Evaluation of Different Thermoanalytical Methods for the Analysis of the Stability of Naproxen-Loaded Amorphous Solid Dispersions

The aim of this research was to investigate three thermoanalytical techniques from the glass transition temperature (Tg) determination point of view. In addition, the examination of the correlation between the measured Tg values and the stability of the amorphous solid dispersions (ASDs) was also an important part of the work. The results showed that a similar tendency of the Tg can be observed in the case of the applied methods. However, Tg values measured by thermally stimulated depolarization currents showed higher deviation from the theoretical calculations than the values measured by modulated differential scanning calorimetry, referring better to the drug-polymer interactions. Indeed, the investigations after the stress stability tests revealed that micro-thermal analysis can indicate the most sensitive changes in the Tg values, better indicating the instability of the samples. In addition to confirming that the active pharmaceutical ingredient content is a crucial factor in the stability of ASDs containing naproxen and poly(vinylpyrrolidone-co-vinyl acetate), it is worthwhile applying orthogonal techniques to better understand the behavior of ASDs. The development of stable ASDs can be facilitated via mapping the molecular mobilities with suitable thermoanalytical methods.


Introduction
The increasing number of newly discovered poorly water-soluble drug candidates encourages the pharmaceutical actors to develop the current formulation strategies and opens up novel methods [1,2]. Otherwise, the properties of the widely used excipients and technologies may create a barrier to the commercialization of effective active pharmaceutical ingredients (APIs) if the final dosage form prepared that way does not fulfill the necessary bioavailability requirements [3]. Amorphous forms can be a possible solution to tackle these challenges since the disordered structure contributes to the enhanced dissolution of poorly water-soluble APIs [4]. However, the majority of the API are thermodynamically stable rather than in the crystalline form. It means that their amorphous status is unstable and can be characterized by higher free Gibbs energy, which pushes the system toward relaxation and eventually crystallization [5][6][7]. If the physical stability of amorphous API decreases, it loses its advantages from the dissolution point of view. Therefore, the authorization bodies strictly require ensuring the stability of the amorphous form at least until the end of the expiration date [8].

Preparation of Amorphous Solid Dispersions
The amorphous solid dispersions of NAP and PVPVA64 were prepared by singleneedle electrospinning (SNES). A nozzle with an inner diameter of 0.5 mm was applied for the fiber formation. An NT-35 high voltage direct current supply (MA2000; Unitronik Ltd., Nagykanizsa, Hungary) was connected to the spinneret while a 20 kV electrical potential was set during the experiments. Opposite the needle, a grounded aluminum collector covered with aluminum foil was placed 15 cm far from the spinneret. The solutions containing the API and the polymer were fed by a SEP-10S Plus type syringe pump (Aitecs, Vilnius, Lithuania) with a 10 mL/h dosing rate. The preparation of electrospun amorphous solid dispersions was accomplished at room temperature (25 • C) and at 45 ± 5% relative humidity.

Scanning Electron Microscopy (SEM)
A JEOL JSM 6380LA type scanning electron microscope (JEOL, Tokyo, Japan) was applied to investigate the morphology and size of the electrospun amorphous solid dispersions. A conductive double-sided carbon adhesive tape was used for fixing the specimens to the sample holders. Before the SEM examinations, a thin layer of conducting gold was sputtered to the surface of the samples by a JEOL 1200-type equipment (JEOL, Tokyo, Japan) to avoid electrostatic charging. During the SEM measurements, the accelerating voltage was adjusted to 10 kV, the applied working distance was between 7 and 15 mm, and the spot size was 40 nm. The quantitative evaluation of the photos was performed with a randomized diameter determination method [45].

X-ray Powder Diffraction (XRPD)
A PANalytical X'pert Pro MDP X-ray diffractometer (Almelo, The Netherlands) equipped with a Cu-Kα source and Ni filter was used to investigate the crystalline traces of the electrospun materials. The applied voltage and current were 40 kV and 30 mA, respectively. The measurements were performed in continuous scan mode in a scan range between 2θ angles of 4 and 44 • with a step size of 0.0167 • and 15 s counting time.

Modulated Differential Scanning Calorimetry (MDSC)
A DSC3+ device (Mettler Toledo AG, Zürich, Switzerland) coupled with a Huber TC100 cooler (Offenburg, Germany) was applied to examine the amorphous character of the electrospun sample. The DSC measurements were performed in a stochastic temperaturemodulated mode called TOPEM ® , which enabled the separation of the total heat flow to reversing-and non-reversing components. During the TOPEM ® measuring process, the frequency of the modulation varies randomly within a given range, in this case, between 15 and 30 s. The temperature was raised from 0 • C to 250 • C while the overall heating rate was 2 • C/min. The pulse height was set to 1 • C, meaning that the temperature was modulated continuously by ±0.5 • C. The DSC chamber was purged with dry nitrogen using a flow rate of 50 mL/h. For the DSC experiments, a sample weight of 7-15 mg was measured into a 40 µL pierced aluminum pan.
To determine the T g of the amorphous NAP, the traditional linear heating DSC method was applied from −50 • C to 250 • C with a heating rate of 20 • C/min. The nitrogen flush, the sample mass, and the pan were the same as used during the modulated measurements.

