1880 | Metallomics, 2014, 6, 1880--1888 This journal is©The Royal Society of Chemistry 2014

Cite this:Metallomics, 2014,

6, 1880

Reactivity–activity relationships of oral anti-
diabetic vanadium complexes in gastrointestinal
media: an X-ray absorption spectroscopic study†

Aviva Levina,a Andrew I. McLeod,a Lauren E. Kremer,a Jade B. Aitken,ab

Christopher J. Glover,b Bernt Johannessenb and Peter A. Lay*a

The reactions of oral V(V/IV) anti-diabetic drugs within the gastrointestinal environment (particularly in

the presence of food) are a crucial factor that affects their biological activities, but to date these have

been poorly understood. In order to build up reactivity–activity relationships, the first detailed study of

the reactivities of typical V-based anti-diabetics, Na3VVO4 (A), [VIVO(OH2)5](SO4) (B), [VIVO(ma)2] (C, ma =

maltolato(�)) and (NH4)[VV(O)2(dipic)] (D, dipic = pyridine-2,5-dicarboxylato(2�)) with simulated

gastrointestinal (GI) media in the presence or absence of food components has been performed by the

use of XANES (X-ray absorption near edge structure) spectroscopy. Changes in speciation under conditions

that simulate interactions in the GI tract have been discerned using correlations of XANES parameters that

were based on a library of model V(V), V(IV), and V(III) complexes for preliminary assessment of the oxidation

states and coordination numbers. More detailed speciation analyses were performed using multiple linear

regression fits of XANES from the model complexes to XANES obtained from the reaction products from

interactions with the GI media. Compounds B and D were relatively stable in the gastric environment (pH B 2)

in the absence of food, while C was mostly dissociated, and A was converted to [V10O28]6�. Sequential gastric

and intestinal digestion in the absence of food converted A, B and D to poorly absorbed tetrahedral vanadates,

while C formed five- or six-coordinate V(V) species where the maltolato ligands were likely to be partially

retained. XANES obtained from gastric digestion of A–D in the presence of typical food components

converged to that of a mixture of V(IV)–aqua, V(IV)–amino acid and V(III)–aqua complexes. Subsequent

intestinal digestion led predominantly to V(IV) complexes that were assigned as citrato or complexes

with 2-hydroxyacidato donor groups from other organic compounds, including certain carbohydrates.

The absence of strong reductants (such as ascorbate) in the food increased the V(V) component in

gastrointestinal digestion products. These results can be used to predict the oral bioavailability of various

types of V(V/IV) anti-diabetics, and the effects of taking such drugs with food.

Introduction

The anti-diabetic activities of vanadium compounds have been
known for over a century.1 In the early 1980s, a relationship was
proposed1 between this activity and the role of vanadate
([VVO4]3�) as a powerful inhibitor of protein tyrosine phospha-
tases (PTPs),2 which act as negative regulators of the insulin

signalling cascade.3 This finding spurred an interest in V-based
oral drugs for the treatment of type 2 (non-insulin-dependent)
diabetes, which is a growing health concern worldwide.1,4 Early
studies on vanadium anti-diabetics concentrated on [VVO4]3� or
[VIVO(OH2)5]2+ (A and B in Chart 1).5–7 However, more recent
research has focussed on the design of neutral lipophilic V(IV)
complexes of a general formula [VIVOL2] (where L is a mono-
anionic bidentate ligand), which have advantages of increased
gastrointestinal absorption and reduced toxicity compared with
inorganic V(V) or V(IV) salts.1,4,8,9 Archetypal examples of such
ligands are maltol (see C in Chart 1) or its close analogue, ethyl
maltol (both approved food additives);1,8,10 the V(IV) complex of
the latter ligand had entered phase II clinical trials.10 Another
widely studied class of potential anti-diabetics are anionic V(V)
complexes of the dipicolinicato (pyridine-2,5-dicarboxylato(2�))
ligand (D in Chart 1) and its derivatives.9,11

a School of Chemistry, The University of Sydney, Sydney, NSW 2006, Australia.

E-mail: peter.lay@sydney.edu.au
b Australian Synchrotron, 800 Blackburn Rd., Clayton, VIC 3168, Australia

† Electronic supplementary information (ESI) available: (i) Compositions of semi-
synthetic meals; (ii) comparison of spectra of the reaction products in gastro-
intestinal media with those of the model complexes (Fig. S1, see also Fig. 1 and 2
in the main text); and (iii) overlays of experimental and fitted spectra for multiple
linear regression analyses (Fig. S2, see also Table 1 in the main text). See DOI:
10.1039/c4mt00146j

Received 21st May 2014,
Accepted 28th July 2014

DOI: 10.1039/c4mt00146j

www.rsc.org/metallomics

Metallomics

PAPER

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025

http://crossmark.crossref.org/dialog/?doi=10.1039/c4mt00146j&domain=pdf&date_stamp=2014-08-01


This journal is©The Royal Society of Chemistry 2014 Metallomics, 2014, 6, 1880--1888 | 1881

Significant issues were apparent when V(V) and V(IV) com-
plexes were used as anti-diabetics in animal experiments and
human phase I clinical trials including the following: (i) a
distinct dichotomy of response (either achieved early in the
treatment or not achieved at all);1 and (ii) a poor correlation
between the glucose-lowering effect and V levels in the blood.12

In addition, administration together with food greatly reduced
the oral bioavailability of such complexes, which suggested
ligand substitution with food components.1,13 Animal studies
using the 14C-labelled V(IV) ethylmaltolato complex showed that
the compound dissociated within an hour after the ingestion
(in fed animals), most likely in the stomach.1,12a These data
indicated that the interactions with gastrointestinal media
(including food components) were crucial for controlling the
biological activities of V-based oral anti-diabetics.1,4,14,15 How-
ever, apart from some stability studies in acidic or neutral
aqueous solutions (resembling gastric or intestinal environ-
ments, respectively),11,16 no reactivity studies of anti-diabetic
V(V) or V(IV) complexes in gastrointestinal media have been
performed, as yet.

