with nanomolar IC50 values. For the monoNHC complex [IrIII(F20tpp)(BIMe)(NH3)]+ (1d0 ), signicant
potentiation of the cytotoxicity was also found under the same
conditions. The cytotoxicity of [IrIII(oep)Cl(CO)] was also evaluated for comparison. This complex is relatively noncytotoxic in
the dark with an IC50 value >50 mM and increased to 19.7 �
1.0 mM upon visible light irradiation. For cisplatin, the difference in the phototoxicity index (PI) was <1, indicating an
absence of photoinduced cytotoxicity under our experimental
conditions. Thus, the cytotoxicity of the iridium(III) porphyrin
complexes with the incorporation of axial bis-carbene ligands is
signicantly enhanced under light irradiation.
To examine the relationship between photocytotoxicity and
the photosensitizing properties of the complexes, we measured
the cellular reactive oxygen species (ROS) generation using the
ROS probe H2DCF-DA aer treatment of cancer cells with the
iridium(III) porphyrin complexes. As shown in Fig. 15A, no
signicant change in DCF uorescence was observed in NCIH460 lung cancer cells incubated with the complexes in the
dark. Exposure to visible light irradiation resulted in increased
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Fig. 15 (A) Generation of ROS examined by DCF fluorescence
measurement in NCI-H460 cells treated with or without iridium(III)
porphyrin complexes (1 mM) for 2 h with or without irradiation by visible
light. (B) Confocal microscopy imaging of ROS generation in cells
incubated with complex 2c with or without irradiation by visible light.
Scale bar: 20 mm. (C) Photooxidation of peptide from thioredoxin by
2c. ESI-MS/MS spectra of the triply charged disulfide-bridged peptide
(m/z 421.8638; top) and oxidized peptides (m/z 427.1954; middle, m/z
433.1978; bottom). Fragments with blue labels indicate sites of disulfide bond formation, and red labels represent oxidative modification
sites.
DCF uorescence intensity, revealing elevated cellular ROS
levels. In particular, a 10-fold elevation in ROS levels in cells
treated with 2c was observed. The result was further corroborated by the strong green uorescence observed from DCF when
cells were treated with 2c followed by light irradiation (Fig. 15B).
These results conrmed the generation of ROS, possibly 1O2, in
NCI-H460 cells treated with Ir(III) complexes upon visible light
irradiation. We further examined the possibility of protein
oxidation as a consequence of photoinduced oxidative stress
caused by 2c. A peptide (RIMKCPGCWTA) from thioredoxin
(Trx) was employed as a model to investigate the possible
oxidative modication sites by electrospray ionization tandem
mass spectrometry (ESI-MS/MS). The peptide was found to
undergo oxidative modications in the presence of 2c upon
irradiation. Three different types of oxidized products,
including the formation of a disulde bridge and the oxidation
of the sulfur atoms of cysteine and methionine, were characterized (Fig. 15C, S25 and Tables S6–S8†). The peptide alone as
a control was shown to remain unchanged when incubated in
the dark or upon light irradiation (Fig. S24 and Table S5†). As
shown in Fig. 15C and S25,† three triplycharged species were
detected with mass differences of �0.671 (top), +4.660 (middle)
and +10.662 (bottom) Da, respectively, from the unmodied
peptide. Further MS/MS analysis revealed that the most intense
peak (m/z 421.8638; Fig. 15C (top), Table S6†) corresponds to the
formation of an intramolecular disulde bond, in which the
resulting fragment y5 and y8 ions bearing free cysteine and
cysteine thioaldehyde residues, respectively, were observed
when comparing with the peptide alone (Fig. S26†).