Thermogravimetric Analysis (TGA)
The residual solvent content of the samples was investigated by thermogravimetric analysis using a Q5000 TGA instrument (TA Instruments, New Castle, DE, USA). Ca. 10 mg electrospun sample was measured into a tared platinum pan. The adjusted heating program increased the temperature of the chamber from 20 to 105 • C at 2 • C/min, which was followed by an isothermal part at 105 • C for a further 15 min. Nitrogen flush with a rate of 25 mL/min was introduced into the chamber during the measurements.

Thermally Stimulated Depolarization Current (TSDC)
TSDC measurements were performed with a TSCII-type thermally stimulated current equipment (Setaram, Calure, France). The device used liquid nitrogen as a coolant, which was controlled by a Norhof 910 LN2 pump (Ede, The Nederlands). The measuring chamber was purged with helium three times before each measurement to ensure an inert atmosphere during the experiment. For the TSDC experiments, ca. 18-20 mg electrospun material was measured and compressed manually into a copper sample holder with a Teflon ring, which was applied as the bottom electrode ( Figure 1A). Preliminary works showed that this amount corresponded to the 0.5 mm sample thickness. After the sample preparation, a stainless steel disc used as an upper electrode was placed on the surface of the sample ( Figure 1B). The closed sample holder was put in the equipment between a needle-type electrode probe and an electrode holder ( Figure 1C). The effective area of the prepared Pharmaceutics 2022, 14, 2508 5 of 20 parallel plane capacitor was 38.5 mm 2 (meaning that the diameter of the upper electrode was 7 mm). material was measured and compressed manually into a copper sample holder with a Teflon ring, which was applied as the bottom electrode ( Figure 1A). Preliminary works showed that this amount corresponded to the 0.5 mm sample thickness. After the sample preparation, a stainless steel disc used as an upper electrode was placed on the surface of the sample ( Figure 1B). The closed sample holder was put in the equipment between a needle-type electrode probe and an electrode holder ( Figure 1C). The effective area of the prepared parallel plane capacitor was 38.5 mm 2 (meaning that the diameter of the upper electrode was 7 mm).  Figure 2 presents the scheme of the applied measuring process, during which the depolarization current induced by molecular mobility was determined [37]. During all measurements, the annealing temperature (Ta) was adjusted to 20 °C , and the annealing time (ta) was 1 min. After holding the sample at the annealing temperature, the measuring program continued with a heating step to reach the polarization temperature (Tp). Tp for each composition was set such that it was ca. 20 °C higher than its Tg determined by DSC [37]. The polarization time (tp) was 5 min in all cases, while 300 V/mm field strength (E) was applied, which meant 150 V polarization voltage (Up) for the 0.5 mm sample thickness. The polarization was followed by a cooling step with a 10 °C /min cooling rate (rc) to the 0 °C (T0). The electric field was still present during the cooling step. The holding time at T0 (t0) was set to 1 min while the polarization field was removed. Then a heating step was followed with a heating rate of 5 °C /min (rh) to reach the final temperature (Tf = 150 °C ). The depolarization current was measured during the heating and was depicted as a function of the temperature.  Figure 2 presents the scheme of the applied measuring process, during which the depolarization current induced by molecular mobility was determined [37]. During all measurements, the annealing temperature (T a ) was adjusted to 20 • C, and the annealing time (t a ) was 1 min. After holding the sample at the annealing temperature, the measuring program continued with a heating step to reach the polarization temperature (T p ). T p for each composition was set such that it was ca. 20 • C higher than its T g determined by DSC [37]. The polarization time (t p ) was 5 min in all cases, while 300 V/mm field strength (E) was applied, which meant 150 V polarization voltage (U p ) for the 0.5 mm sample thickness. The polarization was followed by a cooling step with a 10 • C/min cooling rate (r c ) to the 0 • C (T 0 ). The electric field was still present during the cooling step. The holding time at T 0 (t 0 ) was set to 1 min while the polarization field was removed. Then a heating step was followed with a heating rate of 5 • C/min (r h ) to reach the final temperature (T f = 150 • C). The depolarization current was measured during the heating and was depicted as a function of the temperature.

Micro-Thermal Analysis (µTA)
The third method to determine the Tg of the samples was µ TA™. The measurements were accomplished using a 2990 Micro-Thermal Analyzer (TA Instruments, New Castle, The third method to determine the T g of the samples was µTA™. The measurements were accomplished using a 2990 Micro-Thermal Analyzer (TA Instruments, New Castle, DE, USA) [46] with µTALab software (SPM Labs Llc., Tempe, AZ, USA). The key element of the device is the atomic force microscopic (AFM) head with an extremely tiny temperature probe. Since the prepared electrospun fibers had a very loose and soft structure, stabilizing the probe on the surface of the sample before the measurement was not possible. Therefore, fibers were compressed first using the measuring cell of the TSDC. Later, flat round pastilles were formed with a Camilla OL95-type press by using 100 bar pressure. Approximately 50-55 mg samples were used for this to reach~0.5 mm sample thickness. Then ca. 1 × 1 mm pieces were cut from the pastilles and stuck with double-sided adhesive tape on the surface of a 1 cm 2 metal disk, which was placed under the thermal probe. The surface of the electrospun sample was investigated by a microscope coupled with a charged coupled device (CCD) camera. This accessory facilitated the selection of the measuring points. The temperature probe was heated from 0 • C to 180 • C with a heating rate of 10 • C/s. Five points were measured on each investigated surface, and two different pieces were investigated from each composition.

