Design, synthesis and applications of hyaluronic acid-paclitaxel bioconjugates

Article abstract of DOI:10.3390/molecules13020360

Paclitaxel (1a), a well known antitumor agent adopted mainly for the treatment of breast and ovarian cancer, suffers from significant disadvantages such as low solubility, certain toxicity and specific drug-resistance of some tumor cells. To overcome thes

Full text of DOI:10.3390/molecules13020360

Molecules 2008, 13, 360-378
molecules
ISSN 1420-3049
© 2008 by MDPI
www.mdpi.org/molecules
Review
Design, Synthesis and Applications of Hyaluronic
Acid-Paclitaxel Bioconjugates^†
Francesca Leonelli, Angela La Bella, Luisa Maria Migneco and Rinaldo Marini Bettolo*
Dipartimento di Chimica and Istituto di Chimica Biomolecolare del CNR, Sezione di Roma,
Università degli Studi di Roma "La Sapienza”, P.le Aldo Moro 5, BOX n. 34 ROMA 62, I-00185
Roma, Italy; E-mails: francesca.leonelli@uniroma1.it, angela.labella@uniroma1.it,
luisamaria.migneco@uniroma1.it
^†Dedicated to the Memory of Prof. Vittorio Crescenzi [1]
* Author to whom correspondence should be addressed. E-mail: rinaldo.marinibettolo@uniroma1.it
Received: 29 January 2008; in revised form: 11 February 2008 / Accepted: 11 February 2008 /
Published: 12 February 2008
Abstract: Paclitaxel (1a), a well known antitumor agent adopted mainly for the treatment
of breast and ovarian cancer, suffers from significant disadvantages such as low solubility,
certain toxicity and specific drug-resistance of some tumor cells. To overcome these
problems extensive research has been carried out. Among the various proposed strategies,
the conjugation of paclitaxel (1a) to a biocompatible polymer, such as hyaluronic acid
(HA, 2), has also been considered. Coupling a bioactive compound to a biocompatible
polymer offers, in general, many advantages such as better drug solubilization, better
stabilization, specific localization and controlled release. Hereafter the design, synthesis
and applications of hyaluronic acid-paclitaxel bioconjugates are reviewed. An overview of
HA-paclitaxel combinations is also given.
Keywords: Paclitaxel, Hyaluronic Acid, Hyaluronic Acid-Paclitaxel Bioconjugate,
Synthesis, Biological Activity.

Molecules 2007, 12
1. Introduction
1.1.Paclitaxel
361
Paclitaxel (1a), a taxane diterpenoid isolated in 1967 from the bark of Taxus brevifolia (Pacific
yew) [2], is a well known antitumor agent adopted mainly for the treatment of breast [3-5] and ovarian
cancer [5-8]. Paclitaxel is a mitotic inhibitor which acts by interfering in the normal microtubule
growth during cell division.
O
R¹O
O
OH
O
HN
Ph
7
10
; R¹ = Ac
2'
1a R =
13
RO
3'
Ph
O
OH
H
OBz
HO
OAc
1b R = H; R¹ = H
Since the beginning, the difficulty of paclitaxel availability was evident, owing to its scarcity in the
bark (10 g of pure material from 1,200 Kg of bark) and to the fact that the use of this tree as the only
source of compound 1a would have rapidly caused its disappearance. In addition, owing to the
complexity of its structure, paclitaxel can only be obtained in trace amounts by total synthesis. Thus,
studies aimed to develop alternative ways of supply were initiated by Green, Guéritte-Voegelein and
co-workers [9] and Holton [10]. These authors developed a semisynthetic route to paclitaxel starting
from 10-deacetylbaccatin III (1b), extracted in high yield from the leaves of Taxus baccata L.
(European yew). The Holton preparation was licensed to Bristol-Myers Squibb enabling the company
to produce 1a on a very large scale. Currently paclitaxel production employs plant cell fermentation
technology [11], but the search for new semisynthetic routes or new culturing media is still in
progress, due to the excellent antitumor properties of this drug.
Despite the above valuable therapeutic features, paclitaxel suffers from significant disadvantages
among which low water solubility, certain toxicity (which limits the clinically administered dose) and
specific drug-resistance of some tumor cells [12]. Owing to its low water solubility it is generally
administered as a castor oil (Cremophor®)/EtOH solution. This type of administration requires
hospitalization, since side effects such as hypersensivity, may occur [8, 13-14]. In addition it has been
reported that Cremophor® reduces the free paclitaxel fraction because of its entrapment in
Cremophor® micelles [15-16].
1.2.Hyaluronic Acid
Hyaluronic acid (HA, 2) is a glycosaminoglycan found distributed throughout the connective,
epithelial and neural tissues [17]. It is one of the main components of the extracellular matrix,
contributes significantly to cell proliferation and migration and is also involved in the progression of
some malignant tumors where it is highly concentrated; besides, it turns out to be an important signal
for activating kinase pathways [18-19] and regulating angiogenesis [20]. Moreover, since some
specific HA receptors (CD44, RHAMM) are overexpressed in various malignant cell types, linking an

Molecules 2007, 12
362
antitumor drug to 2 might improve targeting to cancerous cells and overcome, if the case, the problem
of low drug hydrosolubility. For these reasons, HA has been linked to various antitumor drugs [21,
22].
R
OH
O
O
O
O
HO
HO
O
OH
NH
O
n
2 HA R = OH
9 HA-ADH R = HNNHC(=O)(CH₂)₄C(=O)NHNH₂
11 HA-TBA R = O(Bu₄N)
13 HA-NH₂ R = NH(CH₂)₂NH₂
1.3. Paclitaxel Derivatives
To overcome the disadvantages related to paclitaxel's low water solubility and toxicity, extensive
research has been carried out and various strategies have been proposed, such as for instance, changes
in its formulation [8, 23-26] and the preparation of new derivatives, mainly through ester formation at
the C-2’ or C-7 positions [27]. In some of these derivatives, paclitaxel is linked to macromolecules,
such as poly(ethyleneglycol) [28-42], N-(2-hydroxypropyl)methacrylamide [39, 43-47], carboxy-
methyldextran [48], poly(L-glutamic acid) [49-74], peptides [75-76], proteins [77-79], dendrimers [37,
42, 80-81] and HA [82-87]. Joining a bioactive compound to a biocompatible polymer offers, in
general, several advantages like better drug solubilization, stabilization, localization and controlled
release [88-90]. For derivatives other than those quoted above, see [91-100].
In the present review we shall deal only with HA-paclitaxel bioconjugates. To the best of our
knowledge, only four HA-paclitaxel bioconjugates 3-6 (Figure 1) have been described so far in the
literature, differing mainly in the anchor chain between HA and paclitaxel.
Prestwich and co-workers, at Stony Brook University in New York and at the University of Utah in
Salt Lake City, pioneered these studies and made a major contribution to the field [82-83]. This work
was followed by the work at University of Rome “La Sapienza” of Crescenzi, Marini Bettolo and co-
workers [84-86], in collaboration with Padua based Fidia Farmaceutici S.p.A., and by that of Tabrizian
and co-workers at McGill University in Montreal [87]. Hereafter we wish to report on the design,
synthesis and applications of HA-paclitaxel bioconjugates 3-6, prepared by the above mentioned
groups. An overview of HA-paclitaxel combinations is also given.
2. Synthesis and Applications of HA-paclitaxel Bioconjugates 3-4
2.1. Synthesis
Prestwich and co-workers prepared bioconjugate 3 [82-83] by the dihydrazide method [101-103].
This method was developed with the aim of obtaining under mild conditions, necessary to avoid HA
degradation, a HA derivative bearing a terminal hydrazido group which would have allowed further

