Smart Films Produced by Electrospinning of Poly(butylene-adipate-co -terephthalate)/poly-( ε -caprolactone) for Controlled Delivery of Ibuprofen

Wound dressing devices composed of microfibers of poly(butylene-adipate-co -terephthalate) and poly-( ε -caprolactone) incorporated with ibuprofen were obtained by electrospinning technique. The effect of ibuprofen concentration (0, 10, and 20% m m -1 ) on morphology, spectroscopic, and thermal characterization was evaluated. The fibers containing ibuprofen presented beads and revealed no uniformity. The spectroscopic analysis showed signals that reveal the ibuprofen incorporation on fibers. At the same time, X-ray diffraction spectroscopy indicated a difference in the fiber crystallinity depending on drug concentration, where a lower crystallinity was verified by the film containing a greater concentration incorporated. Rheological measurements revealed that films were more plastic in greater ibuprofen incorporation. Contact angle characterization revealed that ibuprofen solubilization on composite surfaces increased the film wettability. Finally, the fibers promoted the controlled release of ibuprofen, promoting morphological changes in polymeric matrices. The material developed can be used in future biomedical applications.


Introduction
Ibuprofen (IBU, [(RS)-2-(4-(2-methyl propyl)phenyl) propanoic acid) is a known anti-inflammatory drug non-steroidal used against fever, pain, and symptoms of rheumatoid, arthritis, and osteoarthritis. 1,2Besides its broad uses, its low solubility (49 μg mL -1 at 25 ºC), rapid clearance after oral administration, and short half-life (2 h) are the main drawbacks associated with this molecule. 1,2IBU also presents poor skin permeability, making its transdermal application more difficult. 1This requires high and multiple dosages in patients, generating several side effects, such as bleeding and ulceration. 1,2Researchers have been developing transdermal and topical formulations of IBU to overcome these drawbacks, increase therapeutic efficacy, and improve patient adherence.Several drug delivery systems have been used to solubilize and promote the controlled drug delivery of IBU, such as β-cyclodextrin, lipid carriers, hydrogels, microemulsions, surfactants, mesoporous silica, etc. [1][2][3] Notably, IBU has been incorporated in formulations containing skin penetration enhancers for transdermal controlled release, such as ethanol 70%.However, these systems promote skin irritation and lead to quick evaporation, limiting their use. 1 It is increasing the studies involving the obtention of microfibers as drug carriers, mainly due to their better patient compliance, higher encapsulation efficiency, reduced heterogeneity of therapeutic concentration of the drug in the carrier, etc. 4 Electrospinning is one of the most used methods to produce fibers with diameters varying from micro to nanometers. 5 These fibers can be used in biomedical applications, such as wound healing, tissue engineering scaffolds, enzyme immobilization, and drug delivery systems. 6,7Generally, the fibers obtained by electrospun present a high surface area, allowing the in situ incorporation of bioactive agents alongside variable porosity and morphologies similar to extracellular matrix structure (ECM). 5,8Poly(butylene-adipate-coterephthalate) (PBAT) is a polyester derived from fossil sources that presents interesting properties for biomedical materials, such as biodegradability, toughness, and high flexibility. 8Additionally, it offers high processability, high elongation at break, and mechanical properties similar to a thermoplastic elastomer.It is a bioplastic candidate to replace synthetic polymers in several applications, such as packaging, agricultural, and biomedical. 4,9However, it is also worth mentioning that the low elastic modulus PBAT, as well as its poor oxygen barrier properties, is a disadvantage for using only this polymer in the materials. 10olycaprolactone (PCL) is a polymer approved by Food and Drug Administration (FDA) that has been extensively used in bone regeneration, as well as to obtain materials for tissue engineering purposes due to its mechanical elasticity and low autoimmune response. 11However, the main disadvantage of the PCL is its surface hydrophobicity, which exerts a direct influence on cell attachment and proliferation. 12In this way, our research group has combined PBAT with PCL to obtain materials with better performance for biomedical applications. 9izvi and D'Souza 13 reported the electrospinning of PBAT/PCL for use in drug delivery systems.The authors believe in the potential of the union of these polymers due to their biodegradable and biocompatible characteristics.Aiming for a more advanced application, the electrospinning of PBAT/PCL together with propolis for dressings has already been reported by Zanella et al. 14 with satisfactory results for antimicrobial activity.Recently, we studied the synthesis and characterization of a wound dressing device composed of monoaxial electrospun PBAT/PCL-based microfibers incorporated with silver sulfadiazine (SS). 4ibers presented diameters varying from 3.113 (without PCL) to 0.591 μm (10% of PCL m m -1 ). 4 Thermal stability studies revealed that SS incorporation presented a low influence over the degradation temperature of fibers.SS increased the fiber's crystallinity, and the final material was effective against Gram-negative and Gram-positive bacteria (Escherichia coli and Staphylococcus aureus, respectively). 4Finally, this article incorporated IBU, a drug with different polarity degree, and subsequent characterization of the PBAT/PCL/IBU fibers.The main difference of the present study is that IBU is soluble in the same solvents used to obtain fibers (chloroform), while SS is not.The fiber's main characteristics were compared with the previous article. 4