Stress Stability Test
A short-term stress stability test was accomplished with the different ASDs to examine their behavior after storage at a higher temperature, and higher relative humidity (RH). The samples were placed into a Pol-Eko KK115 type climate chamber (Pol-Eko Apparatura, Poland) at 30 • C and 65% RH in open holders for 1 week. Sampling was done after 1 day and 1 week. The stability samples were investigated by SEM, DSC, TSDC, µTA, and XRPD.

Polarized Light Microscopy (PLM)
The presence of crystalline traces in the samples after the stress stability test was analyzed by an Amplival Carl Zeiss (Jena, Germany) polarized microscope equipped with an OLYMPUS C4040 Z-type camera. A DP-Soft software was applied for recording PLM images and evaluation. The agglomerated electrospun materials were distributed in silicon oil before the measurements.

In Vitro Dissolution Testing
The dissolution test of the different electrospun samples was carried out with a Pharmatest PTWS 600 dissolution tester (Pharma Test Apparatebau AG, Hainburg, Germany). The samples were examined using the so-called "tapped basket" method, which means the combination of the USP I and the USP II dissolution tests [47]. The adjusted stirrer speed of the paddles was 50 rpm. For the dissolution tests, 900 mL of 0.1 N HCl dissolution media at 37 ± 0.5 • C was used. The investigated dose was 50 mg, while each composition was measured in triplicate. Online measurement of the dissolved NAP was performed using an Agilent 8453 UV-Vis spectrophotometer (Agilent Technologies, Santa Clara, CA, USA) at 272 nm and a flow cell system equipped with a length of 10 mm cuvettes.

Preparation and Basic Characterization of the Samples
The preparation of appropriate ASDs is the key condition to evaluate the contribution of different thermoanalytical methods to the characterization of the glass transition process. Electrospinning, being able to form a perfect amorphous structure, was chosen for the sample preparation in this research. This ASD preparation method requires less solvent than other methods, the electrostatic field facilitates, the evaporation of the solvents, and the electrospinning can be performed at room temperature and atmospheric pressure; therefore, it is a very gentle way of the preparation of amorphous pharmaceutical solids. Table 1 summarizes the details of the different ASD's examined in this work. Another advantage of electrospinning is that changes in the morphology of the fibers might be visible indicators of the instability of the ASD systems [48]. Considering the SEM images of the different ASDs after the electrospinning (Figure 3), it can be seen that the fiber formation was successfully achieved in all cases. Although the fiber diameter of the NAP-loaded samples is slightly smaller than the PVPVA64 fibers, the diameter of each composition falls in a similar size range. The thinner fibers observed in the case of the APIcontaining samples suggest that NAP probably increased the conductivity of the solution, thus helping the elongation of the jets during the electrospinning process [49].  However, the main question that arises is whether the formation of the amorphous arrangement was successful. The XRPD patterns of the fibrous samples showed only the amorphous halo and no characteristic Bragg peaks of the crystalline NAP ( Figure 4A), which suggested that the amorphization was successfully fulfilled via electrospinning. This was confirmed by the DSC measurements as no melting peak of the API was observed in the thermograms of the electrospun samples ( Figure 4B). Although flatter peaks were seen at lower temperatures, those belonged to other events such as the enthalpy relaxation, the presence of moisture in the samples, and the glass transitions. As the polymer content decreased, the size of the integrated peak also decreased. However, the main question that arises is whether the formation of the amorphous arrangement was successful. The XRPD patterns of the fibrous samples showed only the amorphous halo and no characteristic Bragg peaks of the crystalline NAP ( Figure 4A), which suggested that the amorphization was successfully fulfilled via electrospinning. This was confirmed by the DSC measurements as no melting peak of the API was observed in the thermograms of the electrospun samples ( Figure 4B). Although flatter peaks were seen at lower temperatures, those belonged to other events such as the enthalpy relaxation, the presence of moisture in the samples, and the glass transitions. As the polymer content decreased, the size of the integrated peak also decreased. which suggested that the amorphization was successfully fulfilled via electrospinning. This was confirmed by the DSC measurements as no melting peak of the API was observed in the thermograms of the electrospun samples ( Figure 4B). Although flatter peaks were seen at lower temperatures, those belonged to other events such as the enthalpy relaxation, the presence of moisture in the samples, and the glass transitions. As the polymer content decreased, the size of the integrated peak also decreased. The effect of the moisture content was investigated by TGA as well ( Figure 5), which correlated well with the DSC results. The smallest peak area belonged to the lowest polymer content sample in the case of the DSC thermograms, while that composition was characterized by the lowest weight loss by the TGA measurements. This suggests that the moisture content of the samples can be linked to the polymer, which can influence the glass transition temperature and also the physical stability of the ASDs [50]. To exclude the effect of the residual solvents coming from the solvent-based electrospinning, the sam- The effect of the moisture content was investigated by TGA as well ( Figure 5), which correlated well with the DSC results. The smallest peak area belonged to the lowest polymer content sample in the case of the DSC thermograms, while that composition was characterized by the lowest weight loss by the TGA measurements. This suggests that the moisture content of the samples can be linked to the polymer, which can influence the glass transition temperature and also the physical stability of the ASDs [50]. To exclude the effect of the residual solvents coming from the solvent-based electrospinning, the samples were investigated 2 weeks later of the preparation process as well ( Figure 5B). Although the weight loss of the samples decreased after drying at room temperature, suggesting the evaporation of the residual solvents, the decreasing tendency in the function of the NAP content remained.
Pharmaceutics 2022, 14, x FOR PEER REVIEW 9 of 20 ples were investigated 2 weeks later of the preparation process as well ( Figure 5B). Although the weight loss of the samples decreased after drying at room temperature, suggesting the evaporation of the residual solvents, the decreasing tendency in the function of the NAP content remained. Summarizing the results of the basic characterizations it can be said that the preparation of ASDs was successfully performed, and the samples proved to be suitable for further investigations.