Molecules 2007, 12
363
coupling still under mild conditions. The spacer should have eased intracellular enzyme degradation or
hydrolytic cleavage [90]. Thus paclitaxel 1a was first reacted with succinic anhydride and pyridine at
room temperature for 3 days to give the 2’-hemisuccinate paclitaxel derivative 7, that in turn was
transformed, by a reaction with N-hydroxysuccinimido diphenyl phosphate, into 2’-ester 8 containing
a N-hydroxysuccinimide moiety. Finally 8 was reacted with adipic dihydrazide modified HA 9 (HA-
ADH), prepared from low molecular weight HA 2 and adipic dihydrazide [101-103] at pH 6.5 [104] in
a 3mM phosphate buffer and DMF mixture (Scheme 1).
Figure 1. HA-paclitaxel Bioconjugates 3-6.
O
AcO
O
OH
Ph
NH
O
O
2'
Ph
O
O
O
O
H
OBz
HO
OAc
H
N
N
H
O
O
NH
HN
R
OH
OH
O
O
O
O
O
O
HO
HO
O
HO
HO
O
O
O
OH
NH
OH
NH
O
O
n
3 R = OH
O
OH
H
H
H
N
N
N
4 R =
HN
N
H
O
S
O
HOOC
O
O
AcO
O
OH
Ph
NH
O
O
AcO
O
OH
2'
Ph
O
Ph
NH
O
O
2'
O
O
H
OBz
Ph
O
O
HO
OAc
O
O
H
OBz
HO
OAc
OH
HN
O
O
O
NH
O
O
O
HO
HO
OH
O
O
OH
NH
n
O
O
O
HO
O
HO
O
5
OH
NH
O
n
6

Molecules 2007, 12
364
The reasons for using low molecular weight HA were: to monitor the biopolymer loading by
NMR; to have a readily injectable non viscous solution; besides, once in the plasma, low molecular
weight HA is taken up quickly by cells without further degradation and can be expelled from the body
via kidneys. Coupling paclitaxel derivative 8 with HA-ADH 9, gave bioconjugate 3 after dialysis and
lyophilization. By varying the 8/9 ratio several bioconjugates of type 3 were prepared, whose
hydrosolubility depends on ADH and paclitaxel 2’-hemisuccinate loading.
Evaluation of bioconjugate 3 ability to bind to tumor cells and its subsequent internalization by
cells, was achieved by converting it with fluorescein isothiocyanate (FITC) in DMF into the
fluorescently labeled HA-paclitaxel derivative 4 [83].
Scheme 1. Preparation of Bioconjugate 3.
O
AcO
O
OH
Ph
NH
O
2'
Ph
O
O
a)
b)
1a
O
O
H
OBz
HO
OAc
O
OH
7
O
AcO
O
OH
Ph
NH
O
2'
Ph
O
O
O
O
H
OBz
d)
c)
HO
OAc
4
3
O
O
O
N
O
8
a) Succinic anhydride, CH₂Cl₂, pyridine, r.t., 3 d; b) N-hydroxysuccinimidobiphenyl phosphate,
MeCN, Et₃N, r.t., 6 h; c) HA-ADH 9, DMF/H₂O 2:1, r.t., 24 h, pH 6.5 [82-83] or pH 8.5 [105]; d)
fluorescein isothiocyanate, DMF, r.t., 12 h.
2.2. In Vitro Antitumor Activity of Bioconjugates 3-4
Bioconjugate 3 showed effective in vitro cytotoxicity against HCT-116 (colon tumors), SK-OV-3
(ovarian cancer) and HBL-100 (breast cancer) human cell lines [82-83]. In contrast, no cytotoxicity
was observed against NIH 3-T-3 (nontransformed mouse fibroblast) cell lines. Selective toxicity was
attributed to receptor-mediate binding and uptake of HA-paclitaxel bioconjugate owing to
overexpression of CD44 receptors by the above human cell lines. Selective targeting due to the
receptor characteristic was then confirmed by the possibility of blocking bioconjugate uptake and

Molecules 2007, 12
365
toxicity with a 100-fold excess of high molecular weight HA and with anti-CD44 mAb; different
results were obtained with a 100-fold excess of chondroitin sulfate (a sulfated glycosaminoglycan).
Paclitaxel (1a) release from bioconjugate 3 was evaluated in various media. From these
experiments it was found that cleavage occurs at C-2’ ester function, owing to the greater stability of
the hydrazide linkage over the ester bond. Thus only free 1a is released. It was also observed that
release was dramatically accelerated in the presence of hydrolytic enzymes. Prestwich and co-workers
showed also that cytotoxicity of bioconjugate 3 depends on both HA (2) modification and paclitaxel
(1a) loading: high loading, in fact, lowers solubility and causes modification in the HA structure
masking the HA receptor recognition elements resulting in a citotoxicity decrease.
In vitro cytotoxicity of 3 against the CD44(+) human ovarian tumor cell lines SK-OV-3ip and
NMP-1 was also recently evaluated by Klostergaard and co-workers [105] at the University of Texas
in Houston. Their results turned out to be in good agreement with those previously obtained by
Prestwich and co-workers [82-83], especially as far as “cell targeting” ability is concerned.
Klostergaard and co-workers have shown, in fact, that the ability of 3 to reduce cell survival was
inhibited by preblocking the HA binding sites with HA 2 (≈40 kDa).
2.3. In Vivo Antitumor Activity of Bioconjugate 3
Better in vivo antitumor efficacy and lower toxicity against CD44(+) human ovarian carcinoma
xenografts NMP-1 and SKOV-3ip, as compared to free paclitaxel, was also demonstrated by the same
authors for bioconjugate 3 [105].
3. Synthesis and Applications of HA-paclitaxel Bioconjugate 5
3.1. Synthesis
The approach chosen by Crescenzi, Marini Bettolo and co-workers, in collaboration with FIDIA
Farmaceutici S.p.A., a pharmaceutical company involved for many years in the production and
derivatization of HA, is quite simple. Paclitaxel 1a was joined to HA by means of a spacer linked to
both paclitaxel 1a and HA 2 via ester functions (Scheme 2) [84-86].
Scheme 2. Preparation of Bioconjugate 5.
O
AcO
O
OH
Ph
NH
O
2'
a)
b)
1a
Ph
O
O
5
O
O
H
OBz
HO
OAc
Br
10
a) 4-Bromobutanoic acid, EDC, DMAP, CH₂Cl₂, r.t.; b) HA-TBA 11, NMP, r.t.