Polymeric solution preparation
The preparation of the polymeric solution at 20% (m v -1 ) occurred by using PCL 25% (m m -1 ) and PBAT 75% (m m -1 ) to obtain 5.0 mL of the final solution.It involves using 0.75 and 0.25 g of PBAT and PCL, respectively.According to a previous study, 4 this proportion of polymers results in thin and homogeneous fibers.The solvent quantities were added in the following steps to obtain 85 and 15% (v v -1 ) of chloroform (Chl) and dimethylformamide (DMF), respectively.The solution was magnetically stirred for 24 h.DMF presents a higher dielectric constant than chloroform at 25.0 ºC, favoring electrospinning. 15

Ibuprofen incorporation
The working concentration chosen for IBU was 20 and 30% in relation to the mass of the PBAT/PCL blend, being designated PBAT/PCL-20 and PBAT/PCL-30, respectively.For incorporation, IBU was added to the PBAT/PCL solution and stirred until complete dissolution.Afterward, 5.0 mL of the final solution was transferred to a graduated glass syringe (10.0 mL) containing a needle (internal diameter of 0.7 mm) and put in an infusion pump system.The negative pole is connected to the target collector and an alternating cable.The positive pole is positioned to the needle.We used the following electrospinning conditions for the systems containing or not IBU: needle-to-connector distance of 12 cm, a potential voltage applied of 15 kV, flow rate of 1.0 mL h -1 , temperature of 23.5 ± 1.5 ºC, and relative air humidity of 50 (± 5)%.

Solution characterization
Relative viscosity (ɳ rel ) was measured using an Ubbelohde capillary viscometer (MyLabor, No. 300, São Paulo, Brazil).Measurements were carried out with a viscometer immersed in a water bath at 23 ± 2 °C.The solutions were glued to the viscometer and left to rest until they reached the bath temperature.Flow times were performed in triplicate for each sample.
The conductivity of the solutions was evaluated using an MS TECNOPON conductivity meter (model mCE-105, Piracicaba, Brazil) with a measurement range of 0 to 200 mS cm -1 , cell constant (K) of 1 ± 0.2, resolution of 0.1 µS cm -1 , and electrode area of 140 mm × (Ø) 10 mm.The temperature of the measurement solutions was 25 ± 3 °C.The assay was performed in triplicate.