Moreover, additional oxidative modication of the methionine residue to give sulfoxide (y3) with a shi of +16 Da was also
found on the disulde-bridged peptide (m/z 427.1954; Fig. 15c
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(middle), Table S7†). In addition, another oxidation product
(m/z 433.1978) with a mass increment of +10.662 in a triply
charged state is ascribed to the addition of two oxygen atoms
(+32 Da) in the singly charged species. MS/MS sequence analysis
displayed the identied y-ions, which are attributed to the
oxidized methionine (y3; O-Met, Met +16 Da) and cysteine (y8;
O-Cys, Cys +16 Da) of the peptide (Fig. 15c (bottom) and Table
S8†). These results show that treatment with 2c combined with
light activation promoted the oxidation of cysteine and methionine residues through a singlet oxygen-mediated mechanism.
To examine the photoinduced cytotoxicity, the apoptotic cell
death and cell cycle progression of the cancer cells treated with
2c and visible light irradiation were analyzed by ow cytometry.
NCI-H460 cells were incubated with 2c at 0.1 mM, a concentration that could not lead to strong antiproliferative effects in the
dark. Upon exposure to light irradiation, the proportion of cells
treated with 2c undergoing apoptotic cell death increased from
5.9% to 81.7%, as shown by the annexin-V-FITC/propidium
iodide assay (Fig. 16A). On the other hand, complex 2c
(0.1 mM) did not exhibit a marked effect on the progression of
the cell cycle in the dark, showing only a mild increase in the
G0/G1-population from 59.6% to 66.3%. In agreement with the
annexin-V/propidium iodide ow cytometry results above,
visible light irradiation led to a signicant increase in the subG1 population (from 2.2% to 96.9%) as a result of extensive DNA
fragmentation due to cell death (Fig. 16B). We also examined
the antiangiogenic property of 2c in the inhibition of endothelial cell tube formation. As shown in Fig. 16C, moderate inhibition of MS-1 cell tube formation was observed aer treatment
of the complex in the dark, while tube formation was completely
abrogated upon light irradiation. The above results showed that
a low dose of 2c causes very low-level cellular damage in the
dark but could induce pronounced apoptosis and inhibition of
angiogenesis upon visible light irradiation. Noticeably, other
iridium porphyrin complexes were also observed to exert similar
effects (Fig. S27–S29†). The in vivo photoinduced therapeutic
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efficacy of 2c was also examined. NCI-H460 tumor-bearing mice
were divided into four groups, vehicle control, 2c (3.0 mg kg�1),
vehicle control with irradiation, and 2c (3.0 mg kg�1) with
irradiation, and subjected to two intratumoral injections of the
compounds in a period of 15 days. Mice in the irradiation
groups were injected with 2c or solvent vehicle followed by
exposure of the tumor site to white light (400–800 nm) at
a power density of 110 mW cm�2 for 30 min on the rst and
seventh days. The other two groups of mice received the same
treatment without irradiation as a control. As shown in Fig. 17A,
the tumor growth of mice treated with 2c and irradiation was
markedly decreased by 72% in comparison to that of the vehicle
Fig. 17 In vivo antitumor effects of complex 2c in nude mouse model
bearing NCI-H460 lung cancer xenografts. (A) Tumor volume. (B) Body
weight of mice. (C) Tumor weight after the experiment. Red arrows
indicate the injection of the mice with 2c together with irradiation on
day 0 and day 7. (D) Photo of tumors of each group after treatment for
15 days. Data are expressed as the mean � standard error; **p < 0.01.
Fig. 16 Anticancer properties of 2c (0.1 mM) upon visible light irradiation. (A) Apoptosis/necrosis in NCI-H460 cells as examined by flow
cytometry of annexin-V-FITC/propidium iodide-stained cells. (B) Cell cycle progression in NCI-H460 cells as examined by flow cytometry. (C)
Inhibition of angiogenesis of MS-1 endothelial cells.
304 | Chem. Sci., 2019, 10, 293–309
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group with light irradiation aer only two injections. In
contrast, treatment with 2c without irradiation was able to
inhibit tumor growth by only 41%. All of the mice displayed
negligible changes in body weight throughout the treatment
period (Fig. 17B). Moreover, the tumor weight of 2c-treated mice
in the photoirradiation group was found to be much lower than
that in the dark control group (Fig. 17C and D), demonstrating
the markedly enhanced antitumor efficacy of the combination
of dark and photoinduced tumor inhibitory activities.