Molecules 2007, 12
366
Thus, paclitaxel was treated at room temperature with 4-bromobutanoic acid in the presence of 1-
[3-(dimethylamino)propyl]-3-ethylcarbodiimide hydrochloride (EDC) and N,N-dimethylpyridine-4-
amine (DMAP) to cleanly give in 78 % yield paclitaxel 2’-(4-bromobutanoate) (10, Scheme 2). The
authors confirmed the formation of a 2’-O-substituted paclitaxel derivative by the characteristic
downfield shifts in the ¹H- and ¹³C-NMR of the signals of H-C(2’) from δ(H) 4.77 [91] to 5.50 and of
C(2’) from δ(C) 73.2 [91] to 74.2, respectively.
Compound 10 was then dissolved in 1-methylpyrrolidin-2-one (NMP) and treated for 7 days at
room temperature with HA-TBA 11 (Mw = 185 kDa; 10/11 1:4) to give 5. The ratio of reactants
chosen was a good compromise to give hydrosoluble bioconjugate. Bioconjugate 5 was isolated from
the reaction mixture after EtOH/NaCl precipitation, extensive dialysis (cut off ca. 2 kDa) against
distilled water and finally freeze-dried.
A ca. 25% substitution degree was deduced for 5 by comparing its UV absorbance in EtOH/H₂O
7:3 with a UV-absorption calibration plot of paclitaxel 1a and HA-Na. Compound 5 was hydrosoluble.
As for the bioconjugate 3 paclitaxel loading can be varied by changing the 10/11 ratio.
3.2. In Vitro Antitumor Activity of Bioconjugate 5
The in vitro antitumor activity of a hydrosoluble bioconjugate 5 with a 20% wt/wt carboxyl
esterification, was tested in respect to bladder cancer cells by Rosato and co-workers at Padua
University [85, 106]. The in vitro 5 inhibitory activity on the growth of RT-4 and RT-112/84 bladder
cancer cells was much stronger than that of paclitaxel (1a). Furthermore, the powerful increase in
efficiency of 5 in respect to 1a was attributed, as in the case of bioconjugate 3, to the active
intracellular uptake mediated by specific HA receptors (CD44) overexpressed on the tumor cell
surface and a subsequent hydrolytic release of the active drug in the intracellular medium only. To
prove whether the CD44 HA receptor could directly interact with 5, the CD44 expression was also
analyzed at different times after RT-4 and RT112/84 cells were incubated with either the bioconjugate
5 or HA 2. In both cases the authors noted a similar striking up-regulation in the CD44 expression
showing therefore a direct interaction of conjugated HA with the receptor. The stability of 5 was tested
in human urine and no bioconjugate degradation or paclitaxel release was observed 6 hours after
incubation (pH 6.5).
3.3. In Vivo Antitumor Activity of Bioconjugate 5
Rosato and co-workers also studied [106] the in vivo antitumor therapeutic activity of bioconjugate
5 by inoculating subcutaneously RT-112/84 TCC bladder tumor cells in mice. A comparison between
the antitumor activity of paclitaxel (1a) and bioconjugate 5 showed that the efficacy of 1a and 5 is
equal though the former has a slightly stronger cytoreductive activity.
A pharmacokinetic analysis of 5 was also performed in order to exclude the presence of paclitaxel
1a in the blood after administration of bioconjugate 5 to rat bladder. According to the authors,
although the stability of 5 had already been tested in vitro, it might be possible that release of
paclitaxel takes place in vivo after bladder instillation. The experiments confirmed that paclitaxel
concentration in the blood was negligible, since after administration it remained entirely confined in

Molecules 2007, 12
367
the bladder. Mice were also treated locally with bioconjugate 5 and paclitaxel to determine whether 5
was well tolerated by the urothelial mucosa. From this study it emerged that bioconjugate 5 is very
well tolerated and induces only slight morphologic changes in the urothelial epithelium, while
paclitaxel produces notable toxic effects on the bladder.
In order to establish its potential therapeutic applications and to evaluate its biodistribution after
intravenous, intravesical, oral or intraperitoneal administration in healthy mice, Meléndez-Alafort and
co-workers [107] at the University of Padua, labeled bioconjugate 5 with ^99mTc by treating it with a
^99mTc-pertechnetate solution, SnCl₂ and sodium gluconate. The solution was stirred and incubated at
65°C for 90 min. The radiopharmaceutical was purified by size exclusion chromatography and the
radiochemical purity of the labeled bioconjugate 5 prepared in this way was 100%. The ^99mTc labeled
bioconjugate 5 was stable for 6 h at 37°C in a phosphate buffer.
From biodistribution studies it emerged that the animals injected intravenously with the ^99mTc
labeled bioconjugate 5 showed a rapid and high liver and spleen uptake, while those administered
intraperitoneally, intravesically and orally showed that it remained at the administration site.
Therefore, according to Meléndez-Alafort and co-workers, bioconjugate 5 should be administered
intravenously for liver metastasis therapy, orally or intravesically for local treatment of bladder and
superficial cancers and intraperitoneally for ovarian cancer or other tumors in the peritoneal cavity.
4. Synthesis and Applications of HA-paclitaxel Bioconjugate 6 and Biomaterial 14
4.1. Synthesis
In the field of drug delivery, great attention has been recently devoted to the possibility of
incorporating bioactive molecules into polymeric matrices [108-113]. An approach developed some
years ago based on alternate deposition of polyanion and polycation layers leading to polyelectrolyte
multilayer (PEM) films, constructed by the layer-by-layer (LbL) technique, can be used to build up
polymeric matrices in a controlled manner. PEMs may present some advantages in drug delivery such
as the possibility of including several drugs. It is, therefore, suitable for complex releasing
pharmacokinetics. Tabrizian and co-workers [87] reported on the assembling of HA-paclitaxel
bioconjugate 6 (Figure 1), previously described by Prestwich and co-workers [82] in a PEM system
with chitosan 12 (CH) to give biomaterial 14.
The preparation of biomaterial 14 started from known 8 [82] (Section 2.1 and Scheme 1). The
latter was reacted with 13 (see section 1.2), prepared in turn treating HA (2, Mw = 0.5 MDa) with
ethylenediamine hydrochloride (EDA) and EDC in a buffered medium (pH 5) at r.t. for 12 h, purifying
the reaction mixture by dialysis against water and freeze-drying the resulting aqueous solution.
Coupling of paclitaxel derivative 8 with 13 was performed at room temperature for 24 h in a DMF
and phosphate buffer (pH 6.5). After that time the crude compound was purified by dialysis to give
two bioconjugates 6 with 3 and 6 mol % paclitaxel loading respectively; only the former, however,
exhibited the hydrosolubility necessary for the PEM preparation.

Molecules 2007, 12
368
Scheme 3. Preparation of Biomaterial 14.
O
AcO
O
OH
Ph
NH
O
2'
Ph
O
O
O
O
b)
a)
H
OBz
OH
6
8
HO
OAc
NH₂
O
HO
O
HO
O
O
NH₂
HN
O
6
OH
n
12 chitosan
NH
OH
O
O
O
O
HO
HO
O
OH
NH
O
n
14
a) 13, DMF, pH 6.5, r.t., 24 h; b) polyelectrolyte multilayer construction with polyethyleneimine,
HA 2, HA-paclitaxel 6, chitosan (12).
The final multilayer was obtained by consecutive adsorption of oppositely charged polyelecrolytes
[CH, HA-paclitaxel 6 (3 mol %)]. Paclitaxel 1a release studies were conducted on 10 bilayers of
CH/HA-paclitaxel (CH/HA-paclitaxel)₁₀. The latter were kept in contact with water which was then
removed at different times. By measuring the UV absorbance of released compound 1a, it was found
that the half-life time of 1a was ≈ 3 h. PEM constructed with rhodamine-labeled chitosan (CH-
Rho/HA-paclitaxel)₁₀ were subjected to the same release test; contact water UV spectra showed only
the paclitaxel absorbance peak, while that of rhodamine was lacking, proving in this way the
multilayer stability during release experiments.
4.2. In Vitro Antitumor Activity of Biomaterial 14
In vitro activity of biomaterial 14 was evaluated by means of a cell viability assay. While cells
cultured onto (CH/HA-paclitaxel)₁₀ showed a 95% reduction in viability after 4 days, those cultured
onto (CH/HA)₁₀ showed no reduction in viability [87].
5. HA-paclitaxel Combinations
Although this review is mainly focused on the HA-paclitaxel bioconjugates, for the sake of
completeness, we wish to present hereafter a small section on HA-paclitaxel combinations, i.e. species
in which no covalent links between HA (2) and paclitaxel (1a) are present, and on their bioactivity.