Measuring the Glass Transition Temperature with Different Methods
The main goal of this research was to evaluate three thermoanalytical methods, working on different principles, for characterizing amorphous pharmaceuticals. Therefore, the next step was to investigate the glass transition of the prepared electrospun samples and determine the Tg values based on the measurements. Figure 6 proves that each technique was suitable to indicate clearly one signal related to the glass transition. As it was mentioned above, MDSC makes it possible to separate the overlapping events and present the glass transition in the reversible heat flow. Taking advantage of this, Tg values of the NAPloaded samples were easily determined from the ramp belonging to the glass transition of the ASDs ( Figure 6A). Similarly, µ TA indicates the glass transition with a ramp too, because the sensor position decreases with increased molecular mobility and free volume ( Figure 6C). µ TA was able to measure more points of the sample in a few seconds, ena- Summarizing the results of the basic characterizations it can be said that the preparation of ASDs was successfully performed, and the samples proved to be suitable for further investigations.

Measuring the Glass Transition Temperature with Different Methods
The main goal of this research was to evaluate three thermoanalytical methods, working on different principles, for characterizing amorphous pharmaceuticals. Therefore, the next step was to investigate the glass transition of the prepared electrospun samples and determine the T g values based on the measurements. Figure 6 proves that each technique was suitable to indicate clearly one signal related to the glass transition. As it was mentioned above, MDSC makes it possible to separate the overlapping events and present the glass transition in the reversible heat flow. Taking advantage of this, T g values of the NAP-loaded samples were easily determined from the ramp belonging to the glass transition of the ASDs ( Figure 6A). Similarly, µTA indicates the glass transition with a ramp too, because the sensor position decreases with increased molecular mobility and free volume ( Figure 6C). µTA was able to measure more points of the sample in a few seconds, enabling the examination of the micro homogeneity of the samples. The relative standard deviations were between one and six percent, indicating the homogeneous distribution of the API in the polymer matrix. During the TSDC measurements, a well-visible peak corresponds to the T g since the depolarization current starts to increase when the ordered dipoles start to rearrange to the disordered state ( Figure 6B). As all techniques showed only one single ramp (DSC, µTA) or peak (TSDC), the results confirmed that the amorphization was successfully achieved. The absence of phase separation indicated that the NAP is molecularly dispersed in the PVPVA64. Looking at the T g results of the three different measurements together, it is clear that the same decreasing tendency can be observed in the case of each method as the API content is increasing. This trend refers to the plasticizing effect of the NAP, which was efficiently detectable with all the tested analytical techniques. However, the Tg of the pure API is missing from Figure 6 because that could not be determined by the applied methods. Two different amorphization techniques were tested to prepare the amorphous NAP. First, a quench cooling process was tried. The crystalline API was heated to 30 °C above its melting point, and then it was cooled with liquid nitrogen. The prepared sample was then measured into a DSC pan, and the same MDSC method was adjusted as used in the case of the ASDs. Not surprisingly, the ambient temperature while the samples were measured and the slow heating rate during the MDSC measurement was favorable to the crystallization. Consequently, only the melting peak of the crystalline API was observed in the thermograms (data are not shown). For this reason, amorphous NAP was attempted to form in-situ in the DSC chamber. To achieve this, the crystalline API measured into the DSC pan was heated to 30 °C above its melting point, and then it was cooled down with the maximum cooling rate of the device (~40 °C /min) to −70 °C . The MDSC method resulted in only the melting peak of the NAP again, indicating that the rate of temperature change, applicable with this method, is slow to detect the glass transition in the case of this prone to crystallization of the API (data are not shown). In order to avoid crystallization, finally, the in-situ prepared amorphous NAP was investigated with the conventional DSC method and faster heating rate (20 °C /min). This measurement method proved to be suitable for detecting the glass transition of the amorphous NAP (Figure 7). Although the sample was not fully amorphous, as the melting peak was also visible in the thermogram, a clear ramp appeared under 0 °C , indicating the Tg of the amorphous part of the investigated NAP. The determined Tg value is the same as the estimated result described in the [51] publication confirming the theoretical calculations experimentally. However, it is worth considering that the amorphization (applied method, cooling rate, etc.) can affect the measured Tg value; therefore, the Tg measured in this study might differ from other already published values [52,53]. Despite this, regarding the determination of the Tg of the pure NAP, DSC proved to be the most suitable technique among the three tested methods. The in-situ sample preparation could not be performed in the case of the µ TA device, while (although the in-situ sample preparation However, the T g of the pure API is missing from Figure 6 because that could not be determined by the applied methods. Two different amorphization techniques were tested to prepare the amorphous NAP. First, a quench cooling process was tried. The crystalline API was heated to 30 • C above its melting point, and then it was cooled with liquid nitrogen. The prepared sample was then measured into a DSC pan, and the same MDSC method was adjusted as used in the case of the ASDs. Not surprisingly, the ambient temperature while the samples were measured and the slow heating rate during