Membranes characterization
The fiber morphology was evaluated by scanning electron microscopy (SEM) using a microscope model VEGA3 TESCAN (Kohoutovice, Czech Republic).Briefly, the samples were fixed in the support through a carbon adhesive tape and gold metalized through a Denton Vacuum (Desk V) metallizer (Moorestown, USA) (thickness of 5 nm).The analysis was performed at 20 kV.
The fiber's wettability was evaluated using the sessile drop method.The samples were placed in a metal plate, where distilled water (ca.7 μL) was deposited into the fibers.The contact angle was measured through analysis of the images through the software AmScope 3.7 (Irvine, USA).
The IBU incorporation was evaluated by Fourier transformed infrared spectroscopy (FTIR) using the attenuated total reflectance (ATR) module.These analyses were performed using a PerkinElmer FTIR Spectrometer (Waltham, USA).The measures were performed in the wavelength range from 4000 to 650 cm -1 at 25 ºC, using eight scans (resolution of 1 cm -1 ).
The X-ray diffraction was used to evaluate the crystallinity change after IBU incorporation in fibers.A Bruker TM Diffractometer (Billerica, USA) realized this analysis at a diffraction angle (2θ) ranging from 4 to 60 o (resolution of 0.01).A radiation source of Cu Kα (λ = 1.5406Å) and a graphite monochromator were used in the analysis.
Differential scanning calorimetry (DSC) and thermogravimetric analysis were used to characterize the thermal behavior of the fibers without and containing IBU.In DSC analysis, the samples (5.940 ± 0.6200 mg) were placed in closed aluminum crucibles under a nitrogen atmosphere (flow rate of 50 mL min -1 ).The samples were heated and cooled from 25 to 200 ºC (at 10 ºC min -1 ).The crystallinity percentage (x c ) of the fibers was obtained using equation 1: (1)   where ΔH m and are the melting and theoretical melting enthalpies, respectively.
is defined as the enthalpy of a sample 100% crystalline (114 and 139 J g -1 for PBAT and PCL, respectively). 4Thermogravimetric analyses were obtained to evaluate the degradation temperature of fiber containing or no IBU.Thermograms were obtained by a PerkinElmer STA 6000 Thermal Analyzer (Waltham, USA).The samples (average mass around 7.291 ± 1.339 mg) were put in porcelain crucibles using the same conditions discussed in DSC.
Mechanical tensile-strength analyses were obtained for the films.For this, the stress-strain curves were obtained, following the ASTM-D882-12 16 technical standard, using a texturometer TA HD Plus (Stable Micro Systems) with 5 kg of the load cell (Vienna Court, UK).The analysis was performed in triplicate until the films were utterly broken, with a traction ratio of 1 mm s -1 and 10 mm.

Release kinetics
The IBU release kinetics were obtained in 100.0 mL of phosphate buffer (pH 7.4) at 0.10 mol L -1 and 37.0 ºC.This media simulates the pH and temperature of the skin.First, an analytic curve for different IBU concentrations was obtained by SHIMADZU UV-Vis spectrophotometer, UV-1800 (Kyoto, Japan) at 264 nm.The IBU release studies from fibers were used in a controlled bath shaker Newlab NL-343-01 (Piracicaba, Brazil) at 100 rpm and controlled temperature (37 ± 2 ºC).The amount of IBU released was evaluated by UV-Vis using solutions aliquots (2.0 mL) in different time intervals.In each time interval, the same medium quantity was replaced in the systems to maintain a constant volume.
The initial IBU concentration incorporated in fibers was evaluated using an analytical curve in ethanol.For this, 10.0 mg of IBU films were solubilized in 5.0 mL of ethanol for 2 h, and the amount of IBU incorporated was evaluated through the absorbance at 264 nm.
The release curves were fitted using different release models, such as zero and first orders, Higushi, Korsmeyer-Peppas, Hixson-Crowell, Hopfenberg, Baker-Lonsdale, Peppas-Sahlin, Quadratic, Weibull, Gompertz, and Probit.These models predict the mechanism of the IBU release from fibers.The fitting was obtained using DDSolver software using a non-linear optimization method. 17Finally, we used the correlation coefficient (R 2 ) and the Akaine Information Criterion (AIC) to evaluate the best-fitting model. 18,19he same characterizations performed by PBAT/PCL/IBU films were also carried out for the samples after the IBU release reached equilibrium.In this way, films after 1500 min in contact with phosphate buffer solution (PBS) were dried and performed to the measurements.