Our group has previously applied XANES (X-ray absorption
near-edge structure) spectroscopy in reactivity and speciation
studies of toxic and medicinal metal ions in biological
media,17–19 including the reactions of anti-diabetic Cr(III) and

Mo(VI) complexes with artificial digestion systems.14,15 Such
XANES analyses are particularly suitable for V complexes, due
to the high sensitivity of their spectra to changes in oxidation
states (V(V), V(IV), or V(III)) and coordination numbers (four, five
or six) of their complexes that are typically encountered in
biological systems.20–22 Recent analysis of XANES spectra of
twenty-three biologically-relevant V(V), V(IV) and V(III) complexes
showed that simple correlations, based on pre-edge and edge
parameters, can be used for the reliable determination of
oxidation states and coordination numbers of V species in
complex biological and environmental samples.22 In the cur-
rent research, this methodology has been applied to reactivity
studies of V(V) and V(IV) complexes with known anti-diabetic
properties (A–D in Chart 1)1,5–7,9 in simulated gastrointestinal
media (in the presence or absence of food components).14,15

Experimental
Materials and sample preparation

The model V(V) and V(IV) complexes (Chart 1) were either
purchased from Aldrich (A and B, purity 499%), or synthesized
by modified literature procedures (C, D, F, G, I and J)23–29 and
characterized by elemental analyses, infrared spectroscopy and
electrospray mass spectrometry, as described previously.22 Note
that V-oxido binding in V(IV) and V(V) complexes (except for A,
Chart 1) is represented with triple, rather than double, bonds
(contrary to the common convention). The triple bond arises
from a combination of one s and two p bonds.30,31 Published
XANES spectra for E (the mineral pascoite, Ca3[VV

10O28]�17H2O)32

and H (0.10 M solution of VIIICl3 in 1.0 M HCl)33 were also used in
the fits. Other reagents of analytical or higher purity grade were
purchased from Sigma-Aldrich or Merck, and used without further
purification. Water was purified by the Milli-Q technique. The
pH values of the reaction solutions were measured by a HI 9023
pH-meter (Hanna Instruments) equipped with a PHR-146 solid-
state micro-pH electrode (Lazar Research Laboratories), and the
instrument was calibrated daily with pH standard solutions
(Sigma).

A summary of the reaction conditions and designations of
the samples are given in Table 1. Stock solutions of A, B and D
(0.10 M in H2O) were prepared daily because these solutions are
known to be stable for at least several days under ambient
conditions.11,34 By contrast, C is sparingly water-soluble and
undergoes significant oxidation to V(V) within hours in aerated
aqueous solutions.23 Therefore, this compound was diluted
with an inert solid14,15 by thorough mixing of C (6.30 mg,
0.200 mmol) with boron nitride (BN, 0.200 g). Aliquots of this
mixture (10.0 mg) were used to prepare solutions of C in
reaction media (1.0 mL of 1.0 mM V), the insoluble BN was
then separated by gravity. Mixing of solid complexes with BN
(B10 mass parts BN per 1 part of V complex) was also used for
the preparation of samples of model compounds for XAS
analyses (A–D, F, G, I and G in Chart 1).22

Artificial gastrointestinal digestions of A–D in the absence of
food components14,15 were performed by dissolving compounds

Chart 1 Structures of anti-diabetic V(V) and V(IV) complexes used for the
reactions with gastrointestinal media (A–D), and model complexes used
for the data analysis (E–J). The V–oxido binding in V(IV) and V(V) com-
plexes, except for A, is correctly represented by triple, rather than double,
bonds (a combination of one s and two p bonds).30,31

Paper Metallomics

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025



1882 | Metallomics, 2014, 6, 1880--1888 This journal is©The Royal Society of Chemistry 2014

A–D ([V]final = 1.0 mM) in artificial gastric juice (150 mM NaCl,
acidified by HCl to pH = 1.8)35 and incubation of the resultant
solutions for 1 h at 310 K in a rocking water bath with free access
to air. In one series of experiments (A1–D1 in Table 1), the
reaction solutions were then immediately frozen at B195 K and
freeze-dried (217 K and 0.5 mbar for 16 h). Freeze-drying of the
samples was used to stop the reactions, to increase the signal-to-
noise ratio in XANES spectra, and to minimize the synchrotron
radiation-induced chemical changes in the samples.36 In
another series (A2–D2 in Table 1), simulated gastric digestion
was followed by raising the pH value of the solutions to 7.535 by
dropwise addition of aqueous NaHCO3 (1.0 M). The incubation
was continued for further 2 h at 310 K (simulated intestinal
digestion), after which the samples were freeze-dried, as described
above. The chosen reaction times (1 h and 2 h) correspond to

typical residence times (in humans) of ingested drugs in the
stomach and small intestines, respectively.37,38

Modified literature procedures14,15,37,38 were used for artifi-
cial digestion of A–D in the presence of typical food compo-
nents and digestive enzymes. For experiments A3–D3 and
A4–D4 (Table 1), an aliquot (10 mL) of commercial liquid
semi-synthetic meal ("liquid breakfast", Sanitarium, Australia;
detailed composition is given in ESI†)39 was acidified to pH =
1.8 (from the initial value of 6.7) by dropwise addition of
concentrated HCl (B0.10 mL of 10 M solution), then pepsin
solution (0.014 g porcine pepsin in 0.60 mL of 0.10 M HCl) was
added. Aliquots (1.0 mL) of the resultant solution were imme-
diately mixed with A–D to [V]final = 1.0 mM, and incubated for
1 h at 310 K in a rocking water bath with free access to air
(simulated gastric digestion), followed either by freeze-drying of
the samples (experiments A3–D3), or by simulated intestinal
digestion (experiments A4–D4). For the latter experiments,
NaHCO3 solution (1.0 M, B0.15 mL) and pancreatin-bile
solution (0.010 g of porcine pancreatin and 0.050 g of porcine
bile extract in 0.25 mL of 0.10 M NaHCO3) were added dropwise
to the samples (to final pH = 7.5), followed by incubation for a
further 2 h at 310 K, and freeze-drying of the resultant mixtures.
Experiments A5 and C5 (Table 1) were performed in the same
manner as A4–D4, except that the semi-synthetic meal was
freshly prepared from separate components and did not con-
tain vitamin additions (see ESI† for details). For experiment C6
(Table 1), compound C (in a mixture with BN, see above) was
dissolved in HEPES-buffered saline (20 mM HEPES, 140 mM
NaCl, pH = 7.40; where HEPES = 4-(2-hydroxyethyl)-1-piper-
azineethanesulfonic acid)40 under a stream of Ar (to avoid
V(IV) oxidation to V(V))23 to [V]final = 1.0 mM, BN was removed
by centrifugation, and the resultant solution was immediately
frozen at B195 K and freeze-dried.