the MDSC measurement was favorable to the crystallization. Consequently, only the melting peak of the crystalline API was observed in the thermograms (data are not shown). For this reason, amorphous NAP was attempted to form in-situ in the DSC chamber. To achieve this, the crystalline API measured into the DSC pan was heated to 30 • C above its melting point, and then it was cooled down with the maximum cooling rate of the device (~40 • C/min) to −70 • C. The MDSC method resulted in only the melting peak of the NAP again, indicating that the rate of temperature change, applicable with this method, is slow to detect the glass transition in the case of this prone to crystallization of the API (data are not shown). In order to avoid crystallization, finally, the in-situ prepared amorphous NAP was investigated with the conventional DSC method and faster heating rate (20 • C/min). This measurement method proved to be suitable for detecting the glass transition of the amorphous NAP ( Figure 7). Although the sample was not fully amorphous, as the melting peak was also visible in the thermogram, a clear ramp appeared under 0 • C, indicating the T g of the amorphous part of the investigated NAP. The determined T g value is the same as the estimated result described in the [51] publication confirming the theoretical calculations experimentally. However, it is worth considering that the amorphization (applied method, cooling rate, etc.) can affect the measured T g value; therefore, the T g measured in this study might differ from other already published values [52,53]. Despite this, regarding the determination of the T g of the pure NAP, DSC proved to be the most suitable technique among the three tested methods. The in-situ sample preparation could not be performed in the case of the µTA device, while (although the in-situ sample preparation was possible) in the TSDC equipment the huge changes in the free volume resulted in the loss of contact between the sample and the electrode, generating a noisy and uninterpretable curve (data are not shown). On the whole, however, Tg of all ASDs could be measur moanalytical technique. In addition, the determination of th to use of the Gordon-Taylor equation (Equation (1)) for calc ues of the ASD samples [51,54].
Tg,mix = (wdTg,d + KwpTg,p)/(wd + K In Equation (1), wd and wp indicate the weight fraction respectively. Tg,mix, Tg,d, and Tg,p refer to the Tg of the ASD, respectively. Furthermore, K is a constant, which can be det amorphous drug (ρd) and polymer (ρp) based on Equation (2 K ≈ (ρdTg,d/ρpTg,p) Using the density data from the publication [51], the t ASDs was determined according to the Gordon-Taylor equ ured Tg of the pure NAP and PVPVA64 by DSC. The calcula ues were compared in Figure 8. Based on this comparison, On the whole, however, T g of all ASDs could be measured by each investigated thermoanalytical technique. In addition, the determination of the T g of the pure NAP enabled to use of the Gordon-Taylor equation (Equation (1)) for calculating the theoretical T g values of the ASD samples [51,54].
In Equation (1), w d and w p indicate the weight fraction of the drug and the polymer, respectively. T g,mix , T g,d , and T g,p refer to the T g of the ASD, pure drug, and the polymer, respectively. Furthermore, K is a constant, which can be determined using the density of amorphous drug (ρ d ) and polymer (ρ p ) based on Equation (2).
Using the density data from the publication [51], the theoretical T g of the prepared ASDs was determined according to the Gordon-Taylor equation and utilizing the measured T g of the pure NAP and PVPVA64 by DSC. The calculated and the measured T g values were compared in Figure 8. Based on this comparison, it can be concluded that the DSC results are most close to the calculated T g values. This may not be surprising considering that the T g values of the pure components used for the calculation were determined by DSC, it is logical. However, why the values measured by the other two methods differ so much and in such directions is questionable.
ASDs was determined according to the Gordon-Taylor equation and utilizing the measured Tg of the pure NAP and PVPVA64 by DSC. The calculated and the measured Tg values were compared in Figure 8. Based on this comparison, it can be concluded that the DSC results are most close to the calculated Tg values. This may not be surprising considering that the Tg values of the pure components used for the calculation were determined by DSC, it is logical. However, why the values measured by the other two methods differ so much and in such directions is questionable.  It is considered to be obvious that there are some differences between the results of the three different techniques because their measuring principles are distinct. TSDC analysis uses an electric field that can excite other parts of the molecule too in contrast to the simple increase in temperature used by the other two methods [35]. Furthermore, the effect of mechanical loading in the case of µTA can also influence the locality of the T g [55]. During the TSDC measurements, the plan is to approach the heating rate of the MDSC. However, heating that is too slow is not recommended because the peaks relating to phase separation can disappear [56]. That is why 5 • C/min was adjusted as the heating rate during the TSDC measurements. Despite the higher heating rate, lower temperatures were measured than in the case of the DSC measurements, especially at lower API content. It is well known that the Gordon-Taylor equation does not give a precise prediction to T g if intermolecular bonds occur in the system [57], for instance, in the case of ASDs containing NAP and PVPVA64. Since the T g values measured by DSC are very close to the calculated values (less than 5 • C differences were by each composition) it can be assumed that the DSC did not detect or hardly detected the interaction between the API and the polymer ( Table 2). In contrast, the values measured by the TSDC method reflect the interactions between the NAP and the PVPVA64, suggesting that the presence of intermolecular interactions can be better detected with this technique. Table 2. Deviation of the measured T g values from the calculated ones.