Molecules 2007, 12
369
5.1. Paclitaxel-loaded Crosslinked HA Films for the Prevention of Postsurgical Adhesions
Burt and co-workers at the University of British Columbia [114] investigated the use of paclitaxel
(1a) as an inhibitor of postsurgical adhesion by loading it into a biocompatible, mucoadhesive film of
crosslinked HA to be applied to abraded tissues in order to release the drug over 2-3 days. Since 1a is
as a powerful wound healing inhibitor, its permanence on the wound for a limited time might reduce
the formation of postsurgical adhesions. After several optimization studies, HA films crosslinked with
2 mM EDAC and 10% glycerol were found to posses suitable flexibility, elasticity and dissolution
properties. In these films paclitaxel was present as a solid dispersion. According to Burt and co-
workers a possible mechanism for drug release involves the uptake of water, the swelling of the
crosslinked HA matrix and the dissolution of dispersed paclitaxel.
An in vivo comparison between the administration of paclitaxel on the abrasion of the rat cecal side
wall by repeated intraperitoneal injections in a 1:1 Cremophor EL®:ethanol formulation and by
loading it into a crosslinked HA film showed similar, though incomplete, inhibition of adhesion
formations in rats.
5.2. In vivo Inhibition of Mice Lewis Lung Carcinoma and U14 Cervical Tumor By Combination of
Paclitaxel and HA.
Yuan and co-workers [115] at Tianjin University have investigated the effects of combined
administration of HA (2) with Cremophor® solutions of paclitaxel (1a) on the control of Lewis lung
carcinoma (LLC) migration and ascites formation of U14 cervical tumor. In vivo studies on mice
showed that the combined use of HA and paclitaxel is more effective in inhibiting metastasis of LLC
and U14 than HA or paclitaxel alone. Thus, Yuan and co-workers hypothesized that the synergic
behavior of paclitaxel and HA might be due to an increased host immunity. The increase in the
expression of vitamin D₃ binding protein (DBP), a macrophage stimulating activator, may be a crucial
factor in inhibiting the activity of tumor cells. Yuan and co-workers [115] found that DBP expression
was increased by administrating the paclitaxel-HA combination. The administration of HA or
paclitaxel alone did not have the same effects.
5.3. Polyelectrolyte Multilayers Films Incorporating Paclitaxel
As outlined in Section 4, PEMs have recently become an appropriate substrate coating able to
incorporate biological factors for example peptides, proteins, hormones, growth factors or drugs [116-
121]. The final aim of such approaches is that of controlling the rate and selectivity of cellular
adhesion.
In their studies at Louis Pasteur University in Strasbourg Vodouhê, Lavalle and co-workers [122]
designed a polylysine/hyaluronic acid (PLL/HA) based multilayers surface coating which acts as a
reservoir for paclitaxel without the need of chemical modifications both on the PEM and on the drug.
The amount of compound 1a embedded in PLL/HA films could be finely tuned. The authors tested the
viability of HT29 cell line seeded on (PLL/HA)₃₀ film. Unfortunately these in vitro studies showed
these films did not adhere the cells. The HT29 cellular adhesion occurred when the film surface was

Molecules 2007, 12
370
modified by adding a poly(sodium 4-styrene sulfonate) (PSS) layer on the top of PLL/HA films. As
shown previously by Chan and co-workers [123], a sulfonate group of PSS chains adsorbed on the
surface not only is able to promote cellular adhesion, but also allows modulation of the accessibility of
HT29 cells to paclitaxel in terms of delay and/or kinetics by varying its composition. Paclitaxel
activity remained constant after embedding in the polyelectrolyte multilayers and cellular viability
could be reduced of about 80% 96 h after seeding.
6. Conclusions
HA-paclitaxel hydrosoluble bioconjugates appear promising in cancer therapy. Their cytotoxicity
against various cancer cell lines is, in fact, comparable to that of free paclitaxel (1a) and systemic
toxicity reduced owing to selective targeting of cancer cells due to HA CD44 receptors
overexpression. Besides, as illustrated in the Introduction, the problems connected with the
administration of paclitaxel in a castor oil (Cremophor®)/EtOH solution can be avoided. From
biodistribution studies it appears recommendable a different way of administration depending on
tumor localization. The preparation of nanobiomaterials incorporating HA-paclitaxel bioconjugates
offers a further solution for the delivery of this valuable drug. Finally very interesting results were
obtained with HA-paclitaxel combinations both for cancer chemotherapy and for better wound healing
and prevention of postsurgical adhesion.
Acknowledgements
We are grateful to the Guest Editor and Editor-in-Chief of Molecules for inviting us to present this
review which offered us the opportunity to describe the work of the groups operating in the field of
HA-paclitaxel bioconjugates and combinations. Financial support by Università degli Studi di Roma
“La Sapienza” (Ateneo 60%) is gratefully acknowledged.
References and Notes
1. Prof. Vittorio Crescenzi (12-Jan-1932-12-Jun-2007), a leading scientist in the field of
macromolecules and biopolymers, taught in several Italian Universities (Bari, Napoli, Trieste,
Roma “La Sapienza”). He was a NATO Fellow in the Laboratory of Nobel Laureate P.J. Flory at
Stanford University and Visiting Professor at Stevens Institute of Technology in Hoboken, N.J.
2. Wani, M.C.; Taylor, H.L.; Wall, M.E.; Coggon, P.; McPhail, A.T. Plant antitumor agents. VI.
Isolation and structure of Taxol, a novel antileukemic and antitumor agent from Taxus brevifolia.
J. Am. Chem. Soc. 1971, 93, 2325-2327.
3. Perez, E.A. Paclitaxel in breast cancer. Oncologist 1998, 3, 373-389.
4. Gibbs, J.B. Mechanism-based target identification and drug discovery in cancer research. Science
2000, 287, 1969-1973.
5. Jordan, M.A.; Wilson, L. Microtubules as a target for anticancer drugs. Nat. Rev. Cancer 2004, 4,
253-265.

Molecules 2007, 12
371
6. Markman, M. Weekly paclitaxel in the management of ovarian cancer. Semin. Oncol. 2000, 27,
37-40.
7. Seiden, M.V. Ovarian Cancer, Oncologist 2001, 6, 327-332.
8. Singla, A.K.; Garg, A.; Aggarwal, D. Paclitaxel and its formulations. Int. J. Pharm. 2002, 235,
179-192.
9. Denis, J.-N.; Greene, A.E.; Guénard, D.; Guéritte-Voegelein, F.; Mangatal, L.; Potier, P. Highly
efficient, practical approach to natural Taxol. J. Am. Chem. Soc. 1988, 110, 5917-5919.
10. Holton, R.A. Method for preparation of Taxol. Eur. Pat. Appl. 1990, EP 400971.
11. Patel, R.N. Tour de Paclitaxel: biocatalysis for semisynthesis. Annu. Rev. Microbiol. 1998, 52,
361-395.
12. Galletti, E.; Magnani, M.; Renzulli, M.L.; Botta, M. Paclitaxel and docetaxel resistance:
molecular mechanisms and development of new generation taxanes. ChemMedChem 2007, 2,
920-942.
13. Szebeni, J.; Muggia, F.M.; Alving, C.R. Complement activation by Cremophor EL as a possible
contributor to hypersensitivity to paclitaxel: an in vitro study. J. Natl. Cancer Inst. 1998, 90, 300-
306.
14. Thigpen, J.T. Chemotherapy for advanced ovarian cancer: overview of randomized trials. Semin.
Oncol. 2000, 27, 11-16.
15. Knemeyer, I.; Wientjes, M.G.; Au, J.L.-S. Cremophor reduces paclitaxel penetration into bladder
wall during intravesical treatment. Cancer Chemother. Pharmacol. 1999, 44, 241-248.
16. Gelderblom, H.; Verweij, J.; Van Zomeren, D. M.; Buijs, D.; Ouwens, L.; Nooter, K.; Stoter, G.;
Sparreboom, A. Influence of Cremophor EL on the bioavailability of intraperitoneal paclitaxel.
Clin. Cancer Res. 2002, 8, 1237-1241.
17. Laurent, T.C.; Laurent, U.B.; Fraser, J.R. Functions of hyaluronan. Ann. Rheum. Dis. 1995, 54,
429-432.
18. Misra, S.; Toole, B.P.; Ghatak, S. Hyaluronan constitutively regulates activation of multiple
receptor tyrosine kinases in epithelial and carcinoma cells. J. Biol. Chem. 2006, 281, 34936-
34941.
19. Ohno, S.; Im, H.-J.; Knudson, C.B.; Knudson, W. Hyaluronic oligosaccharides induce matrix
metalloproteinase 13 via transcriptional activation of NFkB and p38 MAP kinase in articular
chondrocytes. J. Biol. Chem. 2006, 281, 17952-17960.
20. Rooney, P.; Kumar, S.; Ponting, J.; Wang, M. The role of hyaluronan in tumour
neovascularization (review). Int. J. Cancer 1995, 60, 632-636.
21. Akima, K.; Ito, H.; Iwata, Y.; Matsuo, K.; Watari, N.; Yanagi, M.; Hagi, H.; Oshima, K.; Yagita,
A.; Atomi, Y.; Tatekawa, I. Evaluation of antitumor activities of hyaluronate binding antitumor
drugs: synthesis, characterization and antitumor activity. J. Drug Target. 1996, 4, 1-8.
22. Jaracz, S.; Chen, J.; Kuznetsova L.V.; Ojima, I. Recent advances in tumor-targeting anticancer
drug conjugates. Bioorg. Med. Chem. 2005, 13, 5043-5054.
23. Pawar, R.; Shikanov, A.; Vaisman, B.; Domb, A.J. Intravenous and regional paclitaxel
formulations. Curr. Med. Chem. 2004, 11, 397-402.
24. Kim, T.-Y.; Kim, D.-W.; Chung, J.-Y.; Shin, S.G.; Kim, S.-C.; Heo, D.S.; Kim, N.K.; Bang, Y.-J.
Phase I and pharmacokinetic study of Genexol-PM, a Cremophor-free, polymeric micelle-