Discussion
The coordination of the NHC ligand to IrIII–porphyrins causes
several major alterations to the spectral and photophysical
parameters compared to those of the [IrIII(por)Cl(CO)]
and [Ir(por)L2]+ (L ¼ isocyanide, pyridine or imidazole)
complexes.16a
Split Soret band
All NHC complexes in this work feature two distinct Soret bands
with comparable intensity. Metalloporphyrins showing split
Soret bands are classically termed hyperporphyrins.14,15c The
valence of the metal ions and the nature of the axial ligand(s)
are known to dictate this spectral attribute. Hyperporphyrins
can be divided into p-type and d-type. In d-type hyperporphyrins, which are relevant to our case, the metal ions are
generally trivalent or at a higher oxidation state with low metal
reduction potential and partially lled dp orbitals. As a result,
the extra Soret band is attributed to the ring-to-metal LMCT
transition of a1u(p),a2u(p) / eg(dp) character. Metalloporphyrins of FeIII, MnIII and CrIII ions are canonical examples
of this type.14 However, this scenario is not applicable to 1 and 2,
which contain a d6 IrIII ion, because all nominal dp (dxz, dyz)
orbitals are fully occupied, and no such LMCT transition can
take place in the UV-visible spectral region. Notably, the double
Soret band found in d6 metalloporphyrin is not unique to our
Ir–NHC system; a few IrIII- and RhIII-porphyrin complexes
bearing phenyl(alkoxycarbonyl)carbene or NHC with a trans
methyl ligand, recently described by Woo and co-workers, also
exhibit this spectral attribute.6,33 Woo and co-workers suggested
that orbital mixing with relatively low-energy doubly excited
states, [eg(dp)]3[a1u(p),a2u(p)]3[eg(p*)]2, may be responsible for
the extra Soret band. Our TD-DFT calculations on 2a indicated
that the high-energy (extra) Soret band mainly comes from
electronic transitions from the hybrid of the iridium dxy orbital
and the p orbitals of the porphyrin's peripheral tolyl groups to
the core p* porphyrin orbitals (pyrrole rings + mesocarbons),
which is best described as an MLCT transition with mixed ILCT
character, while the low-energy (conventional) Soret band
mainly comes from p / p* IL transitions within the porphyrin
ligand. Based on RR experiments, the independent excitation of
2a at the extra Soret band (435.7 nm) and at the conventional
Soret band (368.9 nm) results in the selective enhancement of
different vibrational modes, corroborating that the excited
states associated with the two bands have different characteristics. In particular, the former (MLCT) excitation primarily
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enhances vibrational modes involving the core skeleton to
which the Ir(III) ion is directly linked, while the latter (p–p*)
excitation enhances mainly the vibrational modes within the
tolyl rings to which the porphyrin core is connected. Overall, the
experimental ndings from the RR study of 2a concur with the
conclusion from DFT calculations that the extra Soret band is
associated with an Ir-to-porphyrin MLCT excitation.