Solution characterization
The PBAT/PCL solution (Table 1) has a conductivity very close to the binary mixture Chl/DMF (1.206 ± 0.004 µs cm -1 ), indicating a neutral characteristic of the polymers in the solution.The addition of IBU causes a decrease in the conductivity of the solution with increasing concentration, resulting from the presence of IBU in anionic form.In solution, IBU can have a neutral or anionic form depending on the pH of the medium. 20Sequeira et al. 21also observed a reduction in conductivity with the addition of IBU to poly(vinyl alcohol)/lysine solution for electrospinning.
Table 1 also shows the relative viscosities of the studied solutions.The relative viscosity of the PBAT/PCL blend is reduced with the addition of IBU and can be eliminated by the interaction of the polymer-IBU.Khan et al. 22 reported that IBU has an intermediate interaction with neutral polymers that can cause changes in the solution.Furthermore, IBU is a known drug with a plasticizing characteristic that causes a decrease in viscosity. 23neral characterization of PBAT/PCL/IBU films First, PBAT/PCL fibers were uniform and continuous, without bead formation (Figures 1a and 1d).SEM images reveal that IBU incorporation significantly changes the morphology of the fibers.SEM images (Figures 1b, 1c and  1f) show beads' formation without presenting uniformity.The reduction in viscosity by approximately 30%, shown in Table 1, may explain the significant formation of beads.The formation of beads is related, among other factors, to the solution viscosity parameter.The reduction in the viscosity of a solution leads to the formation of beads or electrospraying. 24For PBAT/PCL/IBU-30, it is impossible to observe any fibers formed.This fact can be explained by the reduction in the conductivity of the solution presented in Table 1.Conductivity can influence the formation of smooth fibers due to the density of charges present in the solution that interfere with the stability of the formed jet.   Figure 2 presents the FTIR spectra of the films studied.The IBU FTIR spectra reveal the presence of the following bands: 2924 (hydrogen atoms axial deformation at primary carbon-CH 3 ), 1419, and 1321 (axial deformation of C-O of the carboxylic acid group), 936 (angular deformation out of the plane of C=O binding), and 779 cm -1 (angular deformation of hydrogens of the para-substituted aromatic ring). 25All these vibrational modes are found in the FTIR spectra of PBAT/PCL/IBU films, which indicates the IBU incorporation in the polymeric matrices.Finally, the broadband at the wavelength ranges from 2900 to 3400 cm -1 present only in the IBU FTIR spectra due to the carboxylic acid present in this drug.The band at 1269 cm -1 is also observed in the FTIR spectra of the pure polymers and the films containing IBU.However, in the last, an increase in intensity is observed due to the overlap of ester C-O bands of PBAT with C-O carboxylic acid of IBU.
Mechanical analyses were performed to investigate this possibility better (Figure 3).
The tensile strength curves reveal that the films containing 30% (m m -1 ) of IBU presented higher tensile strength, indicating a behavior of less plastic for this sample (Figure 3).The tensile strength of films was 1.60, 0.08, and 0.49 MPa for the samples PBAT/PCL, PBAT/PCL/IBU-20 IBU, and PBAT/PCL/IBU-30, respectively.These results also indicate a higher crystallinity for the lower IBU concentration film.Finally, it is necessary to mention that IBU incorporated the lowest strength of the films.The characteristic of IBU can explain this to act as a plasticizer. 26Plasticizers can disrupt the polymeric network and, consequently, reduce tensile strength due to the greater flexibility of the material. 27IBU incorporation decreases the intermolecular polymeric chain interactions between PBAT and PCL. 28However, it is necessary to mention that the mechanical behavior presented here did not compromise using PBAT/PCL/IBU films for biomedical purposes. 28in et al. 28 discussed that materials with higher crystallinity offer high elastic moduli and resistance to tensile force.It directly compromises the ductility of the fiber for transdermal application, harming its use. 28However, our electrospun matrices presented tensile strength values in accordance with materials which has been applied to wound healing in vivo study. 28-ray diffraction analysis was performed to investigate better the crystallinity behavior of the films (Figure 4).The peak characteristics for the films containing IBU were in 2θ angles of 12.4, 16.7, 20.3, and 22.5 o .These peaks are present in IBU, as previously reported by Yu et al. 29 The peak 2θ located at 17.5 o presented in the diffractogram of PBAT and PCL is attributed to PBAT, as Monteiro et al. 30 previously verified.For PBAT/PCL/IBU-20, a crystalline pattern is observed due to the presence of peaks corresponding to PCL and IBU.For PBAT/PCL/IBU-30, on the other hand, the presence of broad and diffuse maxima observes an amorphization of IBU and PCL.Panda et al. 31 also observed the amorphization of IBU in an electrospun polyvinylpyrrolidone (PVP) system and highlighted this as a favorable point for better solubility of the drug.Celebioglu and Uyar 32 also observed the formation of entirely amorphous IBU in hydroxypropyl-betacyclodextrin membranes with increasing IBU concentration.
DSC analysis was used to evaluate the possibility of changes in the crystallinity of the ibuprofen films (Figure 5).All values of temperatures and heat (melting and crystallization) obtained by TA-50WS are presented in Table 2.The DSC curves show that endothermic peak 1 is related to PCL and the aliphatic monomer of PBAT. 14 Endothermic peak 2, present in PBAT/PCL/IBU-30, refers to the crystalline phase of β-form crystals of butylene adipate (BA) present in PBAT. 33The appearance of peak 2 indicates that IBU acts as an agent that causes a fusionrefusion mechanism, causing a β-to-α transition of the BA segment to occur. 34Finally, exothermic peak 3 is related to the aromatic monomer of PBAT melting, 14 while peak 4 is related to polymer recrystallization. 35irst, it is observed that the incorporation and IBU concentration in PBAT/PCL films changes its T melting and ΔH melting for peak 1, mainly for 20% of IBU.For example, the incorporation of 20% of IBU increases the ΔH melting about 15.4 J g -1 (from 21.6 to 37.0 J g -1 , respectively).It strongly indicates a greater polymeric organization (a higher crystallinity) under this condition.Additionally, the absence of the melting peak of IBU (peak 2) was observed in this film, indicating the overlap between the melting peak of IBU and PCL polymer. 36he event related to the PBAT monomer peak (peak 3) shows a considerable difference in the comparison between PBAT/PCL and PBAT/PCL/IBU films for both IBU concentrations.This decrease in the melting temperature with the IBU incorporation indicates the interaction between the drug and PBAT. 37The polymer recrystallization peak (peak 4) temperatures vary from 71 to 76 ºC.The observation of the ΔH recrystalization reveals a lower value to the greater IBU concentration (30% m m -1 ), indicating less crystallization in this condition.This can be confirmed by the analysis of the crystallinity degree for films, calculated using equation 1 (Table 3).
The results in Table 3 reveal that increasing the IBU concentration from 20 to 30% (m m -1 ) makes the film more plastic.These data agree with mechanical analyses that demonstrate the plasticizing characteristic of IBU.Furthermore, the reduction in crystallinity of the peak corroborates the XRD data that show the amorphization   of the polymer and drug groups.Furthermore, when comparing the PCL (peak 1) and PBAT (peak 3) peaks, the more pronounced reduction in crystallinity for PBAT indicates a more significant interaction of IBU with this polymer.This fact also explains the greater crystallinity for PCL when compared to PBAT with the addition of IBU.The interaction of IBU with PBAT provides greater chain mobility for PCL 23 and, consequently, increases the volumetric amount of organized lamellas.The analysis of degradation temperature is essential in developing a formulation for transdermal purposes.For example, it is necessary to evaluate if the sample suffers any thermal degradation in the skin temperature. 38This can lead to premature drug delivery, compromising the matrice for this application.Figure 6 presents the thermogravimetric curves obtained by TGA analysis for the films.