XANES spectroscopy and data processing

Vanadium K-edge spectra of samples A–D (Chart 1), A1–D1,
A2–D2, A3–D3, A4–D4 and C6 (Table 1) were recorded at the
X-ray absorption spectroscopy beamline, Australian Synchro-
tron (AS, Melbourne, Australia). The beam energy was 3.0 GeV,
and the maximal beam current was 200 mA. The beamline had
a channel-cut Si[111] monochromator, an upstream collimating
mirror, and a downstream sagittally focusing mirror; both
mirrors were Rh-coated and also provided harmonic rejection.
Mixtures of compounds A–D with BN or neat freeze-dried
reaction products (see the Sample preparation section above)
were pressed into 0.5 mm thick pellets that were supported
within a polycarbonate spacer between two 63.5 mm Kapton
tape windows (window size, 2 � 10 mm). The samples were
placed in a He-filled box at B295 K, and the XANES data were
collected in fluorescence detection mode, using a Ge planar
detector (Eurisys; 100-element). Low-temperature XAS measure-
ments were not used, since they led to a significant reduction in
the signal-to-noise ratio, due to the strong absorption of
photons at the 5–6 keV energy range by the cryostat windows
and air between the sample compartment and the detector.
For all the samples, only the XANES regions were recorded

Table 1 Conditions of sample preparation and results of the linear fits to
the XANES from the reactions of anti-diabetic complexes A–D with
artificial digestive media

Samplea Conditionsb Modelc R2 d

A1 Gastric digestion; no food 100% E 0.994
B1 100% B 0.999
C1 100% B 0.990
D1 100% D 0.993

A2 Gastric and intestinal digestion;
no food

100% A 0.994
B2 100% A 0.994
C2 (30 � 2)% D;

(70 � 2)% G
0.998

D2 100% A 0.996

(A3–D3)av
e Gastric digestion; artificial meal 1f (50 � 4)% B;

(22 � 2)% H;
(28 � 2)% I

0.999

A4 Gastric and intestinal digestion;
artificial meal 1f

100% J 0.996
B4 100% J 0.999
C4 100% J 0.999
D4 (10 � 1)% A;

(90 � 2)% J
0.999

A5 Gastric and intestinal digestion;
artificial meal 2 f

(66 � 2)% A;
(34 � 2)% J

0.998

C5 (48 � 2)% A;
(52 � 2)% J

0.997

C6 pH = 7.4, no. O2 100% F 0.997

a Designations of the initial compounds (A–D) correspond to those in
Chart 1, and the numbers (1–6) designate the treatment conditions. The
XANES spectra for A5 and C5 were collected at the ANBF, and all the
other spectra were collected at the AS (see Experimental for details).
b In all the experiments, the total V concentrations in the reaction
mixtures were 1.0 mM. Details of the treatment conditions are
described in the Experimental section. c A XANES spectrum or a combi-
nation of spectra of model V(V), V(IV) and V(III) complexes (Chart 1) that
provide the best possible match for the XANES spectrum of the
corresponding sample (see Fig. 3 and Fig. S1 and S2, ESI). Standard
deviations were calculated using Origin software46 as a part of multiple
linear regression procedure. d Regression coefficient for the superposi-
tion of the sample and model spectra (see Fig. S2, ESI for multiple
linear regression results). e Since nearly identical XANES spectra were
obtained from samples A3, B3, C3 and D3 (Fig. S1d and e, ESI), the averaged
spectrum was used for the modelling. f Artificial meal 1 was a commercial
semi-synthetic meal ("liquid breakfast");39 and artificial meal 2 was
prepared from separate components;14,15 see ESI for the composition
of the both meals.

Metallomics Paper
D

ow
nloaded from

 https://academ
ic.oup.com

/m
etallom

ics/article/6/10/1880/6007943 by guest on 12 Septem
ber 2025



This journal is©The Royal Society of Chemistry 2014 Metallomics, 2014, 6, 1880--1888 | 1883

(5250–5700 eV range; step sizes, 10 eV below 5450 eV, 0.25 eV at
5450–5525 eV and 2 eV above 5525 eV). The energy scale was
calibrated using a V foil as an internal standard (calibration
energy, 5465.0 eV, corresponding to the first peak of the first
derivative of V(0) edge).41 The XANES spectra of the model
complexes, F, G, I and J (Chart 1), as well as those of samples A5
and C5 (Table 1), were recorded at B295 K using the fluores-
cence detection mode at the Australian National Beamline
Facility (ANBF, beamline 20B, Photon Factory, KEK, Tsukuba,
Japan), as described previously.22 No significant photodamage of
V(V) samples occurred at ANBF (as shown by comparison of XANES
data from sequential scans), while the relative V(IV) content
increased by B10% in the second scans of the samples recorded
at the AS.36 The extent of photodamage was higher at the AS
compared with those at the ANBF because of the higher photon
flux, but this also provided higher signal-to-noise ratios.36 Consis-
tent results were obtained on both beamlines when only the first
scans for each sample at the AS were used for the analyses.22,36

Calibration, averaging and splining of XANES data were
performed using the XFit software package.42 The spectra were
normalized (using the Spline program within the XFit package)
according to the method of Penner-Hahn and coworkers,43 to
match the tabulated X-ray cross-section data44 for V (in a similar
manner to the earlier work on Cr(III) XANES spectra).15 This
normalization technique led to consistent XANES spectra for all
of the samples, regardless of the beamline used and the signal-to-
noise ratio. Published XANES spectra of E and H32,33 were
digitized using WinDIG software,45 and the energy scales for these
data were adjusted, as described previously.22 Multiple linear
regression analyses of XANES data were performed using Origin
software46 with previously described criteria for a successful fit.17

Results

A comparison of XANES spectra (5460–5520 eV) of the parent
complexes (A–D in Chart 1) with those of the reaction products
in artificial gastrointestinal media (A1–D1, A2–D2, A3–D3 and
A4–D4 in Table 1) is shown in Fig. 1. Key XANES parameters
(position and intensity of the pre-edge absorbance, edge energy
at the half-edge jump, and post-edge absorbance intensity) for
these samples are plotted in Fig. 2, where they are compared
with the corresponding parameters for model V(V/IV/III) com-
plexes (designated with red ellipses in Fig. 2).22 Comparison of
XANES of the reaction products (Table 1) with those of selected
model complexes (Chart 1), or their linear combinations, are
shown in Fig. 3 and Fig. S1 and S2 (ESI†), and the best fits to the
XANES from each sample are summarized in Table 1.