Sample
MDSC In contrast to TSDC, µTA showed higher values than the DSC measurements. One of the reasons can be the measuring principle; instead of the whole sample only very small volumes (touched by the thermal probe) are heated during the µTA measurement. On the other hand, compression applied on the measured fibers could contribute to the higher T g values. The effect of the compression was investigated in-depth. It was observed that the compression significantly affects the measured glass transition ( Figure 9); with increasing compression force, the determined T g increased as well. Although in this way, the differences in the T g values measured by DSC and µTA are increasing too, the samples compressed by the press were used during the further experiments because this sample preparation is more reproducible. Otherwise, it could be challenging to distinguish the differences that come from the distinct composition and from the compression, which could led to false results. In addition, the tendency was similar to that shown in Figure 6C  Taking into account the results of the three different tec be stated that all of them are suitable for determining the Tg theless, each method has an advantage compared to the othe the only applicable method for measuring the Tg of the am were influenced by intermolecular interactions. Finally, µ TA making it feasible to measure repetitions in a very short tim neity of the samples and indicating the effect of mechanical

Effect of the Stress Stability Tests
It was clearly visible that all tested analytical technique gating the ASDs containing NAP and PVPVA64. To see their of the ASD systems' physical stability, the prepared samples conditions. Overviewing the SEM images, it is already con effect of the API does not favor the morphology of the fiber Taking into account the results of the three different techniques to measure T g , it can be stated that all of them are suitable for determining the T g of API-loaded ASDs. Nevertheless, each method has an advantage compared to the other two. The DSC proved to be the only applicable method for measuring the T g of the amorphous NAP. TSDC results were influenced by intermolecular interactions. Finally, µTA provided the fastest results, making it feasible to measure repetitions in a very short time, determining the homogeneity of the samples and indicating the effect of mechanical stresses.

Effect of the Stress Stability Tests
It was clearly visible that all tested analytical techniques are appropriate for investigating the ASDs containing NAP and PVPVA64. To see their relevance in the examination of the ASD systems' physical stability, the prepared samples were stored at stress stability conditions. Overviewing the SEM images, it is already conspicuous that the plasticizer effect of the API does not favor the morphology of the fibers (Table 3). While the electrospun polymer kept its fibrous structure even after one week of storage, the ASD samples lost it. With increasing API content, the merging of the fibers and the disappearance of the fibrous structure happened earlier. The samples with 10% and 20% drug loading remained fibrous after one day of storage. The diameter of the fibers started to increase, and fibers were united in the case of the sample containing 30% of NAP after the first day. The samples with the highest API loading lost their fibrous characteristics right after one day of storage. Considering the SEM images, it can be expected that the T g values may be changed since the samples reacted spectacularly to the increased moisture content in their environment [58]. Table 3. Summary of the SEM images of the prepared samples before and after storage.

START 1 Day 1 Week
PVPVA64 stress stability conditions. Overviewing the SEM images, it is already conspicuous that the plasticizer effect of the API does not favor the morphology of the fibers (Table 3). While the electrospun polymer kept its fibrous structure even after one week of storage, the ASD samples lost it. With increasing API content, the merging of the fibers and the disappearance of the fibrous structure happened earlier. The samples with 10% and 20% drug loading remained fibrous after one day of storage. The diameter of the fibers started to increase, and fibers were united in the case of the sample containing 30% of NAP after the first day. The samples with the highest API loading lost their fibrous characteristics right after one day of storage. Considering the SEM images, it can be expected that the Tg values may be changed since the samples reacted spectacularly to the increased moisture content in their environment [58]. Table 3. Summary of the SEM images of the prepared samples before and after storage.

START 1 Day 1 Week
PVPVA64 stress stability conditions. Overviewing the SEM images, it is already conspicuous that the plasticizer effect of the API does not favor the morphology of the fibers (Table 3). While the electrospun polymer kept its fibrous structure even after one week of storage, the ASD samples lost it. With increasing API content, the merging of the fibers and the disappearance of the fibrous structure happened earlier. The samples with 10% and 20% drug loading remained fibrous after one day of storage. The diameter of the fibers started to increase, and fibers were united in the case of the sample containing 30% of NAP after the first day. The samples with the highest API loading lost their fibrous characteristics right after one day of storage. Considering the SEM images, it can be expected that the Tg values may be changed since the samples reacted spectacularly to the increased moisture content in their environment [58]. Table 3. Summary of the SEM images of the prepared samples before and after storage.