Molecules 2007, 12
372
formulated paclitaxel, in patients with advanced malignancies. Clin. Cancer Res. 2004, 10, 3708-
3716.
25. Wang, Y. Tocosol® paclitaxel. Anticancer formulation. Drugs Fut. 2006, 31, 40-42.
26. Henderson, I.C.; Bhatia, V. Nab-paclitaxel for breast cancer: a new formulation with an improved
safety profile and greater efficacy. Exp. Rev. Anticancer Ther. 2007, 7, 919-943.
27. Skwarczynki, M.; Hayashi, Y.; Kiso, Y. Paclitaxel prodrugs: toward smarter delivery anticancer
agents. J. Med. Chem. 2006, 49, 7253-7269, and references cited therein
28. Greenwald, R.B.; Pendri, A.; Bolikal, D.; Gilbert, C.W. Highly water soluble taxol derivatives:
2’-polyethylene glycol esters as potential prodrugs. Bioorg. Med. Chem. Lett. 1994, 4, 2465-2470.
29. Greenwald, R.B.; Pendri, A.; Bolikal, D. Highly water soluble taxol derivatives: 7-polyethylene
glycol carbamates and carbonates. J. Org. Chem. 1995, 60, 331-336.
30. Li, C.; Yu, D.; Inoue, T.; Yang, D.J.; Milas, L.; Hunter, N.R.; Kim, E.E.; Wallace, S. Synthesis
and evaluation of water-soluble polyethylene glycol-paclitaxel conjugate as a paclitaxel prodrug.
Anticancer Drugs 1996, 7, 642-648.
31. Greenwald, R.B.; Gilbert, C.W.; Pendri, A.; Conover, C.D.; Xia, J.; Martinez, A. Drug delivery
systems: water soluble taxol 2’-poly(ethylene glycol) ester prodrugs-design and in vivo
effectiveness. J. Med. Chem. 1996, 39, 424-431.
32. Pendri, A.; Conover, C.D.; Greenwald, R.B. Antitumor activity of paclitaxel-2’-glycinate
conjugate to poly(ethylene glycol): a water soluble prodrug. Anticancer Drug Des. 1998, 13, 387-
395.
33. Ceruti, M.; Crosasso, P.; Brusa, P.; Arpicco, S.; Dosio, F.; Cattel. L. Preparation, characterization,
cytotoxicity and pharmacokinetics of liposomes containing water-soluble prodrugs of paclitaxel.
J. Controlled Release 2000, 63, 141-153.
34. Feng, X.; Yuan, Y.-J.; Wu, J.-C. Synthesis and evaluation of water-soluble paclitaxel prodrugs.
Bioorg. Med. Chem. Lett. 2002, 12, 3301-3303.
35. Rodrigues, P.C.; Scheuermann, K.; Stockmar, C.; Maier, G.; Fiebig, H.H.; Unger, C.; Mülhaupt,
R.; Kratz, F. Synthesis and in vitro efficacy of acid-sensitive poly(ethylene glycol) paclitaxel
conjugates. Bioorg. Med. Chem. Lett. 2003, 13, 355-360.
36. Zhang, X.; Li, Y.; Chen, X.; Wang, X.; Xu, X.; Liang, Q.; Hu, J.; Jing, X. Synthesis and
characterization of the paclitaxel/MPEG-PLA block copolymer conjugate. Biomaterials 2005, 26,
2121-2128.
37. Khandare, J.J.; Jayant, S.; Singh, A.; Chandna, P.; Wang, Y.; Vorsa, N.; Minko, T. Dendrimer
versus linear conjugate: influence of polymeric architecture on the delivery and anticancer effect
of paclitaxel. Bioconj. Chem. 2006, 17, 1464-1472.
38. Wermeckes, B.; Hess, M.; Dehne, S.; Jo, B.-W.; Sohn, J.-S. Characterization of PEG-modified
paclitaxel. Mater. Res. Innov, 2006, 10, 364-375.
39. Kratz, F.; Abu Ajai, K.; Warnecke, A. Anticancer carrier-linked prodrugs in clinical trials. Expert
Opin. Invest. Drugs 2007, 16, 1037-1058.
40. Xie, Z.; Lu, T.; Chen, X.; Lu, C.; Zheng, Y.; Jing, X. Triblock poly(lactic acid)-b-poly(ethylene
glycol)-b-poly(lactic acid)/paclitaxel conjugates: synthesis, micellization, and cytotoxicity. J.
Appl. Polym. Sci. 2007, 105, 2271-2279.