Treatment of A in artificial gastric juice in the absence of
food components (pH B 1.8; 1 h at 310 K; A1 in Table 1) led to a
notable decrease in intensity of the pre-edge absorbance, but
no significant changes in edge energy (Fig. 1a), which was
consistent with the formation of six-coordinate V(V) species
(Fig. 2).22,32,47 The XANES of A1 closely matched the literature
data for [V10

VO28]6� (E in Chart 1, the mineral pascoite),32 as
shown in Fig. 3a. Decavanadate ([V10

VO28]6�) is well-known

to be the predominant form of V(V) in aqueous solutions at
pH B 2 and [V] Z 1 mM in the absence of strongly binding
ligands.20,48 By contrast, treatment of B under the same condi-
tions (B1 in Table 1) caused no significant changes in the pre-
edge and edge parameters and a slight increase in post-edge
absorbance (Fig. 1b and 2), which was likely to be caused by
partial deprotonation of the aqua ligands in B.20,48 The reaction
product of D under these conditions exhibited a similar XANES
to that of the initial compound (D1 in Table 1 and Fig. 1d), apart
from a slight decrease in pre-edge intensity, which pointed to the
formation of a mixture of five- and six-coordinate V(V) species
(Fig. 2). The relative stability of D in aqueous solutions at pH B 2
compared to the other complexes has also been proposed
previously from NMR spectroscopic studies.11

The XANES of C1 (Table 1) was distinguished from that of
the initial compound, C, by a strong decrease in intensity and

Fig. 1 Comparison of XANES of initial complexes (A–D) with those of the
reaction products with artificial digestion systems. Designations of the
samples correspond to those in Chart 1 and Table 1. All the data were
collected at B295 K in fluorescence detection mode for solid samples
(mixtures of model complexes with BN or freeze-dried reaction mixtures;
see Experimental for details).

Paper Metallomics

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025



1884 | Metallomics, 2014, 6, 1880--1888 This journal is©The Royal Society of Chemistry 2014

a shift in energy of the pre-edge absorbance (Fig. 1c), which
was consistent with the formation of six-coordinate V(IV)
species (Fig. 2). Of all the available model XANES spectra,22

that of B was the closest match for C1 (Table 1 and Fig. S1a,
ESI†), which was in agreement with the literature data that
the V(IV) maltolato complex was largely dissociated and con-
verted to aquated V(IV) species at pH r 2.16 By contrast,
dissolution of C in neutral aqueous medium under an Ar atmo-
sphere (to avoid oxidation to V(V))23 resulted in the formation of
a different six-coordinate V(IV) species (C6 in Table 1 and Fig. 2
and Fig. S1b, ESI†). The XANES of C6 closely matched that of a
model six-coordinate V(IV)-maltolato complex, F (Chart 1),23 as
shown in Fig. S1b (ESI†) and in Table 1. This result was
consistent with the addition of H2O as the sixth ligand to C in
neutral aqueous solutions, similarly to the well-known addition of

an aqua ligand to the V(IV) acetylacetonato complex (established
by EPR spectroscopy).49

In summary, XANES data pointed to the relative stabilities of
B and D in the acidic environment of the stomach (in the
absence of food) compared with A and C, which converted
predominantly to [V10

VO28]6� and [VIVO(OH2)5]2+, respectively,
under these conditions. These findings were consistent with
the literature data on the reactivity of A–D in acidic aqueous
solutions (obtained by NMR and EPR spectroscopies and by
potentiometric titrations),11,16,20,48 which showed that the
freeze-dried samples used in this work maintained the specia-
tion of V(V/IV) reaction products that were formed in solutions.

Fig. 2 Correlations of pre-edge and edge parameters in the XANES of
the reaction mixtures (designations correspond to those in Table 1)
and model complexes (Chart 1). The areas corresponding to various
oxidation states and coordination numbers of V complexes (red ellipses)
were drawn based on the XANES data for a library of twenty-three model
V(V), V(IV) and V(III) complexes (asterisks designate non-oxido complexes).22

Fig. 3 Comparison of selected XANES spectra of the reaction products of
A–D with those of model V(V), V(IV) and V(III) complexes (see also Fig. S1 and
S2 in ESI;† designations correspond to those in Chart 1 and Table 1). All the
data were collected at B295 K in fluorescence detection mode for solid
samples (freeze-dried reaction mixtures or mixtures of model complexes
with BN; see Experimental section for details).

Metallomics Paper

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025



This journal is©The Royal Society of Chemistry 2014 Metallomics, 2014, 6, 1880--1888 | 1885

Treatments of A, B, or D under the conditions that mimicked
sequential gastric and intestinal digestions in the absence of
food (pH B 1.8 for 1 h and pH B 7.5 for 2 h at 310 K; A2, B2 or
D2 in Table 1) resulted in XANES that were close to each other
and similar, but not equivalent, to that of A (Fig. 1a, b and d and
Fig. S1c, ESI†). Data shown in Fig. 2 confirmed the formation of
tetrahedral V(V) species under these conditions. Literature data
on the pH- and concentration-dependent speciation of V(V) in
aqueous solutions20,48 suggested that these products were likely
to be the mixtures of [H2VVO4]� (predominant species) and
oligomeric vanadates, such as [V3

VO9]3�. The data for D2
(Fig. 1d and 2) point to complete dissociation of D under
simulated intestinal conditions, which was consistent with the
literature data on the low stability of D at pH 4 7.11 Both V(IV)
complexes studied, B and C, were completely oxidized to V(V)
species under these conditions, but the differences in XANES of
their reaction products (B2 and C2 in Table 1 and Fig. 1)
indicated that the maltolato ligands were partially retained
under conditions of C2. The XANES parameters of C2 were
significantly different from those of A2, B2 and D2, and were
consistent with the formation of a mixture of five- and six-
coordinate V(V) species (Fig. 1c and 2). The XANES data for C2
were best matched by a combination of models D and G (V(V)-
maltolato complex, Chart 1), as shown in Table 1 and in Fig. 3b
and Fig. S2 (ESI†). The fit residues for C2 were small but
significantly exceeded the experimental noise levels (Fig. S2,
ESI†); however, the pre-edge and edge area (crucial determinants
of V oxidation state and coordination number)22,50 were well
reproduced. The differences in the post-edge area between the
experimental and fitted spectra of C2 (Fig. S2, ESI†) were likely to
be caused by the following factors: (i) the nature of V-bound
ligands in the model compounds will not be an exact match to
those in the reaction products and, as such, multiple-scattering
contributions in this region of the XAS will be sensitive to non-
coordinating atoms that are within B5 Å of the vanadium
atom;51 and (ii) the XANES spectra of the reaction products
and the model complexes were collected at different synchrotron
sources, using different monochromator settings.22,50