Interestingly, the intensity of the MLCT band is found to vary
with the number of NHC ligands, as exemplied in the series
[IrIII(F20tpp)Cl(CO)] (log 3MLCT ¼ 0), [IrIII(F20tpp)(IMe)Cl] (1c)
(log 3MLCT ¼ 4.62) and [IrIII(F20tpp)(IMe)2]+ (2f) (log 3MLCT ¼
4.89). Thus, NHC ligands play an indispensable role in
enhancing the allowedness of the MLCT transition. Notably, the
extra Soret band (LMCT band) of high-spin [MnIII(tpp)]+
complexes, typical d-type hyperporphyrins, also displays
comparable intensity to their ‘conventional’ p–p* Soret
band.14,34 This observation was explained by the fact that the
high-lying dp(dxz, dyz) orbitals of the MnIII ion can undergo
substantial interaction with the porphyrin eg(p*) orbitals due to
their energetic proximity, which leads to strong mixing of the
p(por) / dp(MnIII) LMCT and Soret p–p* states.14,33 Thus, we
propose that in our case, the strongly electron-donating NHC
ligand(s) can boost the Ir dp orbitals to a higher level at which
they can mix efficiently with the porphyrin p* orbitals. This
phenomenon in turn enables borrowing of the oscillator
strength from the Soret p–p* transition to enhance the allowedness of the MLCT transition. In fact, the intensity of the
MLCT Soret band increases at the expense of the p–p* Soret
band from [IrIII(F20tpp)Cl(CO)], 1c to 2f with log 3MLCT/log 3Soret
values of 0/5.42, 4.62/5.10 and 4.89/5.00, respectively. Incidentally, the possibility that ruffling deformation also contributes
to enhancing the MLCT band intensity cannot be ruled out, as
all reported IrIII- and RhIII-porphyrin complexes with such an
extra Soret band were found or calculated to have a ruffled
porphyrin ring.5b,6,33
Spectral redshi, reduced emission quantum yield and
lifetime
The ruffled porphyrin ring, as revealed by X-ray crystallographic
analysis, is a key structural feature of [MIII(por)-NHC] (M ¼ Ir
and Rh) complexes.5b,6 Here, the extent of ruffling increases with
the number of NHC ligands owing to the enhanced steric
congestion. In the literature, out-of-plane ring deformation in
the form of either ruffling or saddling is well documented to
engender a spectral redshi in both free base porphyrins and
metalloporphyrins; the extent of redshi is usually proportional
to the magnitude of distortion, albeit in a nonlinear fashion.8 In
addition, metalloporphyrins with deformed porphyrin rings are
known to undergo rapid macrocyclic inversion in both the
ground state and the excited state. This inversion generally
leads to diminished luminescence and emission lifetime
compared to those of planar metalloporphyrins as a result of
the surging nonradiative decay activities in the form of lowenergy out-of-plane vibrations in the excited state.8a,e,9c Indeed,
the mono- and bis-NHC complexes of Ir(III)-porphyrin in this
work exhibit the aforementioned photophysical attributes of
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nonplanar metalloporphyrins; their Soret and Q bands and
their porphyrin-based 3(p, p*) emissions are markedly
redshied by up to 80 nm with respect to the parental [IrIII(por)
Cl(CO)] complexes and bis-ligand analogs (Table 4; Fig. 6 and
10). Furthermore, the emission quantum yield and lifetime
drop to less than 0.7% and 3.6 ms respectively, with the bis-NHC
analogs suffering more severely. As revealed by the excited-state
photophysical parameters in Table 9, the increase in the nonradiative decay constant of the emissive excited state of up to
200 times underlies the decrease in emission quantum yield
and lifetime, although the radiative decay rate constants
increase slightly by 3–14-fold.
Photosensitized singlet oxygen generation
Metalloporphyrins and their derivatives, such as metallocorroles, are important classes of photochemical singlet
oxygen sensitizers that exhibit good biocompatibility, strong
visible light absorption, high triplet-state quantum yields and
long triplet-state lifetimes.29,35 They have been extensively
studied as sensitizers for photodynamic therapy and photodriven aerobic oxidation reactions.28c,36,37 Several iridium(III)porphyrin and corrole complexes have recently been found to
exhibit such favorable inherent properties and are capable of
generating singlet oxygen photochemically.16d,29 In particular,
two s-bonded aza-BODIPY complexes of IrIII(ttp) were reported
to have Fso values of 0.79 and 0.85, which are more than 100
times greater than those of the respective free aza-BODIPY
ligands, revealing the effectiveness of the iridium(III)
porphyrin moiety in promoting singlet oxygen sensitization.