Molecules 2007, 12
373
41. Xie, Z.; Guan, H.; Chen, X.; Lu, C.; Chen, L.; Hu, X.; Shi, Q.; Jing, X. A novel polymer-
paclitaxel conjugate based on amphiphilic triblock copolymer. J. Controlled Release 2007, 117,
210-216.
42. Lim, J.; Simanek, E.E. Synthesis of water-soluble dendrimers based on melamine bearing 16
paclitaxel groups. Org. Lett. 2008, 10, 201-204.
43. Mendichi, R.; Rizzo, V.; Gigli, M.; Giacometti Schieroni, A. Dilute-solution properties of a
polymeric antitumor drug carrier by size-exclusion chromatography, viscometry, and light
scattering. J. Appl. Polym. Sci. 1998, 70, 329-338.
44. Meerum Terwogt, J.M.; ten Bokkel Huinink, W.W.; Schellens, J.H.M.; Schot, M.; Mandjes,
I.A.M.; Zurlo, M.G.; Rocchetti, M.; Rosing, H.; Koopman, F.J.; Beijnen, J.H. Phase I clinical and
pharmacokinetic study of PNU166945, a novel water-soluble polymer-conjugated prodrug of
paclitaxel. Anti-Cancer Drugs 2001, 12, 315-323.
45. Duncan, R.; Gac-Breton, S.; Keane, R.; Musila, R.; Sat, Y.N.; Satchi, R.; Searle, F. Polymer-drug
conjugates, PDEPT and PELT: basic principles for design and transfer from the laboratory to
clinic. J. Controlled Release 2001, 74, 135-146.
46. Rihova, B.; Kubackova, K. Clinical implications of N-(2-hydroxypropyl)methacrylamide
copolymers. Curr. Pharm. Biotechnol. 2003, 4, 311-322.
47. Haag, R.; Kratz, F. Polymer Therapeutics: concept and applications. Angew. Chem. Int. Ed. 2006,
45, 1198-1215.
48. Sugahara, S.; Kajiki, M.; Kuriyama, H.; Kobayashi, T. Paclitaxel delivery systems: the use of
amino acid linkers in the conjugation of paclitaxel with carboxymethyldextran to create prodrugs.
Biol. Pharm. Bull. 2002, 25, 632-641.
49. Multani, A.S.; Li, C.; Ozen, M.; Yadav, M.; Yu, D.-F.; Wallace, S.; Pathak, S. Paclitaxel and
water-soluble poly(L-glutamic acid)-paclitaxel induce direct chromosomal abnormalities and cell
death in a murine metastatic melanoma cell line. Anticancer Res. 1997, 17, 4269-4274.
50. Li, C.; Yu, D.-F.; Newman, R.A.; Cabral, F.; Stephens, L.C.; Hunter, N.; Milas, L.; Wallace, S.
Complete regression of well-established tumors using a novel water-soluble poly(L-glutamic
acid)-paclitaxel conjugate. Cancer Res. 1998, 58, 2404-2409.
51. Li, C.; Price, J.E.; Milas, L.; Hunter, N.R.; Ke, S.; Yu, D.-F.; Charnsangavej, C.; Wallace, S.
Antitumor activity of poly(L-glutamic acid)-paclitaxel on syngeneic and xenografted tumors.
Clin. Cancer Res. 1999, 5, 891-897.
52. Multani, A.S.; Li, C.; Ozen, M.; Imam, A.S.; Wallace, S.; Pathak, S. Cell-killing by paclitaxel in a
metastatic murine melanoma cell line is mediated by extensive telomere erosion with no decrease
in telomerase activity. Oncol. Rep. 1999, 6, 39-44.
53. Li, C.; Newman, R.A.; Wu, Q.-P.; Ke, S.; Chen, W.; Hutto, T.; Kan, Z.; Brannan, M.D.;
Charnsangavej, C.; Wallace, S. Biodistribution of paclitaxel and poly(L-glutamic acid)-paclitaxel
conjugate in mice with ovarian OCa-1 tumor. Cancer Chemother. Pharmacol. 2000, 46, 416-422.
54. Li, C.; Ke, S.; Wu, Q.P.; Tansey, W.; Hunter, N.; Buchmiller, L.M.; Milas, L.; Charnsangavej, C.;
Wallace, S. Tumor irradiation enhances the tumor-specific distribution of poly(L-glutamic acid)-
conjugated paclitaxel and its antitumor efficacy. Clin. Cancer Res. 2000, 6, 2829-2834.

Molecules 2007, 12
374
55. Oldham, E.A.; Li, C.; Ke, S.; Wallace, S.; Huang, P. Comparison of action of paclitaxel and
poly(L-glutamic acid)-paclitaxel conjugate in human breast cancer cells. Int. J. Oncol. 2000, 16,
125-132.
56. Li, C.; Ke, S.; Wu, Q.-P.; Tansey, W.; Hunter, N.; Buchmiller, L.M.; Milas, L.; Charnsangavej,
C.; Wallace, S. Potentiation of ovarian OCA-1 tumor radioresponse by poly(L-glutamic acid)-
paclitaxel conjugate. Int. J. Radiat. Oncol. Biol. Phys. 2000, 48, 1119-1126.
57. Ke, S.; Milas, L.; Charnsangavej, C.; Wallace, S.; Li, C. Potentiation of radioresponse by
polymer-drug conjugates. J. Controlled Release 2001, 74, 237-242.
58. Auzenne, E.; Donato, N.J.; Li, C.; Leroux, E.; Price, R.E.; Farquhar, D.; Klostergaard, J. Superior
therapeutic profile of poly-L-glutamic acid-paclitaxel copolymer compared with Taxol in
xenogeneic compartmental models of human ovarian carcinoma. Clin. Cancer Res. 2002, 8, 573-
581.
59. Singer, J.W.; Baker, B.; de Vries, P.; Kumar, A.; Shaffer, S.; Vawter, E.; Bolton, M.; Garzone, P.
Poly-(L)-glutamic acid-paclitaxel (CT-2103) [XYOTAX], a biodegradable polymeric drug
conjugate: characterization, preclinical pharmacology, and preliminary clinical data. Adv. Exp.
Med. Biol. 2003, 519, 81-99.
60. Milas, L.; Mason, K.A.; Hunter, N.; Li, C.; Wallace, S. Poly(L-glutamic acid)-paclitaxel
conjugate is a potent enhancer of tumor radiocurability. Int. J. Radiat. Oncol. Biol. Phys. 2003,
55, 707-712.
61. Tishler, R.B. Polymer-conjugated paclitaxel as a radiosensitizing agent-A big step forward for
combined modality therapy? Int. J. Radiation Oncology Biol. Phys. 2003, 55, 563-564.
62. Zou, Y.; Fu, H.; Ghosh, S.; Farquhar, D.; Klostergaard, J. Antitumor activity of hydrophilic
paclitaxel copolymer prodrug using locoregional delivery in human orthotopic non-small cell lung
cancer xenograft models. Clin. Cancer Res. 2004, 10, 7382-7391.
63. Sabbatini, P.; Aghajanian, C.; Dizon, D.; Anderson, S.; Dupont, J.; Brown, J.V.; Peters, W.A.;
Jacobs, A.; Mehdi, A.; Rivkin, S.; Eisenfeld, A.J.; Spriggs, D. Phase II study of CT-2103 in
patients with recurrent epithelial ovarian, fallopian tube, or primary peritoneal carcinoma. J. Clin.
Oncol. 2004, 22, 4523-4531.
64. Singer, J.W.; Shaffer, S.; Baker, B.; Bernareggi, A.; Stromatt, S.; Nienstedt, D.; Besman, M.
Paclitaxel poliglumex (XYOTAX; CT-2103): an intracellularly targeted taxane. Anti-Cancer
Drugs 2005, 16, 243-254.
65. Nemunaitis, J.; Cunningham, C.; Senzer, N.; Gray, M.; Oldham, F.; Pippen, J.; Mennel, R.;
Eisenfeld, A. Phase I Study of CT-2103, A polymer-conjugated paclitaxel, and carboplatin in
patients with advanced solid tumors. Cancer Invest. 2005, 23, 671-676.
66. Singer, J.W. Paclitaxel poliglumex (XYOTAX, CT-2103): a macromolecular taxane. J.
Controlled Release 2005, 109, 120-126.
67. Chipman, S.D.; Oldham, F.B.; Pezzoni, G.; Singer, J.W. Biological and clinical characterization
of paclitaxel poliglumex (PPX, CT-2103), a macromolecular polymer-drug conjugate. Int. J.
Nanomed. 2006, 1, 375-383.
68. Lee, K.H.; Chung, Y.J.; Kim, Y.C.; Song, S.J. Anti-tumor activity of paclitaxel prodrug
conjugated with polyethylene glycol. Bull. Kor. Chem. Soc. 2005, 26, 1079-1082.