Treatments of any of A–D under simulated gastric condi-
tions in the presence of food components ("liquid breakfast",
see ESI;† samples A3–D3 in Table 1) resulted in the formation
of the same product, as shown in the XANES of Fig. 1, 2 and
Fig. S1d (ESI†). Since the differences in XANES obtained
amongst conditions A3–D3 were comparable to the experi-
mental noise levels (Fig. S1e, ESI†), the average of these data
was used for further processing (Fig. 3c). The edge and post-
edge shapes for A3–D3 were close to those for [VIII(OH2)6]3+

(H in Chart 1),33 while the pre-edge intensity was close to that
for [VIVO(OH2)5]2+(B in Chart 1), as shown in Fig. 3c. Clear
separation of A3–D3 from all the other samples on the basis of
XANES parameters is evident in Fig. 2b. The best match for
XANES of A3–B3 was with a combination of the XANES from
models B, H, and I (V(IV) picolinato complex, Chart 1; a model
of V(IV)-amino acid or protein binding),26–28 as shown in Table 1
and in Fig. S2 (ESI†). These results show that V(III) species can
be formed by reduction of either V(V) or V(IV) in acidic medium

of the stomach in the presence of organic reductants (food
components).

Treatments of A–D under the conditions of sequential
gastric and intestinal digestion in the presence of food compo-
nents ("liquid breakfast", A4–D4 in Table 1), resulted in the
formation of similar products (Fig. 1 and Fig. S1f, ESI†), with
XANES parameters that corresponded to those of six-coordinate
V(IV) complexes (Fig. 2). The XANES of A4, B4 and C4 were
closely matched by that of J (dimeric V(IV) citrate complex,
Chart 1),29 while XANES of D4 was best fitted by a combination
of the XANES of J (main component) and A (Table 1 and Fig. S2,
ESI†). Similar treatments of A or C in the presence of a different
semi-synthetic meal (not containing vitamin supplements, see
ESI†) resulted in a higher proportion of V(V) vs. V(IV) species,
which was best matched by combinations of XANES from
models J and A (samples A5 and C5 in Table 1 and Fig. 3d
and Fig. S2, ESI†). Close matches of XANES of the reaction
products A4–C4 to that of the model J (Table 1 and Fig. 3d)
suggest the binding of the resultant V(IV) species to hydroxido,
alcoholato and/or carboxylato donor groups that most likely
originate from citrate and/or other ligands, such as certain
carbohydrate components of food, that contain 2-hydroxyacid
moieties.4,52

Discussion

A summary of likely chemical transformations of anti-diabetic
V(V/IV) complexes in gastrointestinal media, deduced from
XANES spectra (Table 1), is shown in Scheme 1. The most
striking result of these studies was the crucial role of the
presence and composition of food components on V speciation.
According to the results of phase 1 human clinical trials, V
absorption from oral administration of 75 mg of V(IV)–ethyl-
maltolato complex (a close analogue of C) was B13-fold higher
in the fasted state compared with the fed state.1 These data
pointed to a low bioavailability of V(IV) complexes with combi-
nations of hydroxido, alcoholato and/or carboxylato ligands
that were likely to form in the intestines in the presence of
food components (Scheme 1). These can form due to the high
thermodynamic stabilities of V(V/IV) 2-hydrocarboxylato donor
groups that can form monomeric and polynuclear complexes,
while the formation of V(V/IV) 1,2-diolato complexes with carbo-
hydrates is unlikely under biological conditions.52,53 Such 1,2-
diolato complexes require strongly basic conditions to form in
solution from reactions of V(V) or V(IV) with sugars.52 As is the
case for Cr(IV), V(IV) requires 2-hydroxyacid groups rather than
simple diols to stabilize this oxidation state under physiologi-
cally relevant conditions.53 Apart from small molecule ligands,
sialoglycoproteins may also provide donor groups for strong
V(V/IV) binding.54 The bioavailability of V-containing drugs is
expected to decrease further if the consumed food is rich in
strong reductants, such as ascorbate,55,56 as demonstrated by
comparison of digestion products in the presence of two types
of semi-synthetic meals (samples A4, C4, A5, C5 in Table 1;
see ESI† for meal composition).

Paper Metallomics

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025



1886 | Metallomics, 2014, 6, 1880--1888 This journal is©The Royal Society of Chemistry 2014

In the absence of food, V is likely to be absorbed from the
intestines mainly in the form of V(V) oxido complexes, regard-
less of the oxidation state and chemical form of vanadium that
was ingested (Scheme 1). However, maltolato and related
ligands can remain partially bound to V(V) under these condi-
tions (Scheme 1), as demonstrated by the difference in XANES
of the sample C2 compared with A2, B2 and D2 (Table 1).
This difference may explain the higher bioavailability of C and
its analogues compared with that of B, which was demonstrated
in both animal experiments and human clinical trials.1,57 Alter-
natively, V compounds can be partially absorbed from the oral
cavity58 and the stomach, given the relatively rapid increases in V
levels in the blood (which typically reached a maximum within
1–3 h after oral administration).1,12 Speciation of V in the gastric
environment was more diverse compared with that in the
simulated intestinal juices, particularly in the absence of food
(Scheme 1). Some V anti-diabetic compounds, such as D
(Scheme 1), are relatively stable in the gastric media11 and may
be absorbed intact.9 Although the formation of [VV

10O28]6� in
simulated gastric media has been shown in the in vitro experi-
ments ([V] = 1.0 mM; Table 1 and Scheme 1), it is unclear
whether high enough V(V) concentrations can be reached for
this process to take place in vivo. Absorbed [V10