START 1 Day 1 Week
PVPVA64 stress stability conditions. Overviewing the SEM images, it is already conspicuous that the plasticizer effect of the API does not favor the morphology of the fibers (Table 3). While the electrospun polymer kept its fibrous structure even after one week of storage, the ASD samples lost it. With increasing API content, the merging of the fibers and the disappearance of the fibrous structure happened earlier. The samples with 10% and 20% drug loading remained fibrous after one day of storage. The diameter of the fibers started to increase, and fibers were united in the case of the sample containing 30% of NAP after the first day. The samples with the highest API loading lost their fibrous characteristics right after one day of storage. Considering the SEM images, it can be expected that the Tg values may be changed since the samples reacted spectacularly to the increased moisture content in their environment [58]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests ( Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].
Contrary to expectations, the Tg values did not change in all cases after the stress stability tests ( Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].

20%NAP_ 80%PVPVA64
Pharmaceutics 2022, 14 Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].

30%NAP_ 70%PVPVA64
Pharmaceutics 2022, 14 Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].

40%NAP_ 60%PVPVA64
Pharmaceutics 2022, 14 Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].

50%NAP_ 50%PVPVA64
Pharmaceutics 2022, 14 Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. Contrary to expectations, the Tg values did not change in all cases after the stress stability tests (Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the Tg values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure  10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the Tg values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the Tg region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest APIloaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher Tg values were experienced with µTA after the stress stability tests. Only the Tg of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the Tg-s increased in the direction of the Tg of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drugloading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].
Contrary to expectations, the T g values did not change in all cases after the stress stability tests ( Figure 10). According to the MDSC measurements, only those with an API content of 20% or more showed a decreasing tendency in the T g values; no significant changes were detectable during the measurements of 10% NAP-loaded samples ( Figure 10A). Similar trends were seen in the case of the TSDC results, with the difference that only the results of the samples with drug content of 30% and more showed a decrease in the T g values after the storage ( Figure 10B). Another interesting fact about the TSDC results is that in the case of the 50% drug loading sample, in the T g region measured before storage, only an inflection of a curve can be observed after the stress stability test, but one clear peak appeared at a higher temperature. That is why more red points can be seen in Figure 10B, which can be explained as the signal of phase separation in the highest API-loaded sample. The most significant shifts were measured by µTA ( Figure 10C). In contrast with the other two methods, higher T g values were experienced with µTA after the stress stability tests. Only the T g of the polymer did not change, which is well correlated to the SEM images and the results of the other two methods. Looking at the results of the ASDs, the T g -s increased in the direction of the T g of the PVPVA64, which assumes that the phase separation started [39]. One of the reasons that higher drug-loading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the T g before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59].
the phase separation started [39]. One of the reasons that higher drug-loading samples stand out more might be that these ASDs started to crystallize, which can distort the evaluation. In addition, it is also visible that the order of the Tg before the storage in the case of the 40% and 50% drug-containing samples were exchanged compared to the compressed samples. This difference indicates that the compression force had an influence on the stability of the samples [59]. However, despite the changes in the T g values, only the results of the 50% drug loading samples showed an extra signal pointing to phase separation ( Figure 11). In the non-reversing heat flow of the MDSC thermogram, a peak was observed around 114 • C, which was followed by a small exothermic peak belonging to a cold crystallization ( Figure 11A). A step change around 114 • C is also visible in the reversing heat flow of the sample after the stress stability tests indicating a glass transition, referring to the phase separation in the ASD. The TSDC results showed the above-mentioned inflection in the curve and the second peak, which are related to the phase separation as well ( Figure 11B). Similarly, more than one ramp could see in the case of the µTA results too, representing that the molecular dispersity of the API in the polymer is not homogeneous anymore ( Figure 11C). Indeed, the effect of the compression on the stability of the high NAP-loaded ASD was also visible since an additional ramp appeared even during the measurement of the samples before the storage. The investigation of the other compositions did not result in similar changes. Consequently, only the differences in the T g values can be applied to predict the stability of the prepared ASD samples. However, despite the changes in the Tg values, only the results of the 50% drug loading samples showed an extra signal pointing to phase separation ( Figure 11). In the nonreversing heat flow of the MDSC thermogram, a peak was observed around 114 °C , which was followed by a small exothermic peak belonging to a cold crystallization ( Figure 11A). A step change around 114 °C is also visible in the reversing heat flow of the sample after the stress stability tests indicating a glass transition, referring to the phase separation in the ASD. The TSDC results showed the above-mentioned inflection in the curve and the second peak, which are related to the phase separation as well ( Figure 11B). Similarly, more than one ramp could see in the case of the µ TA results too, representing that the molecular dispersity of the API in the polymer is not homogeneous anymore ( Figure 11C). Indeed, the effect of the compression on the stability of the high NAP-loaded ASD was also visible since an additional ramp appeared even during the measurement of the samples before the storage. The investigation of the other compositions did not result in similar changes. Consequently, only the differences in the Tg values can be applied to predict the stability of the prepared ASD samples.