Molecules 2007, 12
375
69. Lee, Y. Preparation and characterization of folic acid linked poly(L-glutamate)nanoparticles for
cancer targeting. Macromol. Res. 2006, 14, 387-393.
70. Dipetrillo, T.; Milas, L.; Evans, D.; Akerman, P.; Ng, T.; Miner, T.; Cruff, D.; Chauhan, B.;
Iannitti, D.; Harrington, D.; Safran, H. Paclitaxel poliglumex (PPX-Xyotax) and concurrent
radiation for esophageal and gastric cancer: a phase I study. Am. J. Clin. Oncol. 2006, 29, 376-
379.
71. Albain, K.S.; Belani, C.P.; Bonomi, P.; O’Byrne, K.J.; Schiller, J.H.; Socinski, M. Pioneer: a
phase III randomized trial of paclitaxel poliglumex versus paclitaxel in chemotherapy-naïve
women with advanced-stage non small-cell lung cancer and performance status of 2. Clin. Lung
Canc. 2006, 7, 417-419.75.
72. Jackson, E.F:; Esparza-Coss, E.; Wen, X.; Ng, C.S.; Daniel, S.L.; Price, R.E.; Rivera, B.;
Charnsangavej, C.; Gelovani, J.G.; Li, C. Magnetic resonance imaging of therapy-induced
necrosis using gadolinium-chelated polyglutamic acids. Int. J. Radiat. Oncol. Biol. Phys. 2007,
68, 830-838.
73. Boddy, A.V. Paclitaxel poliglumex: antimitotic drug oncolytic. Drugs Fut. 2007, 32, 776-780.
74. Bonomi, P. Paclitaxel poliglumex (PPX, CT-2103): macromolecular medicine for advanced non-
small-cell lung cancer. Expert Rev. Anticancer Ther. 2007, 7, 415-422.
75 Papas, S.; Akoumianaki, T.; Kalogiros, C.; Hadjiarapoglou, L.; Theodoropoulos, P.A.; Tsikaris,
V. Synthesis and antitumor activity of peptide-paclitaxel conjugates. J. Pept. Sci. 2007, 13, 662-
671.
76 Kumar, S.K.; Williams, S.A.; Isaacs, J.T.; Denmeade, S.R.; Khan, S.R. Modulating paclitaxel
bioavailability for targeting prostate cancer. Bioorg. Med. Chem. 2007, 15, 4973-4984.
77. Dosio, F.; Brusa, P.; Crosasso, P.; Arpicco, S.; Cattel, L. Preparation, characterization and
properties in vitro and in vivo of a paclitaxel-albumin conjugate. J. Controlled Release 1997, 47,
293-304.
78. Bicamumpaka, C.; Page, M. In vitro cytotoxicity of paclitaxel-transferrin conjugate on H69 cells.
Oncol. Rep. 1998, 5, 1381-1383.
79. Dosio, F.; Arpicco, S.; Brusa, P.; Stella, B.; Cattel, L. Poly(ethylene glycol)-human serum
albumin-paclitaxel conjugates: preparation, characterization and pharmacokinetics. J. Controlled
Release 2001, 76, 107-117.
80. de Groot, F.M.H.; Albrecht, C.; Koekkoek, R.; Beusker, P.H.; Scheeren, H.W. "Cascade-release
dendrimers" liberate all end groups upon a single triggering event in the dendritic core. Angew.
Chem. Int. Edit. Engl. 2003, 42, 4490-4494.
81. Majoros, I.J.; Myc, A.; Thomas, T.; Mehta, C.B.; Baker, J.R., PAMAM dendrimer-based
multifunctional conjugate for cancer therapy: synthesis, characterization, and functionality.
Biomacromolecules 2006, 7, 572-579.
82. Luo, Y.; Prestwich, G.D. Synthesis and selective cytotoxicity of a hyaluronic acid-antitumor
bioconjugate. Bioconj. Chem. 1999, 10, 755-763.
83. Luo, Y.; Ziebell, M.R.; Prestwich, G.D. A Hyaluronic acid-taxol antitumor bioconjugate targeted
to cancer cells. Biomacromol. 2000, 1, 208-218.
84. Marini Bettolo, R.; Migneco, L.M.; De Luca, G. Taxane covalently bounded to hyaluronic acid or
hyaluronic acid derivatives. PCT Int. Appl. Patent No. WO2004035629, 2004.

Molecules 2007, 12
376
85. Capodilupo, A.L.; Crescenzi, V.; Francescangeli, A.; Joudioux, R.; Leonelli, F.; Marini Bettolo,
R.; Migneco, L.M.; Quagliariello, M.; Bellato, P.; De Luca, G.; Galbiati, E.; Renier, D.; Banzato,
A.; Rosato, A. Hydrosoluble, Metabolically Fragile Bioconjugates By Coupling Tetrabutyl-
ammonium Hyaluronan with 2’Paclitaxel-4-Bromobutyrate: Synthesis and Antitumor Properties
In “Hyaluronan 2003” Hyaluronan Structure, Metabolism, Biological Activities, Therapeutic
Applications, Balazs, E.A.; Hascall, V.C., Eds.; Matrix Biology Institute: New Jersey, 2005; Vol.
I, pp. 391-395.
86. Leonelli, F.; La Bella, A.; Francescangeli, A.; Joudioux, R.; Capodilupo, A.-L.; Quagliariello, M.;
Migneco, L.M.; Marini Bettolo, R.; Crescenzi, V.; De Luca G.; Renier, D. A new and simply
available class of hydrosoluble bioconjugates by coupling paclitaxel to hyaluronic acid through a
4-hydroxybutanoic acid derived linker. Helv. Chim. Acta. 2005, 88, 154-159.
87. Thierry, B.; Kujawa, P.; Tkaczyk, C.; Winnik, F.M.; Bilodeau, L.; Tabrizian, M. Delivery
platform for hydrophobic drugs: prodrug approach combined with self assembled multilayers. J.
Am. Chem. Soc. 2005, 127, 1626-1627.
88. Maeda, H.; Seymour, L.W.; Miyamoto, Y. Conjugates of anticancer agents and polymers:
advantages of macromolecular therapeutics in vivo. Bioconjug. Chem. 1992, 3, 351-362.
89. Vincent, M.J.; Duncan, R. Polymer conjugates: nanosized medicines for treating cancer. Trends
Biotechnol. 2006, 24, 39-47.
90. Luo, Y.; Prestwich, G.D. Cancer targeted polymeric drugs. Curr. Cancer Drug Targets 2002, 2,
209-226.
91. Mellado, W.; Magri, N.F.; Kingstone, D.G.I.; Garcia-Arenas, R.; Orr, G.A.; Horwitz, S.B.
Preparation and biological activity of taxol acetates. Biochem. Biophys. Res. Commun. 1984, 124,
329-336.
92. Magri, N.F.; Kingston, D.G.I. Modified taxols, 4. Synthesis and biological activity of taxols
modified in the side chain. J. Nat. Prod. 1988, 51, 298-306.
93. Souto, A.A.; Acuna, A.U.; Andreu, J.M.; Barasoain, I.; Abal, M.; Amat-Guerri, F. New
fluorescent water-soluble taxol derivatives. Angew. Chem. Int. Ed. Engl. 1996, 34, 2710-2712.
94. Rose, W.C.; Clark, J.L.; Lee, F.Y.F.; Casazza, A.M. Preclinical antitumor activity of water-
soluble paclitaxel derivatives. Cancer Chemother. Pharmacol. 1997, 39, 486-492.
95. Harada, N.; Ozaki, K.; Yamaguchi, T.; Hiroaki, A.; Ando, A.; Oda, K.; Nakanishi, N.; Ohashi,
M.; Hashiyama, T.; Tsujihara, K. Synthesis of taxoids II. Synthesis and antitumor activity of
water-soluble taxoids. Heterocycles 1997, 46, 241-258.
96. Rao, C.S.; Chu, J.-J.; Liu, R.S.; Lai, Y.-K.; Synthesis and evaluation of [¹⁴C]-labelled and
fluorescent-tagged paclitaxel derivatives as new biological probes. Bioorg. Med. Chem. 1998, 6,
2193-2204.
97. Bhat, L.; Liu, Y.; Victory, S.F.; Himes, R.H.; Georg, G.I.; Synthesis and evaluation of paclitaxel
C7 derivatives: solution phase synthesis of combinatorial libraries. Bioorg. Med. Chem. Lett.
1998, 8, 3181-3186.
98. Jagtap, P.G.; Baloglu, E.; Barron, D.M.; Bane, S.; Kingston, D.G.I. Design and synthesis of a
combinatorial chemistry library of 7-acyl, 10-acyl, and 7,10-diacyl analogues of paclitaxel
(taxol) using solid phase synthesis. J. Nat. Prod. 2002, 65, 1136-1142.