VO28]6� is
expected to decompose slowly (within hours) in the blood and
to show biological activities that are distinct from those of other
V(V) or V(IV) species.59 Formation of V(III) in the stomach in the
presence of reducing food components (Scheme 1) could facil-
itate V uptake through Fe(III) metabolic pathways.60 The close
similarity between V(III) and Fe(III) in biochemical pathways has
previously been demonstrated by high-affinity binding of V(III) to
the main Fe(III) transport protein, transferrin.61 However, selec-
tive Fe(III) uptake by intestinal epithelial cells is preceded by its
reduction to Fe(II).60 Although the possibility of formation of V(II)
in biological systems has not yet been considered,20,62 stabili-
zation of V(II) by biologically relevant imidazole ligands in vitro is
known.63 However, given that V(III) only appears to be produced
in the presence of food and there is decreased V absorption
under these conditions, it is unlikely that these low-oxidation
states are responsible for the main absorption pathways. Alter-
natively, these epithelial cells may take up V(IV) in the form
of [VIVO]2+, as a chemical analogue of divalent metal ions.64

For instance, the recently discovered [VIVO]2+ transport system of
ascidians (V-accumulating marine organisms) is also capable of
transporting Fe(II).65

The usefulness of three-dimensional correlations of XANES
parameters that were developed previously22 for the determina-
tion of oxidation states and coordination numbers of V in
complex matrices has been confirmed in the current study
(Fig. 2). However, caution is required when the samples are
likely to contain V in various oxidation states, such as A3–D3,
A5 and C5 (Table 1 and Fig. 2). Therefore, the initial assessment
of the chemical state of V with the use of the diagrams in Fig. 2
has to be complemented by comparison of whole XANES
spectra of the samples with those of model complexes (Fig. 3,
Fig. S1 and S2, ESI†). On the whole, these data confirm the
previous findings14,15 that metal-based anti-diabetics are likely
to undergo complete chemical rearrangement in gastrointest-
inal media, particularly in the presence of food components.
The current studies have enabled all oxidation states to be
studied in the one experiment, which was not possible in
previous studies and has provided many new insights in the
speciation that is important in understanding efficacy and
safety of V anti-diabetics. These changes determine the mode
of gastrointestinal absorption and further metabolism of these
drugs and have rationalized the differences in in vivo efficacies.
Reactivity of oral V(V/IV) anti-diabetics in gastrointestinal media
has to be taken into account when considering their further
reactions in the blood,66 and the current work provides an entry
point for such studies, which will be reported in the future.67

The current work illustrates how the XANES methodologies
described herein can be used in studies of vanadium speciation
in blood,18,67 and also in cells,18,68 and tissues.

Conclusions

While the importance of V speciation in controlling the
activities of biological systems has been recognised for many
years,69 the XANES results reported herein provide the most
definitive studies to date on the speciation of all oxidation
states vanadium under conditions that mimic oral adminis-
tration. Typical anti-diabetic V(V) and V(IV) complexes undergo
profound chemical changes in gastrointestinal media, includ-
ing dissociation of the ligands, V(IV) oxidation to V(V) (in the
absence of food), or V(V) reduction to V(IV) and even V(III) (in
the presence of food). Formation of V(III) may be important
for further metabolism via Fe(III) pathways, but the main
absorption mechanisms appear to be associated with vana-
date (poorly absorbed), VIVO2+ species via M2+ uptake mechan-
isms, and passive diffusion of neutral species. These data
confirm the role of such complexes as pro-drugs that release
the active components on the interactions with biological
media. Three-dimensional diagrams of pre-edge and edge
parameters in XANES spectra, developed on the basis of a
library of model V(V/IV/III) complexes,22 have proven to be
useful for the assessment of the chemical states of V in bio-
logical environments.

Scheme 1 Proposed biotransformations of complexes A–D (Chart 1) in
gastrointestinal environments based on the analyses of XANES data
(Table 1).

Metallomics Paper

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025



This journal is©The Royal Society of Chemistry 2014 Metallomics, 2014, 6, 1880--1888 | 1887

Acknowledgements

The research was supported by Australian Research Council
(ARC) Discovery Grants (DP0208409, DP0774173, DP0984722,
DP1095310, and DP130103566), ARC Professorial Fellowships
(DP0208409 and DP0984722) to P.A.L., and an ARC Linkage
Infrastructure, Equipment and Facilities (LIEF) Program grant
(LE0346515) for the 36-pixel Ge detector at ANBF. Initial X-ray
absorption spectroscopy was performed partially at ANBF with
support from the Australian Synchrotron Research Program
(ASRP), which was funded by the Commonwealth of Australia
under the Major National Research Facilities program (ANBF
was operated by the Australian Synchrotron (AS) from 2009
until its closure in 2013). We acknowledge the LIEF program of
the ARC for financial support (grant numbers LE0989759 and
LE110100174) and the High Energy Accelerator Research Orga-
nisation (KEK) in Tsukuba, Japan, for operations support. We
thank Drs Garry Foran, James Hester, Celesta Fong and Michael
Cheah for the assistance with XAS experiments at ANBF, and
Drs Glyn Devlin and Peter Kappen for those at the AS.

Notes and references

1 K. H. Thompson and C. Orvig, J. Inorg. Biochem., 2006, 100,
1925–1935.

2 M. Zhang, M. Zhou, R. L. Van Etten and C. V. Stauffacher,
Biochemistry, 1997, 36, 15–23.

3 A. K. Srivastava and M. Z. Mehdi, Diabetic Med., 2005, 22,
2–13.

4 (a) A. Levina and P. A. Lay, Dalton Trans., 2011, 40,
11675–11686; (b) D. Rehder, Future Med. Chem., 2012, 4,
1823–1837.

5 C. E. Heyliger, A. G. Tahiliani and J. H. McNeill, Science,
1985, 227, 1474–1477.

6 I. G. Fantus, G. Deragon, R. Lai and S. Tang, Mol. Cell.
Biochem., 1995, 153, 103–112.

7 P. Poucheret, S. Verma, M. D. Grynpas and J. H. McNeill,
Mol. Cell. Biochem., 1998, 188, 73–80.

8 K. H. Thompson and C. Orvig, Coord. Chem. Rev., 2001,
219–221, 1033–1053.

9 D. C. Crans, A. M. Trujillo, P. S. Pharazyn and M. D. Cohen,
Coord. Chem. Rev., 2011, 255, 2178–2192.

10 K. H. Thompson, J. Lichter, C. LeBel, M. C. Scaife,
J. H. McNeill and C. Orvig, J. Inorg. Biochem., 2009, 103,
554–558.