Two cationic bis-NHC complexes examined in this work, 2a
and 2c, were found to be efficient photosensitizers for the
photoinduced aerobic oxidation of secondary amines and arylboronic acids. Quenching experiments suggested that singlet
oxygen generated by quenching of the excited state of 2a or 2c is
presumably the active oxidant for these photooxidation reactions. This nding is in good agreement with their high Fso
values of 0.64 and 0.88, respectively. The singlet oxygen
quantum yield of a photosensitizer is determined by the tripletexcited-state quantum yield and the efficiency of energy transfer
Table 9
from the triplet excited state to molecular oxygen.35a Considering that the heavy iridium ion with its large spin orbit
coupling constant (xIr ¼ 3909 cm�1) oen confers an ultrafast
intersystem crossing rate and triplet-excited-state formation
yield close to unity,38 the higher singlet oxygen formation
quantum yield of 2c than of 2a is attributed to the former having
a longer triplet-state lifetime (s ¼ 2.3 vs. 0.4 ms) (Fig. S19†).
Stability, cytotoxicity and photochemical activities
Our previous works showed that porphyrin ligand can stabilize
gold(III) ion against demetallation under physiological conditions rendering gold(III) porphyrins to display effective anticancer activity against multiple cancer cell types in vitro and in
vivo.31a–d We have also found that as a result of strong sdonating property of NHC ligand, pincer gold(III) and platinum(II) complexes containing NHC auxiliary ligand are stable
against ligand exchange reaction under physiological conditions and these complexes display potent antitumor properties.31e,39 By using both porphyrin and NHC ligands altogether,
we prepared a panel of stable octahedral iridium(III) porphyrin
complexes containing NHC ligand that exhibit potent in vitro
anticancer activities and show signicant inhibition of tumor
growth in vivo upon photo-irradiation.
The Ir(III) porphyrin complexes bearing bis-NHC or monoNHC axial ligand(s) display a good stability against ligand
exchange with DMSO solvent or glutathione (Fig. S21 and S22†).
Complex 3 bearing bis-isocyanide ligands is more substitution
labile (Fig. S21f†). Most of the [IrIII(por)(NHC)2]+ complexes
exhibit cytotoxicity to different cancer cell lines with IC50 values
down to submicromolar concentrations (Table 8). Incorporation of NHC ligand(s) into iridium porphyrin increases lipophilicity of the complexes hence their cellular uptake and
accumulation in cancer cells. Complex 2f with meso-tetrakis
(pentauorophenyl)porphyrin ligand displays the lowest
cellular uptake and lipophilicity among the bis-NHC complexes.
Cationic iridium porphyrin complexes show more efficient
cellular internalization and hence increase in anticancer activity
as indicated by lower IC50 values compared to those of the
neutral complex [IrIII(oep)Cl(CO)] and the isoelectronic
kr and knr values of IrIII(por) complexes in CHCl3 solutions at 298 K
Complex
Fem [�10�2]
sem/ms
kra [�10]/s
knrb [�103]/s
[IrIII(tmp)Cl(CO)]
[IrIII(oep)Cl(CO)]
[IrIII(F20tpp)Cl(CO)]
[IrIII(tmp)(IMe)Cl]
[IrIII(tmp)(BIMe)Cl]
[IrIII(F20tpp)(BIMe)Cl]
[IrIII(oep)(IMe)2]+
[IrIII(oep)(BIMe)2]+
[IrIII(oep)(IiPr)2]+
[IrIII(F20tpp)(IMe)2]+c
[IrIII(oep)(CNPhOMe)2]+
[IrIII(oep)(py)2]+
0.22
5.03
2.92
0.05
0.06
0.29
0.41
0.66
0.03
0.08
6.40
12.30
77.2
83.3
101.0
1.8
2.3
1.7
2.7
3.6
1.9
0.5
124.7
55.3
2
60
29
28
26
171
152
183
16
160
52
222
13
11
10
555
435
587
368
276
526
1998
8
16
a
1a
1b
1d
2c
2d
2e
2f
3
4
Radiative decay rate constant determined by kr ¼ Fem/s. b Nonradiative decay rate constant determined by knr ¼ (1 � Fem)/s. c Data in CH2Cl2.
