The formulation of optimized compos

The formulation of optimized composition, chosen inside the
area evidenced in Fig. 10, was: CS 1.15% w/w  CaCl2 0.75% w/w/
PEC 0.64% w/w  HA 0.5% w/w.
The optimized formulation was subjected to the same
characterization previously effected on the design formulations.
The experimental results obtained were the following (mean
values  s.d.; n = 3): particle size = 1849 109mm, PBS amount
absorbed by unit weight = 12  2 g/g, penetration area normalized
by capsule volume = 63  2 mN/mm2
. Since such results lie inside
the confidence interval of the relevant values predicted by the
model, the model is predictive.
3.3. Characterization of Fr1-loaded mini-capsules
Fr1 loading into mini-capsules did not produce any statistically
significant changes in particle size, hydration and mechanical
properties with respect to unloaded mini-capsules. The experimental
results (mean values  s.d.; n = 3) obtained for the loaded
mini-capsules were: particle size = 1996  72mm, PBS amount
absorbed by unit weight = 14  3 g/g, penetration area normalized
by mini-capsule volume = 61 2 mN/mm2
. Mini-capsules were
characterized by %Fr1 values equal to the theoretical one
(100  3.3%). No significantly different results were obtained when
Fig. 8. Contour plots (in bi- and tri- dimensional projections) drawn according to quadratic model for the response variable amount of PBS absorbed/unit weight (g/g) of the
“central composite design”.
Fig. 9. Contour plots (in bi- and tri- dimensional projections) drawn according to quadratic model for the response variable penetration area normalized respect the volume
of formulation (mN/mm2
) of “central composite design”.
274 M. Tenci et al. / International Journal of Pharmaceutics 516 (2017) 266–277
particles were tested after 15 days storage at ambient temperature
in hermetically sealed containers.
3.3.1. Cell proliferation properties
In Fig. 11 % fibroblasts proliferation values after treatment with
Fr1-loaded mini-capsules and unloaded mini-capsules are shown.
It can be observed thatloaded mini-capsules were characterized by
% proliferation values significantly higher than the reference
medium (M w/s) and unloaded formulations. These results
indicate that loaded mini-capsules were able to enhance human
fibroblast proliferation. Such an effect is attributable to the activity
of Fr1 that is released from hydrated mini-capsules.
3.3.2. Antibacterial activity
As for Fr1, even at the maximum concentration tested (50 mg/
ml), microbial growth was observed for all the clinical isolates
(MICs >50 mg/ml). CS solutions with and without Fr1 showed
antibacterial activity against all the tested S. aureus (MIC range
0.09–0.39 mgml and MIC range 0.09–0.78, respectively) and S.
pyogenes (MIC range 0.09–0.39 mgml and MIC range 0.09–0.78,
respectively).
MIC mode for each group of microorganisms tested are reported
in Table 5.
All the clinical isolates species exhibit equal values of MIC mode
for the two solutions (with and without Fr1) that was 0.19 mg/ml.
This result is indeed justified by the fact that CS is a polymer
characterized by well-known antimicrobial properties (Muzzarelli
et al., 2015; Rossi et al., 2010; Zheng and Zhu, 2003). Furthermore,
no significant differences were observed between S. aureus
carrying well-known mechanism of resistance and susceptible
ones.
3.3.3. In vivo efficacy on a rat wound model
3.3.3.1. In vivo rat wound model. The wounds consisted of a fullthickness
injury affecting either epidermis and dermis but leaving
intact the underlying muscular structures. At the beginning of the
experiments (t0), the mean area of one lesion was
21.83  0.59 mm2 (n = 18), for a total mean injured area (3
lesions for each animal) of 65.50  2.21 mm2 (n = 6), accounting
for less than 2% of the total body area of each animal. 18 days after
treatment a wound recovery equal to 77.8  2.8% (n = 6),
54.0  8.2% (n = 6) and 46.6  6.7% (n = 6) was observed for Fr1-
loaded mini-capsules, unloaded mini-capsules and saline solution,
respectively. No significant differences were found between the
wound recovery of unloaded formulation and saline solution,
while a significant (p < 0.05) improvement in wound recovery was
detected for Fr1-loaded formulation, with respect to saline
solution. It must be pointed out that all the three lesions, not
only the control one, were wetted with saline solution to mimic the
in vivo conditions. As already mentioned, it is reported in the
literature that the exudate excess present in chronic ulcers could
delay healing process (Boateng et al., 2008). Recently Ousey et al.
(2016) suggested that an appropriate moist environment actively
supports the healing process, confirming previously published
data in a full-thickness porcine wound model (Svensjö et al., 2000).
The time course of the wound healing process is reported in
Fig. 12. It must be underlined that the values 116% and 109%,
obs