11 D. C. Crans, L. Yang, T. Jakusch and T. Kiss, Inorg. Chem.,
2000, 39, 4409–4416.

12 (a) K. H. Thompson, B. D. Liboiron, Y. Sun, K. D. D.
Bellman, I. A. Setyawati, B. O. Patrick, V. Karunaratne,
G. Rawji, J. Wheeler, K. Sutton, S. Bhanot, C. Cassidy,
J. H. McNeill, V. G. Yuen and C. Orvig, JBIC, J. Biol. Inorg.
Chem., 2003, 8, 66–74; (b) G. R. Willsky, K. Halvorsen, M. E.
Godzala, L.-H. Chi, M. J. Most, P. Kaszynski, D. C. Crans,
A. B. Goldfine and P. J. Kostyniak, Metallomics, 2013, 5,
1491–1502.

13 J. B. Lichter, C. R. E. Orvig, M. C. Scaife and K. H. Thompson, WO
Pat., 2009032591, 2009 (Chem. Abstr., 2009, 150, ref. 322578).

14 A. Levina, A. I. McLeod, J. Seuring and P. A. Lay, J. Inorg.
Biochem., 2007, 101, 1586–1593.

15 A. Nguyen, I. Mulyani, A. Levina and P. A. Lay, Inorg. Chem.,
2008, 47, 4299–4309.

16 T. Kiss, T. Jakusch, D. Hollender, A. Doernyei, E. A. Enyedy,
J. C. Pessoa, H. Sakurai and A. Sanz-Medel, Coord. Chem.
Rev., 2008, 252, 1153–1162.

17 A. Levina, H. H. Harris and P. A. Lay, J. Am. Chem. Soc.,
2007, 129, 1065–1075.

18 J. B. Aitken, A. Levina and P. A. Lay, Curr. Top. Med. Chem.,
2011, 11, 553–571.

19 (a) A. Levina, J. B. Aitken, Y. Y. Gwee, Z. J. Lim, M. Liu,
A. Mitra Singharay, P. F. Wong and P. A. Lay, Chem. – Eur. J.,
2013, 19, 3609–3619; (b) M. Liu, Z. J. Lim, Y. Y. Gwee,
A. Levina and P. A. Lay, Angew. Chem., Int. Ed., 2010, 49,
1661–1664.

20 D. Rehder, Bioinorganic Vanadium Chemistry, John Wiley &
Sons, Chichester, 2008.

21 P. Frank, E. J. Carlson, R. M. K. Carlson, B. Hedman and
K. O. Hodgson, J. Inorg. Biochem., 2008, 102, 809–823.

22 A. Levina, A. I. McLeod and P. A. Lay, Chem. – Eur. J., 2014,
DOI: 10.1002/chem.201403993.

23 P. Caravan, L. Gelmini, N. Glover, F. G. Herring, H. Li,
J. H. McNeill, S. J. Rettig, I. A. Setyawati, E. Shuter, Y. Sun,
A. S. Tracey, V. G. Yuen and C. Orvig, J. Am. Chem. Soc.,
1995, 117, 12759–12770.

24 B. Nuber, J. Weiss and K. Wieghardt, Z. Naturforsch., B:
Anorg. Chem., Org. Chem., 1978, 33, 265–267.

25 K. Wieghardt, Inorg. Chem., 1978, 17, 57–64.
26 H. Sakurai, K. Fujii, H. Watanabe and H. Tamura, Biochem.

Biophys. Res. Commun., 1995, 214, 1095–1101.
27 M. Melchior, K. H. Thompson, J. M. Jong, S. J. Rettig,

E. Shuter, V. G. Yuen, Y. Zhou, J. H. McNeill and C. Orvig,
Inorg. Chem., 1999, 38, 2288–2293.

28 E. Lodyga-Chruscinska, G. Micera and E. Garribba, Inorg.
Chem., 2011, 50, 883–899.

29 M. Tsaramyrsi, M. Kaliva, A. Salifoglou, C. P. Raptopoulou,
A. Terzis, V. Tangoulis and J. Giapinfzakis, Inorg. Chem.,
2001, 40, 5772–5779.

30 C. J. Ballhausen and H. B. Gray, Inorg. Chem., 1962, 1,
111–122.

31 J. R. Winkler and H. B. Gray, Struct. Bonding, 2012, 142,
17–28.

32 P. Chaurand, J. Rose, V. Briois, M. Salome, O. Proux,
V. Nassif, L. Olivi, J. Susini, J.-L. Hazemann and J.-Y.
Bottero, J. Phys. Chem. B, 2007, 111, 5101–5110.

33 P. Frank and K. O. Hodgson, Inorg. Chem., 2000, 39,
6018–6027.

34 D. C. Crans and A. S. Tracey, ACS Symp. Ser., 1998, 711, 2–29.
35 B. Gammelgaard and O. Joens, in Handbook of Metal-Ligand

Interactions in Biological Fluids: Bioinorganic Medicine, ed.
G. Berthon, Marcel Dekker, New York, 1995, vol. 1, pp. 48–61.

36 G. N. George, I. J. Pickering, M. J. Pushie, K. Nienaber,
M. J. Hackett, I. Ascone, B. Hedman, K. O. Hodgson,

Paper Metallomics

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025



1888 | Metallomics, 2014, 6, 1880--1888 This journal is©The Royal Society of Chemistry 2014

J. B. Aitken, A. Levina, C. Glover and P. A. Lay, J. Synchrotron
Radiat., 2012, 19, 875–886.

37 R. P. Glahn, O. A. Lee, A. Yeung, M. I. Goldman and
D. D. Miller, J. Nutr., 1998, 128, 1555–1561.

38 S. Yun, J.-P. Habicht, D. D. Miller and R. P. Glahn, J. Nutr.,
2004, 134, 2717–2721.

39 Liquid breakfast, Sanitarium, Australia, http://www.sanitarium.
com.au/products/breakfast/up-and-go/up-and-go-choc-ice,
accessed 21.04.14.

40 HEPES-buffered saline, Cold Spring Harbor Protocols., 2006,
doi:10.1101/pdb.rec8786.

41 A. C. Thompson, D. T. Attwood, E. M. Gullikson, M. R.
Howells, J. B. Kortright, A. L. Robinson, J. H. Underwood,
K.-J. Kim, J. Kirz, I. Lindau, P. Pianetta, H. Winick, G. P.
Williams and J. H. Scofield, X-ray Data Booklet, University of
California, Berkeley, CA, 2nd edn, 2001.