Correlations between the Measured Tg Values and the Stability
In the previous chapter, the changes in morphology and the Tg values after the stability test were highlighted. However, the investigation of crystalline traces, which could be evidence of physical instability, was not presented above. Therefore, in this section, the stability described by the absence or presence of crystalline material will be discussed. Furthermore, it will also be examined whether there is a correlation between the Tg values and the physical stability.
First, one of the most common methods, the XRPD was applied to investigate the NAP-loaded ASD samples before and after the storage (Figure 12). In connection with what was previously mentioned, the largest changes were observable during the measurement of the 50% drug loading sample. XRPD patterns of the samples after one day and one week of storage showed small Bragg peaks indicating the presence of crystallinity. All the other samples did not show Bragg peaks, which would mean two things. If the samples after the stress stability test contained crystalline traces, their amount is below the detection limit of the applied method at the adjusted parameters. The other possibility

Correlations between the Measured T g Values and the Stability
In the previous chapter, the changes in morphology and the T g values after the stability test were highlighted. However, the investigation of crystalline traces, which could be evidence of physical instability, was not presented above. Therefore, in this section, the stability described by the absence or presence of crystalline material will be discussed. Furthermore, it will also be examined whether there is a correlation between the T g values and the physical stability.
First, one of the most common methods, the XRPD was applied to investigate the NAP-loaded ASD samples before and after the storage (Figure 12). In connection with what was previously mentioned, the largest changes were observable during the measurement of the 50% drug loading sample. XRPD patterns of the samples after one day and one week of storage showed small Bragg peaks indicating the presence of crystallinity. All the other samples did not show Bragg peaks, which would mean two things. If the samples after the stress stability test contained crystalline traces, their amount is below the detection limit of the applied method at the adjusted parameters. The other possibility could be that the samples, except those with 50% drug loading, were stable after storage at stress conditions. To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µ TA. The other two methods did not show any changes in the Tg of this sample.  To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing T g values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest T g -s can be characterized with the lowest physical stability. However, according to the T g values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the T g of this sample.
Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured T g values ( Figure 13). The ASD that showed the highest T g , reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the T g values. These results can be in context with the drug-polymer ratio [60]. Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values (Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stability-related questions. The investigation of the Tg of the different ASDs highlighted that similar  Table 4. PLM images of the samples before and after the stress stability test, and the images of the reference materials.
To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the Tg of this sample. To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the Tg of this sample. To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the Tg of this sample. To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the Tg of this sample. To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the Tg of this sample. To investigate both possibilities, PLM was used. These measurements resulted in a more clear view (Table 4). Birefringence was seen in the samples containing 40% and 50% NAP after one day, while all of the prepared ASDs stored for one week at stress conditions showed crystalline traces. Consequently, the decreasing Tg values predict the instabilities of the samples as the higher NAP loading ASDs with the lowest Tg-s can be characterized with the lowest physical stability. However, according to the Tg values measured after the storage at stress conditions, the physical instability of the sample containing 10% of NAP can be predictable only based on the µTA. The other two methods did not show any changes in the Tg of this sample. Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled Finally, the other crucial factor, the dissolution, needed to be investigated since it can provide whether the prepared ASD enhanced the dissolution of the poorly water-soluble API. The dissolution results showed a good correlation with the measured Tg values ( Figure 13). The ASD that showed the highest Tg, reached the highest dissolution. In addition, a similar decreasing trend was observed in the dissolution percentages as in the case of the Tg values. These results can be in context with the drug-polymer ratio [60].

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of Tg determination and physical stabilityrelated questions. The investigation of the Tg of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled

Conclusions
The present study demonstrated the special applicability of three different thermoanalytical techniques in the context of T g determination and physical stability-related questions. The investigation of the T g of the different ASDs highlighted that similar tendencies could be observed with MDSC, TSDC, and µTA. However, each method has some advantages compared to the other two techniques. The MDSC enabled distinguishing between the glass transition from the non-reversing events of the NAP-PVPVA64 ASDs'. Indeed, the T g of the pure NAP was also successfully determined by DSC. TSDC proved to be suitable to highlight the interactions between the polymer and the API since the deviations from the theoretical values calculated by the Gordon-Taylor equation were higher compared to the T g values measured by MDSC. Finally, the main advantage of the µTA lies in its speed, which contributes to the investigation of the micro homogeneity of the ASDs via measuring more points within a few seconds. The relative standard deviation of the repeated measurements was less than 6% in all cases, indicating that all prepared samples were homogeneous right after the electrospinning.
After the stress stability test, it was clear that the three thermoanalytical methods showed the changes in the T g values in a different way. According to the MDSC results, the T g decreased in the function of storage time in the case of the samples containing 20% or more API. The TSDC was able to detect this decreasing tendency only from the 30% and more drug-loading samples. In contrast with the MDSC and TSDC, however, µTA indicated changes even in the T g values of the sample containing 10% NAP. Considering the PLM images, where the ASD containing 10% API also showed crystalline traces after one week of storage, T g values measured by µTA were the most suggestive of the samples' instability.
The similarities and the additional opportunities drew attention to the fact that it may be worthwhile to use these methods simultaneously. The joint application of more analytical techniques can help to understand the behavior of the ASD samples, which can be really challenging, especially in the early stage of development. Furthermore, the results revealed that stability might be studied with minimal material consumption and fast analytical methods. Indeed, the dissolution percentages showed a similar decreasing trend to the measured T g, indicating that the API content has a key role in the case of ASDs containing NAP and PVPVA64. Overviewing the outputs of this research, it can be concluded that better knowledge of ASD systems can be achieved through the information of suitable analytical methods. In conclusion, accelerated developments and high-quality ASD-loaded medicine production could be achieved thanks to the in-depth understanding of the behavior of ASDs.