First, IBU presents a total degradation in the temperature range from 150 to 240 ºC.The PBAT/PCL films show two stages of mass loss.The first is around 359 ºC (7.0% of loss mass), and the second is at 408 ºC (93% of loss change).This result is similar to results obtained by other researchers.It is related to the dehydration of hydroxyl groups of PLA and carboxylic groups of PBAT, the cleavage of ester linkage by hydrolysis, and C-O and C-C binding scission. 39,40The thermograms of PBAT/PCL/IBU presented different degradation temperature ranges.The film PBAT/PCL/IBU-20 showed a degradation range from 152 to 306 ºC, while for the film with higher IBU concentration, the final degradation temperature was 290 ºC.
These results corroborate the previous crystallinity degree studies, which revealed that PBAT/PCL/IBU-20 presents higher crystallinity (Table 3).It generates more significant intermolecular interactions between the polymeric chain, producing higher energy to promote film degradation.Finally, the results reveal that PBAT/PCL/IBU films presented thermal stability for biomedical purposes. 41he results presented here are similar to those obtained by us with the addition of silver sulfadiazine. 4An increase in the crystallinity of PBAT/PCL films upon incorporation of the drug was observed.The results from this previous work and our current article show that regardless of the degree of drug polarity, there is an increase in polymer chain organization following the drug incorporation process.
Contact angle measurements were performed to evaluate the temporal wettability of the films containing or without IBU incorporated (Figure 7).It is known that low contact angles (< 90 o ) are related to the excellent wettability  (more hydrophilic behavior) of the films. 42Table 4 presents the contact angle values for the images obtained in Figure 7.
It is necessary to mention that PBAT/PCL/IBU films presented lower contact angles than PBAT/PCL samples.This is an indication that IBU incorporation increases the hydrophilicity of the films.The films without IBU present hydrophobic behavior.The hydrophilicity is more pronounced by the film containing the lower IBU concentration (PBAT/PCL 20% (m m -1 ) IBU).These data are in accordance with the mechanical analysis performed, probably indicating different localization of IBU in the films.For the film containing higher IBU concentration, part of the IBU molecules can be grafted into the PBAT/PCL chains, acting as a plasticizer.On the other hand, in the PBAT/PCL/IBU-20, the drug is located more externally, promoting increased wettability.
Figure 8 presents the percentage of IBU released versus time in PBS (pH 7.4) media.
First, the saturation in the liberation occurred in 840 min for both films studied.The saturation in the release curves occurred with the release of 64 and 58% of IBU for PBAT/ PCL/IBU-20 and PBAT/PCL/IBU-30, respectively.The bead's film homogeneity in size verified in SEM analysis (Figure 1) for IBU concentrations justifies the continuum release until the maximum drug release is reached.However, it is demonstrated that a slower release of IBU for the film containing the higher IBU concentration (30% m m -1 ).These results corroborate the assessment that in this film, a proportion of IBU is more internalized, making it more difficult for IBU to release.
The fitting of the experimental data according to several mathematic models of drug dissolution revealed the mechanism involved in the IBU release.The fitting graphs are present in the Supplementary Information (SI) section (Figure S1).
Table 5 presents the mathematical models used for the fitting.
The better model, according to the correlation coefficient values closest to one (R 2 = 1.0000), lower AIC, and greater models selection criterion (MSC), was Gompertz, independently of the IBU concentration in the films (Table 6).
Gompertz is applied with drug release profiles with great solubility and intermediary release rate. 53This model describes a sharp increase during the onset of release and slowly converges to the asymptotic maximum release.Equation 13 presents the factors α and β, where the first is a parameter related to the non-dissolved drug proportion at a time equal to 1. 54 The β parameter describes the shape and dissolution rate.These values were α = 78.74 and β = 1.71 for PBAT/PCL/IBU-20 and α = 58.26,β = 1.48 for PBAT/PCL/IBU-30.The lower values obtained for the film with greater IBU concentration are according to the previously reported results, which showed a greater internalization of IBU in this film. 54BAT/PCL films incorporated with the hydrophobic drug silver sulfadiazine presented a different release mechanism.In these films, there are two steps in the release.The first was related to a non-Fickian mechanism (0.75 < n < 1) and a Fickian mechanism in the second (0.35 < n < 0.75). 4The first step is related to a polymeric relaxation rate, followed by the second, where the dissolution of the drug in the dissolution medium was determinant.These results reveal that drug polarity degree is an essential factor in the release process from PBAT/PCL films. 4BAT/PCL/IBU films were characterized after the IBU-controlled release process by SEM images (Figure 9).The micrographs reveal the presence of a cluster around the beads, which disappeared after the release process.These clusters are probably the IBU molecules, which are the majority on the surface of films, leading to a faster release, as previously reported in this article.
FTIR (Figure S2, SI section) and TGA results (Figure S3, SI section) revealed that IBU was released from the fibers.The IR spectroscopy results showed a decrease or disappearance of prominent IBU bands in the films.For example, the band at 779 cm -1 related to the angular deformation of the hydrogen bond linked to the para-substituted aromatic ring of IBU disappeared after the release process (Figure S2).At the same time, the thermograms revealed a reduction in the intensity of mass change in the temperatures of IBU degradation (Figure S3).
After the IBU release process, the films showed thermal performance observed to understand more about possible morphological and structural changes in the polymer matrices (Figure 10).Table 7 presents the melting and recrystallization heat temperatures of PBAT/PCL/IBU films after release.
Comparison between the ΔH m of samples containing IBU before (Table 2) and after the release process (Table 7) reveals a significant difference between both data.These data can indicate changes in the polymeric chain organization after the IBU release.This statement can be proved by crystallinity degree values obtained by the samples after IBU release (Table 8).
Table 8, when compared to Table 2, reveals an increase in the crystallinity of the films after the release of IBU.The significant increase in crystallinity, especially for PBAT, can be explained by the release of IBU.The release of IBU provides more freedom for the chains to diffuse into the already-formed lamellae, increasing their size and thus increasing the crystallinity of the sample.
Finally, the present article reveals the applicability of using PBAT/PCL films for the controlled release of the hydrophilic anti-inflammatory drug IBU.As previously mentioned, other articles of our research group also demonstrated the possibility of incorporating a hydrophobic antimicrobial agent, silver sulfonamide, in the same materials. 4In this way, our future perspectives involve the association of IBU and silver sulfonamide in the same material to achieve a synergetic effect of anti-pathogenic and anti-inflammatory material for wound dressing.The final material would be more efficient in the treatment of several wounds.Several research groups have demonstrated the efficiency of hybrid materials of this nature.For example, recently, Alizadeh et al. 55 revealed the higher wound dressing potential nanofibers constituted of the antimicrobial polysaccharide chitosan with poly(vinyl alcohol) for the controlled release of antibiotics. 55The final material presented superior protection and antibacterial effect than the isolated starting materials. 55