42 (a) P. J. Ellis and H. C. Freeman, J. Synchrotron Radiat., 1995,
2, 190–195; (b) XFit for Windows, beta-version. Australian
Synchrotron Research Program, Sydney, Australia, 2004.

43 T.-C. Weng, G. S. Waldo and J. E. Penner-Hahn, J. Synchrotron
Radiat., 2005, 12, 506–510.

44 W. H. McMaster, N. Kerr Del Grande, J. H. Mallett and
J. H. Hubbell, Compilation of X-ray Cross Sections, Lawrence
Livermore National Laboratory, Livermore, CA, 1969.

45 D. Lovy, WinDIG, University of Geneva, Geneva, Switzerland,
1996.

46 Microcal Origin Version 6.0, Microcal Software Inc., North-
ampton, MA, 1999.

47 G. Giuli, E. Paris, J. Mungall, C. Romano and D. Dingwell,
Am. Mineral., 2004, 89, 1640–1646.

48 D. C. Crans, J. J. Smee, E. Gaidamauskas and L. Yang, Chem.
Rev., 2004, 104, 849–902.

49 S. S. Amin, K. Cryer, B. Zhang, S. K. Dutta, S. S. Eaton,
O. P. Anderson, S. M. Miller, B. A. Reul, S. M. Brichard and
D. C. Crans, Inorg. Chem., 2000, 39, 406–416.

50 P. Chaurand, J. Rose, V. Briois, M. Salome, O. Proux,
V. Nassif, L. Olivi, J. Susini, J.-L. Hazemann and J.-Y.
Bottero, J. Phys. Chem. B, 2007, 111, 5101–5110.

51 A. Levina, R. S. Armstrong and P. A. Lay, Coord. Chem. Rev.,
2005, 249, 141–160.

52 E. J. Baran, J. Inorg. Biochem., 2009, 103, 547–553.
53 (a) T. W. Hambley, R. J. Judd and P. A. Lay, Inorg. Chem.,

1992, 31, 343–345; (b) G. Barr-David, T. W. Hambley, J. A.
Irwin, R. J. Judd, P. A. Lay, B. D. Martin, R. Bramley,
N. E. Dixon, P. Hendry, J.-Y. Ji, R. S. U. Baker and A. M.
Bonin, Inorg. Chem., 1992, 31, 4906–4908; (c) R. Codd, T. W.
Hambley and P. A. Lay, Inorg. Chem., 1995, 34, 877–882;

(d) R. Codd, P. A. Lay and A. Levina, Inorg. Chem., 1997, 36,
5440–5448.

54 (a) R. Codd, J. A. Irwin and P. A. Lay, Curr. Opin. Chem. Biol.,
2003, 7, 213–219; (b) C. Z. Soe, A. A. H. Pakchung and
R. Codd, Inorg. Chem., 2014, 53, 5852–5861.

55 B. Song, N. Aebischer and C. Orvig, Inorg. Chem., 2002, 41,
1357–1364.

56 P. C. Wilkins, M. D. Johnson, A. A. Holder and D. C. Crans,
Inorg. Chem., 2006, 45, 1471–1479.

57 I. A. Setyawati, K. H. Thompson, V. G. Yuen, Y. Sun,
M. Battell, D. M. Lyster, C. Vo, T. J. Ruth, J. H. Zeisler,
J. H. McNeill and C. Orvig, J. Appl. Physiol., 1998, 84,
569–575.

58 K. Dralle Mjos and C. Orvig, Chem. Rev., 2014, 114, 4540–4563.
59 (a) M. Aureliano and D. C. Crans, J. Inorg. Biochem., 2009, 103,

536–546; (b) A. Chatkon, P. B. Chatterjee, M. A. Sedgwick,
K. J. Haller and D. C. Crans, Eur. J. Inorg. Chem., 2013,
1859–1868; (c) M. Aureliano, Inorg. Chim. Acta, 2014, 420, 4–7.

60 K. Pantopoulos, S. Kumar Porwal, A. Tartakoff and
L. Devireddy, Biochemistry, 2012, 51, 5705–5724.

61 (a) I. Bertini, C. Luchinat and L. Messori, J. Inorg. Biochem.,
1985, 25, 57–60; (b) J. Costa Pessoa, G. Gonçalves, S. Roy,
I. Correia, S. Mehtab, M. F. A. Santos and T. Santos-Silva,
J. Inorg. Biochem., 2014, 420, 60–68.

62 T. Ueki and H. Michibata, Coord. Chem. Rev., 2011, 255,
2249–2257.

63 M. Ciampolini and F. Mani, Inorg. Chim. Acta, 1977, 24,
91–95.

64 A. J. Ghio, C. A. Piantadosi, X. Wang, L. A. Dailey, J. D.
Stonehuerner, M. C. Madden, F. Yang, K. G. Dolan,
M. D. Garrick and L. M. Garrick, Am. J. Physiol.: Lung Cell.
Mol. Physiol., 2005, 289, L460–L467.

65 T. Ueki, N. Furuno and H. Michibata, Biochim. Biophys. Acta,
2011, 1810, 457–464.

66 (a) D. Sanna, M. Serra, G. Micera and E. Garriba, Inorg.
Chem., 2014, 53, 1449–1464; (b) D. Sanna, M. Serra,
G. Micera and E. Garriba, Inorg. Chim. Acta, 2014, 420,
75–84.

67 A. Levina, A. I. McLeod, S. J. Gasparini, W. G. M. De Silva,
J. B. Aitken, C. J. Glover, B. Johannessen and P. A. Lay, 2014,
to be submitted.

68 A. I. McLeod, A. Pulte, J. B. Aitken, A. Levina and P. A. Lay,
2014, to be submitted.

69 (a) T. Kiss and A. Odani, Bull. Chem. Soc. Jpn., 2007, 80,
1691–1702; (b) D. C. Crans, K. A. Woll, K. Prusinskas,
M. D. Johnson and E. Norkus, Inorg. Chem., 2013, 52,
12262–12275.

Metallomics Paper

D
ow

nloaded from
 https://academ

ic.oup.com
/m

etallom
ics/article/6/10/1880/6007943 by guest on 12 Septem

ber 2025