Molecules 2007, 12
377
99. El Alaoui, A.; Schmidt, F.; Monneret, C.; Florent, J.-C. Protecting groups for glucuronic acid:
application to the synthesis of new paclitaxel (taxol) derivatives. J. Org. Chem. 2006, 71, 9628-
9636.
100. Forrest, M.L.; Yanez, J.A.; Remsberg, C.M.; Ohgami, Y.; Kwon, G.S.; Davies, NM. Paclitaxel
prodrugs with sustained release and high solubility in poly(ethylene glycol)-b-poly(ε-
caprolactone) micelle nanocarriers: pharmacokinetics disposition, tolerability, and cytotoxicity.
Pharm. Res. 2008, 25, 194-206.
101. Pouyani,T.; Prestwich, G.D. Functionalized derivatives of hyaluronic acid oligosaccharides-drug
carriers and novel biomaterials. Bioconj. Chem. 1994, 5, 339-347.
102. Pouyani,T.; Harbison, G.S.; Prestwich, G.D. Novel hydrogels of hyaluronic acid: synthesis,
surface morphology, and solid state NMR. J. Am. Chem. Soc. 1994, 116, 7515-7522.
103. Vercruysse, K.P.; Marecak, D.M.; Marecek, J.F.; Prestwich, G.D. Synthesis and in vitro
degradation of new polyvalent hydrazide cross-linked hydrogels of hyaluronic acid. Bioconjug.
Chem. 1997, 8, 686-694.
104. Klostergaard and co-workers [105] prepared bioconjugate 3 basically according to Prestwich and
co-workers method [82-83], but using pH 8.5 in final coupling, which gives a better yield.
105. Auzenne, E.; Ghosh, S.C.; Khodadadian, M.; Rivera, B.; Farquhar, D.; Price, R.E.; Ravoori, M.;
Kundra, V.; Freedman, R.S.; Klostergaard, J. Hyaluronic acid-paclitaxel: antitumor efficacy
against CD44(+) human ovarian carcinoma xenografts. Neoplasia 2007, 9, 479-486.
106. Rosato, A.; Banzato, A.; De Luca, G.; Renier, D.; Bettella, F.; Pagano, C.; Esposito, G.;
Zanovello, P.; Bassi, P. HYTAD1-p20: A new paclitaxel-hyaluronic acid hydrosoluble
bioconjugate for treatment of superficial bladder cancer. Urol. Oncol.-Semin. Ori. 2006, 24, 207-
215.
107. Meléndez-Alafort, L.; Riondato, M.; Nadali, A.; Banzato, A.; Camporese, D.; Boccaccio, P.;
Uzunov, N.; Rosato, A.; Mazzi, U. Bioavailability of ^99mTc-Ha-paclitaxel complex [^99mTc-
ONCOFID-P] in mice using four different administration routes. J. Labelled Compd.
Radiopharm. 2006, 49, 939-950.
108. Sukhishvili, S.A. Layered, erasable polymer multilayers formed by hydrogen-bonded sequential
self-assembly. Macromolecules 2002, 35, 301-310.
109. Chung, A.J.; Rubner, M.F. Methods of loading and releasing low molecular weight cationic
molecules in weak polyelecrolyte multilayer films. Langmuir 2002, 18, 1176-1183.
110. Vázquez, E.; Dewitt, D.M.; Hammond, P.T.; Lynn, D.M. Construction of hydrolytically-
degradable thin films via layer-by-layer deposition of degradable polyelectrolytes. J. Am. Chem.
Soc. 2002, 124, 13992-13993.
111. Hiller, J.; Rubner, M.F. Reversible molecular memory and pH-switchable swelling transitions in
polyelectrolyte multilayers. Macromolecules 2003, 36, 4078-4083.
112. Shchukin, D.G.; Patel, A.A.; Sukhorukov, G.B.; Lvov, Y.M. Nanoassembly of biodegradable
microcapsules for DNA encasing. J. Am. Chem. Soc. 2004, 126, 3374-3375.
113. Peyratout, C.S.; Dähne, L. Tailor-made polyelectrolyte microcapsules: from multilayers to smart
containers. Angew. Chem. Int. Ed. 2004, 43, 3762-3783.

Molecules 2007, 12
378
114. Jackson, J.K.; Skinner, K.C.; Burgess, L.; Sun, T.; Hunter, W.L.; Burt, H.M. Paclitaxel-loaded
crosslinked hyaluronic acid films for the prevention of postsurgical adhesions. Pharm. Res. 2002,
19, 411-417.
115. Yin, D.; Ge, Z.; Yang, W.; Liu, C.; Yuan, Y. Inhibition of tumor metastasis in vivo by
combination of paclitaxel and hyaluronic acid. Cancer Lett. 2006, 243, 71-79.
116. Tezcaner, A.; Hicks, D.; Boulmedais, F.; Sahel, J.; Schaaf, P.; Voegel, J.-C.; Lavalle P.
Polyelectrolyte multilayer films as substrates for photoreceptor cells. Biomacromolecules 2006,
7, 86-94.
117. Vodouhê, C.; Schmittbuhl, M; Boulmedais, F.; Bagnard, D.; Vautier, D.; Schaaf, P.; Egles, C.;
Voegel, J.-C.; Ogier, J. Effect of functionalization of multilayered polyelectrolyte films on
motoneuron growth. Biomaterials 2005, 26, 545–554.
118. Jessel, N.; Atalar, F.; Lavalle, P.; Mutterer, J.; Decher, G.; Schaaf, P.; Voegel, J.-C.; Ogier, J.
Bioactive coatings based on polyelectrolyte multilayer architecture functionalized by embedded
proteins. Adv. Mater. 2003, 15, 692-695.
119. Chluba, J.; Voegel, J.-C.; Decher, G.; Erbacher, P.; Schaaf, P.; Ogier, J. Peptide hormone
covalently bound to polyelectrolytes and embedded into multilayer architectures conserving full
biological activity. Biomacromolecules 2001, 2, 800-805.
120. Caruso, F.; Schüler, C. Enzyme multilayers on colloid particles: assembly, stability, and
enzymatic activity. Langmuir 2000, 16, 9595-9603.
121. Caruso, F.; Niikura, K.; Furlong, D.N.; Okahata Y. Assembly of alternating polyelectrolyte and
protein multilayer films for immunosensing. Langmuir 1997, 13, 3427-3433.
122. Vodouhê, C.; Le Guen, E.; Garza, J.M.; Francius, G.; Déjugnat, C.; Ogier, J.; Schaaf, P.; Voegel,
J.-C.; Lavalle, P. Control of drug accessibility on functional polyelectrolyte multilayer films.
Biomaterials 2006, 27, 4149-4156.
123. Kidambi, S.; Lee, I.; Chan, C. Controlling primary hepatocyte adhesion and spreading on
protein-free polyelectrolyte multilayer films. J. Am. Chem. Soc. 2004, 126, 16286-16287.
© 2008 by MDPI (http://www.mdpi.org). Reproduction is permitted for noncommercial purposes.