Conclusions
The electrospinning technique was used to develop fibers of PCL and PBAT incorporating the anti-inflammatory drug IBU.We performed the obtention of fibers with different IBU concentrations (0, 20, and 30% m m -1 ).Our results revealed that PBAT/PCL films presented different morphology and mechanical behavior after IBU incorporation.For example, fibers without IBU were continuous and uniform, while IBU caused bead formation.The mechanical analysis reveals that IBU incorporation decreased the tensile strength.The results also revealed a greater crystallinity (higher chain organization) for the films containing the lower IBU concentration (20%).Thermal  analysis revealed that PBAT/PCL/IBU films presented thermal stability.Contact angle measurements showed that IBU incorporation increased the films' hydrophilicity, and IBU is probably located more externally on fibers in PBAT/PCL 20% films.Controlled release studies indicated that IBU release from fibers obeys the Gompertz model and a polymeric reorganization after the drug release.All the results make it possible to use PBAT/PCL/IBU films for wound dressing.

Figure 1
Figure 1 presents the SEM images of PBAT/PCL with, and without IBU incorporation.First, PBAT/PCL fibers were uniform and continuous, without bead formation (Figures1a and 1d).SEM images reveal that IBU incorporation significantly changes the morphology of the fibers.SEM images (Figures1b, 1c and 1f) show beads' formation without presenting uniformity.The reduction in viscosity by approximately 30%, shown in Table1, may explain the significant formation of beads.The formation of beads is related, among other factors, to the solution viscosity parameter.The reduction in the viscosity of a solution leads to the formation of beads or electrospraying.24For PBAT/PCL/IBU-30, it is impossible to observe any fibers formed.This fact can be explained by the reduction in the conductivity of the solution presented in Table1.Conductivity can influence the formation of smooth fibers due to the density of charges present in the solution that interfere with the stability of the formed jet.24