306 | Chem. Sci., 2019, 10, 293–309
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[RuII(oep)(CO)] reported by Bogoeva and co-workers.40 Complex
2c accumulates preferentially in cellular ER and somewhat in
mitochondria as shown by the confocal laser microscopy
images in the co-staining experiments, which could account for
the subsequent induction of ER stress and mitochondrial
membrane depolarization by this complex.
Incorporation of bis-NHC ligands to iridium(III) porphyrin
also endows the complexes to display remarkable singlet oxygen
production capability. Complex 2c (with octaethylporphyrin) has
the highest Fso compared to 2a (with meso-tetratolylporphyrin)
and other iridium(III) complexes ([IrIII(corrole)(pyridine)2] and
[IrIII(ttp)(aza-BODIPY)]) without bis-NHC ligands; it exhibits
potent cytotoxicity with an IC50 value in the nano-molar range
and triggers the generation of ROS upon visible light irradiation.
The photo-induced production of ROS (e.g., 1O2) was found to
lead to oxidation of sulfur-containing residues of peptides,
which is presumably a cytotoxic, protein-damaging mechanism.
The photo-cytotoxic effects led to induction of apoptotic cell
death and inhibition of angiogenesis. The in vivo photo-induced
antitumor effect of 2c was demonstrated in a mouse xenogra
model of human lung cancer. Overall, given the synergetic
anticancer properties of the prototype bis-NHC iridium(III)
porphyrin complexes in the dark and upon light activation as
well as the exibility in derivatization of NHC ligand, cationic
[IrIII(por)(NHC)n]+ (H2por ¼ porphyrin; n ¼ 1 or 2) complexes
have great potential for development as a new class of photoactivated anticancer agents.
Conclusions
We synthesized a panel of luminescent ruffled iridium(III)
porphyrin complexes bearing mono- and bis-NHC ligands, four
of which were structurally characterized by X-ray crystallography. The unique photophysical properties resulting from the
coordination of NHC ligands, including split Soret bands,
broadened and redshied absorption and emission spectra and
substantially reduced emission quantum yield and lifetime,
were investigated by spectroscopic and theoretical means and
discussed. In spite of the low triplet-state energy, which limits
their use as a photoredox mediator, the bis-NHC complexes are
versatile photochemical singlet oxygen generators that can
efficiently catalyze the photoinduced aerobic oxidation of
secondary amines and arylboronic acids. In addition, the bisNHC complexes are stable in physiological conditions and
exhibit potent cytotoxicity and photocytotoxicity, presumably
via the generation of ROS, against a panel of cancer cell lines,
and one was demonstrated to have signicant inhibitory effects
against tumor growth in a nude mouse model.
Author contributions
Chi-Ming Che designed and initiated this research project.
Chun-Nam Lok designed the biological experiments. Tsz-Lung
Lam synthesized and characterized all complexes in this work,
performed the spectroscopic and electrochemical measurements and carried out the photocatalytic reactions. Tsz-Lung
Lam, Chun-Nam Lok, and Chi-Ming Che wrote the
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Chemical Science
manuscript. Ka-Chung Tong and Wai-Lun Kwong carried out
the biological experiments. Chen Yang was responsible for X-ray
crystal structure determinations and assisted the time-resolved
spectroscopic measurements. Ming-De Li and David Lee Phillips carried out the resonance Raman spectroscopic measurements. Xianguo Guan, Vanessa Kar-Yan Lo, and Sharon
Lai-Fung Chan were responsible for the DFT/TDDFT calculations on UV-vis absorption spectra as well as resonance Raman
spectra and the associated vibrational mode assignments. All
authors reviewed the manuscript.
Conflicts of interest
There are no conicts to declare.
Acknowledgements
We thank Faisal Mehmood and Pui-Yan Lee for the help on biological studies. This work is nancially supported by Hong Kong
Research Grants Council, General Research Fund (17303815),
Innovation and Technology Fund (ITS/130/14FP) and Basic
Research Program-Shenzhen Fund (JCYJ20160229123546997 and
JCYJ20170412140257516).
Notes and references
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