Figure 2 .
Figure 2. FTIR-ATR spectra of PBAT/PCL films without and with IBU incorporation at different concentrations.

Figure 5 .
Figure 5. DSC curves under (a) heat and (b) cooling of PBAT/PCL films without and with IBU incorporation at different concentrations (20 and 30% m m -1 ).

Figure 8 .
Figure 8. Percentage of IBU released in the function of the time for the films (a) PBAT/PCL/IBU-20, and (b) PBAT/PCL/IBU-30 in PBS (pH 7.4) at 37 ºC.The initial IBU concentration in films was 10 mg.The analysis was performed in quadruplicate.

Table 3 .
Crystallinity degree calculated (equation 1) for the two peaks of the polymers melting containing IBU

Table 4 .
Contact angle values for wettability studies images reported in Figure7

Table 5 .
Mathematical models used to the fitting of liberation data of IBU from films shape parameter that characterizes the curve as exponential; Ti: localization parameter that represents the latency time before the start of the dissolution or release process; α l : scale factor in the logistics 1 model; β l : form factor in the logistics model; α G : scale factor in the Gompertz model; β G : form factor in Gompertz models; Ф: standard normal distribution; α P : scale factor in the Probit model; β P : form factor in the Probit model.
BL : constant in the Baker-Lonsdal model; k 1q : constant in the quadratic model; k 2 : constant in the quadratic model denoting the relative contribution of t-dependent drug release (quadratic); α: scale parameter that defines the time scale of the process; β: