Effect of Chitosan on the Activity of Water-Soluble and Hydrophobic Porphyrin Photosensitizers Solubilized by Amphiphilic Polymers

In this work, we studied the photocatalytic activity of photosensitizers (PSs) of various natures solubilized with polyvinylpyrrolidone (PVP) and ternary block copolymer ethylene and propylene oxide Pluronic F127 (F127) in a model reaction of tryptophan photo-oxidation in water in the presence of chitosan (CT). Water-soluble compounds (dimegin and trisodium salt of chlorin e6 (Ce6)) and hydrophobic porphyrins (tetraphenylporphyrin (TPP) and its fluorine derivative (TPPF20)) were used as PSs. It was shown that the use of chitosan (Mw ~100 kDa) makes it possible to obtain a system whose activity is comparable to that of the photosensitizer-amphiphilic polymer systems. Thus, the previously observed drop in the photosensitizing activity of PS in the presence of a polysaccharide and amphiphilic polymers (AP) was absent in this case. At the same time, chitosan had practically no inhibitory effect on hydrophobic porphyrins solubilized by Pluronic F127.


Introduction
Due to the increasing resistance of bacterial and fungal pathogens to drug therapy, alternative methods of therapy have become very important for the treatment of local infections. Antimicrobial photodynamic therapy (aPDT) may be one of these methods. In most cases, aPDTis used in the treatment of superficial injuries of the skin and soft tissues (purulent wounds, burns, trophic ulcers). As a result of such therapy, complete destruction of bacterial cells without the development of resistance to aPDT occurs [1]. Photosensitizers (PS), generating singlet oxygen( 1 O 2 )-an active oxidizing agent-upon excitation with light, are successfully used in photodynamic therapy (PDT) of diseases of various etiologies [2][3][4]. In the clinical practice of photodynamic therapy in Russia, mainly drugs based on water-soluble phthalocyanines (photosens [5]) and natural porphyrins (photohem [5]), chlorins (photolon [6], photoditazin [7]) and synthetic porphyrin (temoporfin [8]) are used as PS. In the practice of aPDT, cationic photosensitizers [3] proved to be the most effective, and the "cationic" fragment is often represented by a polymer. In particular, Nitzan et al. [9] developed a polymeric PS, consisting of deuteroporphyrin and CT100), the activity of which in the generation of singlet oxygen exceeds the activity of binary PS-AP systems.

Kinetics of Tryptophan Photo-Oxidation
The study of the activity of porphyrin-containing polymer systems during the generation of singlet oxygen in the aqueous phase was carried out using the reaction of oxidation of tryptophan with singlet oxygen with the formation of tryptophan endoperoxide ( Figure 3). Photosensitizing double systems (PS-AP and PS-CT100) with water-soluble PSs were prepared by mixing solutions of porphyrin and polymer or chitosan (in 0.2% acetic acid) for 10 min. [24]. To obtain ternary systems (PS-AP-CT100), porphyrin solutions were first mixed with an amphiphilic polymer for 10 min at room temperature, then a chitosan solution was added and mixed for another 10 min [24]. Solubilization of hydrophobic porphyrins was carried out according to the procedure described in [25]. The PS concentration is 5× 10 −6 M. The AP concentrations varied from 5× 10 −6 M to 5× 10 −4 M; the concentration of CT100 varied from 1× 10 −4 M to 6× 10 −3 M (given per unit).
Photo-oxidation of tryptophan (Trp) with molecular oxygen dissolved in water was carried out in a 1 cm thick quartz cell at room temperature. The concentration of tryptophan is 10 4 M. The kinetics of the process was monitored by the change in concentration of tryptophan, which was determined from the optical density value of the absorption band (λ = 280 nm) in the UV spectrum of tryptophan.

Kinetics of Tryptophan Photo-Oxidation
The study of the activity of porphyrin-containing polymer systems during the generation of singlet oxygen in the aqueous phase was carried out using the reaction of oxidation of tryptophan with singlet oxygen with the formation of tryptophan endoperoxide ( Figure 3).  10 3 Da and a deacetylation degree DA = 75-85% and was used without additional purification (Sigma-Aldrich, Saint Louis, MO, USA). Chitosan was used as a biologically active polysaccharide, while tryptophan (Trp, Sigma-Aldrich, Saint Louis, MO, USA) was utilized as a substrate. The structures of polymers are shown in Figure 2.

Kinetics of Tryptophan Photo-Oxidation
The study of the activity of porphyrin-containing polymer systems during the generation of singlet oxygen in the aqueous phase was carried out using the reaction of oxidation of tryptophan with singlet oxygen with the formation of tryptophan endoperoxide ( Figure 3). Photosensitizing double systems (PS-AP and PS-CT100) with water-soluble PSs were prepared by mixing solutions of porphyrin and polymer or chitosan (in 0.2% acetic acid) for 10 min. [24]. To obtain ternary systems (PS-AP-CT100), porphyrin solutions were first mixed with an amphiphilic polymer for 10 min at room temperature, then a chitosan solution was added and mixed for another 10 min [24]. Solubilization of hydrophobic porphyrins was carried out according to the procedure described in [25]. The PS concentration is 5× 10 −6 M. The AP concentrations varied from 5× 10 −6 M to 5× 10 −4 M; the concentration of CT100 varied from 1× 10 −4 M to 6× 10 −3 M (given per unit).
Photo-oxidation of tryptophan (Trp) with molecular oxygen dissolved in water was carried out in a 1 cm thick quartz cell at room temperature. The concentration of tryptophan is 10 4 M. The kinetics of the process was monitored by the change in concentration of tryptophan, which was determined from the optical density value of the absorption band (λ = 280 nm) in the UV spectrum of tryptophan. Photosensitizing double systems (PS-AP and PS-CT 100 ) with water-soluble PSs were prepared by mixing solutions of porphyrin and polymer or chitosan (in 0.2% acetic acid) for 10 min. [23]. To obtain ternary systems (PS-AP-CT 100 ), porphyrin solutions were first mixed with an amphiphilic polymer for 10 min at room temperature, then a chitosan solution was added and mixed for another 10 min [23]. Solubilization of hydrophobic porphyrins was carried out according to the procedure described in [24]. The PS concentration is 5 × 10 −6 M. The AP concentrations varied from 5 × 10 −6 M to 5 × 10 −4 M; the concentration of CT 100 varied from 1 × 10 −4 M to 6 × 10 −3 M (given per unit).
Photo-oxidation of tryptophan (Trp) with molecular oxygen dissolved in water was carried out in a 1 cm thick quartz cell at room temperature. The concentration of tryptophan is 10 4 M. The kinetics of the process was monitored by the change in concentration of tryptophan, which was determined from the optical density value of the absorption band (λ = 280 nm) in the UV spectrum of tryptophan.
For a comparative assessment of the activity of porphyrin-containing systems in the test reaction of photo-oxidation of tryptophan in an aqueous medium, the effective specific rate constant k eff , determined from the initial linear portion of the kinetic dependence C i = C i (t), was introduced: where C 0i is the initial concentration of substrate i, C i (t) is the concentration of substrate I at the time t (s) of photo-oxidation, C PPS is the concentration of photosensitizer. The measurement error in determining k eff was 10%. The UV spectra and electronic absorption spectra (EAS) of the solutions were recorded on a Cary50 spectrophotometer (Varian, Mulgrave, VIC, Australia); the fluorescence spectra were recorded on a Cary Eclipse spectrofluorimeter (Varian, Mulgrave, VIC, Australia).

Dynamic Light Scattering
The particle size and Zeta potential of polymers (AP and CT 100 ) and TPPF20 solubilized by F127 in aqueous solutions in the initial state and in the ternary systems (TPPF20-F127-CT 100 ) systems was determined by dynamic and electrophoretic light scattering on a Malvern Zetasizer Nano ZS (Malvern Instruments Ltd., Malvern, UK), equipped with a He-Ne laser (λ = 633 nm) at an angle of 173 • . ξ-potential was measured with laser Doppler velocimetry by determining the electrophoretic mobility. The Henry equation was used for calculation of ξ-potential values. A dielectric constant of 78.5 and a viscosity of 0.8872 mPa·s for pure solvent were used for all systems taking into account the low polymer concentration. The solutions were filtered through a standard 0.22 µm membrane into an optical cell (1 × 1 cm 2 ). Data were processed using Zetasizer Software 6.2 (Malvern Instruments Ltd., Malvern, UK).

X-ray Diffraction
X-ray diffraction study of polymeric films was carried out in the Institute of Biochemical Physics using X-ray diffractometer with position-sensitive detector of local design described elsewhere [25] (CuKα radiation, sample to detector distance 105 mm, the width of X-ray beam and detector window 4 mm). The intensity of X-ray scattering was measured in transmission geometry in the range of diffraction vector module 0.04 nm −1 < S < 4.5 nm −1 (S = 2sinθ/λ, 2θ-scattering angle, λ-X-ray wavelength, equal for CuKα radiation to 0.1542 nm). The films were obtained according to the method described in [26]; the mass ratio of the components in the CT 100 -PVP film was 1:2 and 1:5, while for the ternary system DMG-PVP-CT 100 the same ratio was 1:5:10.

Atomic Force Microscopy
The study of the surface structure of polymer films by atomic force microscopy (AFM) was carried out on a MultiMode 8 atomic force microscope (Bruker, Santa Barbara, CA, USA) using an RTESPA-300 probe (Bruker, Santa Barbara, CA, USA). The surface topography of polymer films, as well as their local mechanical properties (Young's modulus), were studied using the PeakForce QNM method. Sreas of 5 × 5 µm 2 were investigated. The films were obtained according to the method described in [26]; the mass ratio of the components in the CT 100 -PVP film was 1:1 and 1:2.

Photocatalytic Activity of Water-Soluble PS
As follows from Figure 4, the solubilization of porphyrins with Pluronic F127 and PVP made it possible to weaken the effect of CT 100 on the photocatalytic activity of water-soluble porphyrins. It should be noted that in the presence of CT 100 , the photocatalytic activity of pure DMG and Ce6 decreases by a factor of 4 and 2, respectively ( Figure 4a Figure 4a) approach the values of k eff for the corresponding binary system DMG-PVP. Thereby, when PVP is added to the DMG-CT 100 system, a significant (4-5 times) increase in the effective constant k eff of the photo-oxidation rate of tryptophan is observed (Figure 4a), which is apparently associated with the partial binding of porphyrin molecules, that were previously localized in the aggregated state near the amino groups of chitosan, with polyvinylpyrrolidone macromolecules. From the literature it follows that the supramolecular structure of chitosan in solutions, which possibly determines the functional activity of the polysaccharide, depends on its molecular weight and the degree of deacetylation [27,28]. Since the values of the degree of deacetylation for CT 20 and CT 100 are close, it is obvious that the conformation of chitosan under the conditions of our experiments is determined by its molecular weight. According to [29] low molecular weight chitosan in weakly acidic solutions is present both in the form of aggregates of macromolecules, in which amino groups (responsible for PS binding) are involved in the formation of intermolecular hydrogen bonds, and in the form of free macromolecules capable of interacting with PS. Such interaction, according to [22], when using chitosan with M = 20 kDa, cannot be completely eliminated even in the presence of high concentrations of PVP. The supramolecular structure of chitosan with higher molecular weight in weakly acidic solutions is a flexible worm-like chain [28,30]. This structure is supported by electrostatic, hydrogen and hydrophobic bonds, in which amino groups are involved. In this case, the addition of PVP to the DMG-CT 100 system makes it possible to almost completely eliminate the interaction of porphyrin with CT 100 and to increase the photocatalytic activity of the system. This is indicated, among other things, by an increase in the intensity of all fluorescence bands in the spectra of the DMG-CT 100 systems upon the addition of PVP ( Figure 5a).
As seen from Figure 4b, the solubilization of DMG with Pluronic F127 is less effective and does not completely prevent the interaction of CT 100 with porphyrin in the DMG-F127-CT 100 system. When Pluronic is used as an AP, the activity of the DMG-F127-CT 100 system increases slightly (Figure 4b) above the level of free DMG. This difference is primarily due to the presence of 0.2% acetic acid (a solvent of chitosan) in the solution, which affects the supramolecular structure of F127 in solution. It is important to note here that the supramolecular structure of PVP is practically independent of the pH of the medium [31]. We have shown that the photocatalytic activity of DMG-F127 complexes in acetic acid drops sharply [32]. This effect is associated with the aggregation of Pluronic micelles in an acidic medium [33], which leads to an increase in the size of polymer associates and compaction of micelles. It can be assumed that as a result of such processes, the formation of pseudopolycation of Pluronic occurs, which leads to the aggregation of PS and a decrease in the values of the effective rate constant k eff of substrate oxidation. proach the values of keff for the corresponding binary system DMG-PVP. Thereby, when PVP is added to the DMG-CT100 system, a significant (4-5 times) increase in the effective constant keff of the photo-oxidation rate of tryptophan is observed (Figure 4a), which is apparently associated with the partial binding of porphyrin molecules, that were previously localized in the aggregated state near the amino groups of chitosan, with polyvinylpyrrolidone macromolecules. From the literature it follows that the supramolecular structure of chitosan in solutions, which possibly determines the functional activity of the polysaccharide, depends on its molecular weight and the degree of deacetylation [28,29].
Since the values of the degree of deacetylation for CT20 and CT100 are close, it is obvious that the conformation of chitosan under the conditions of our experiments is determined by its molecular weight. According to [30] low molecular weight chitosan in weakly acidic solutions is present both in the form of aggregates of macromolecules, in which amino groups (responsible for PS binding) are involved in the formation of intermolecular hydrogen bonds, and in the form of free macromolecules capable of interacting with PS. Such interaction, according to [23], when using chitosan with M = 20 kDa, cannot be completely eliminated even in the presence of high concentrations of PVP. The supramolecular structure of chitosan with higher molecular weight in weakly acidic solutions is a flexible worm-like chain [29,31]. This structure is supported by electrostatic, hydrogen and hydrophobic bonds, in which amino groups are involved. In this case, the addition of PVP to the DMG-CT100 system makes it possible to almost completely eliminate the interaction of porphyrin with CT100 and to increase the photocatalytic activity of the system. This is indicated, among other things, by an increase in the intensity of all fluorescence bands in the spectra of the DMG-CT100 systems upon the addition of PVP (Figure 5a).   As seen from Figure 4b, the solubilization of DMG with Pluronic F127 is less effective and does not completely prevent the interaction of CT100 with porphyrin in the DMG-F127-CT100 system. When Pluronic is used as an AP, the activity of the DMG-F127-CT100 system increases slightly (Figure 4b) above the level of free DMG. This difference is primarily due to the presence of 0.2% acetic acid (a solvent of chitosan) in the solution, which affects the supramolecular structure of F127 in solution. It is important to note here that the supramolecular structure of PVP is practically independent of the pH of the medium [32]. We have shown that the photocatalytic activity of DMG-F127 complexes in acetic acid drops sharply [33]. This effect is associated with the aggregation of Pluronic micelles in an acidic medium [34], which leads to an increase in the size of polymer associates and compaction of micelles. It can be assumed that as a result of such processes, the formation of pseudo-   As seen from Figure 4b, the solubilization of DMG with Pluronic F127 is less effective and does not completely prevent the interaction of CT100 with porphyrin in the DMG-F127-CT100 system. When Pluronic is used as an AP, the activity of the DMG-F127-CT100 system increases slightly (Figure 4b) above the level of free DMG. This difference is primarily due to the presence of 0.2% acetic acid (a solvent of chitosan) in the solution, which affects the supramolecular structure of F127 in solution. It is important to note here that the supramolecular structure of PVP is practically independent of the pH of the medium [32]. We have shown that the photocatalytic activity of DMG-F127 complexes in acetic acid drops sharply [33]. This effect is associated with the aggregation of Pluronic micelles in an acidic medium [34], which leads to an increase in the size of polymer associates and compaction of micelles. It can be assumed that as a result of such processes, the formation of pseudo- For Ce6-CT 100 , a similar dependence of the effective rate constant of tryptophan oxidation k eff on the PVP concentration was obtained, which takes the form of curves with a maximum at a PVP concentration of 5 × 10 −5 M (Figure 4c, curve 2) and is similar to the dependence in the absence of CT 100 (Figure 4c, curve 1). In this case, the addition of PVP to the Ce6-CT 100 system also increases the photocatalytic activity, but the k eff values do not reach the k eff values of the Ce6-PVP binary system. It is interesting to note that the addition of Pluronic F127 to the Ce6-CT 100 system does not change its photocatalytic activity (Figure 4d, curve 2), which is due to the fact that Ce6 is a more hydrophilic porphyrin than DMG and is localized at the edge of the F127 micelle [19] and, apparently, even in the presence of Pluronic, it is prone to aggregation near the amino groups of chitosan. Aggregation is indicated, among other things, by a decrease in the intensity of the band in fluorescence spectra of the Ce6-CT 100 systems upon the addition of F127 (Figure 5b, curve 4).

Photocatalytic Properties of Hydrophobic PS
We have previously shown that solubilization of TPP and its analogs with amphiphilic polymers (AP), such as pluronics (ternary block copolymers of ethylene oxide and propylene oxide), polyethylene oxide and PVP, makes it possible to obtain effective water-soluble photosensitizers for the generation of singlet oxygen [24]. Figure 6 demonstrates the dependences of k eff of the photo-oxidation rate of tryptophan in the presence of TPPF20 (a) and TPP (b), solubilized by Pluronic and the dependence of their ternary systems with chitosan on the concentration of Pluronic F127. It can be seen that in the case of TPPF20-F127 systems, the addition of chitosan (Figure 6a, curves 2-4) leads to an increase in photocatalytic activity by a factor of 1.1-1.3 compared to the activity of TPPF20 solubilized by Pluronic F127 in acidic or neutral media. This growth is primarily associated with the effect of acetic acid on the activity of porphyrins (see curve 1 (neutral medium) and curve A (0.2% CH 3 COOH), Figure 6a). In the case of hydrophobic TPP solubilized with F127, k eff does not change neither in the presence of CT 100 (Figure 6b, curves 2-4) nor in the presence of acid (Figure 6b, curve A).
dependence in the absence of CT100 (Figure 4c curve 1). In this case, the addition of PVP to the Ce6-CT100 system also increases the photocatalytic activity, but the keff values do not reach the keff values of the Ce6-PVP binary system. It is interesting to note that the addition of Pluronic F127 to the Ce6-CT100 system does not change its photocatalytic activity ( Figure  4d, curve 2), which is due to the fact that Ce6 is a more hydrophilic porphyrin than DMG and is localized at the edge of the F127 micelle [20] and, apparently, even in the presence of Pluronic, it is prone to aggregation near the amino groups of chitosan. Aggregation is indicated, among other things, by a decrease in the intensity of the band in fluorescence spectra of the Ce6-CT100 systems upon the addition of F127 (Figure 5b, curve4).

Photocatalytic Properties of Hydrophobic PS
We have previously shown that solubilization of TPP and its analogs with amphiphilic polymers (AP), such as pluronics (ternary block copolymers of ethylene oxide and propylene oxide), polyethylene oxide and PVP, makes it possible to obtain effective water-soluble photosensitizers for the generation of singlet oxygen [25]. Figure 6 demonstrates the dependences of keff of the photo-oxidation rate of tryptophan in the presence of TPPF20 (a) and TPP (b), solubilized by Pluronic and the dependence of their ternary systems with chitosan on the concentration of Pluronic F127. It can be seen that in the case of TPPF20-F127 systems, the addition of chitosan (Figure 6a, curves 2-4) leads to an increase in photocatalytic activity by a factor of 1.1-1.3 compared to the activity of TPPF20 solubilized by Pluronic F127 in acidic or neutral media. This growth is primarily associated with the effect of acetic acid on the activity of porphyrins (see curve 1 (neutral medium) and curve A (0.2% CH3COOH), Figure 6a). In the case of hydrophobic TPP solubilized with F127, keff does not change neither in the presence of CT100 (Figure 6b Such differences in the photosensitizing properties of hydrophobic PSs can be associated with different degrees of aggregation of solubilized tetraphenylporphyrins. Thus, for solubilized TPPF20, the maximum activity is achieved at F127 concentration of 5 × 10 −5 M (Figure 6a, curve 1), while for solubilized TPP, this happens at Pluronic concentrations of 5 × 10 −4 M-1 × 10 −3 M (Figure 6b, curve 1). Thus, TPPF20 is less aggregated and therefore more evenly distributed over Pluronic micelles. Apparently, the reason for the lower aggregation of TPPF20 during solubilization is the presence of fluorine atoms, which provide better binding to Pluronic. According to Bin Yang et al., in case of Pluronic, low pH values of the medium cause aggregation of F127 micelles, i.e., micelles "stick together" through the bridges from protonated water molecules, which leads to an increase in the size of polymer associates and to the compaction of micelles [33]. In this case, such "sticking" leads to the effective concentration of TPPF20 and the substrate within the sticky micelles and a certain increase in activity. Whereas in the case of TPP (less disaggregated in compar-ison with TPPF20), the interaction of micelles does not lead to effective concentration of PS. On the contrary, when PS-unfilled micelles "stick together", the substrate is spatially distant from PS, which is observed at high AP concentrations. The invariability of the state of PS themselves is confirmed by the unchanged fluorescence spectra of solubilized tetraphenylporphyrins upon addition of chitosan (Figure 7). lower aggregation of TPPF20 during solubilization is the presence of fluorine atoms, which provide better binding to Pluronic. According to Bin Yang et al., in case of Pluronic, low pH values of the medium cause aggregation of F127 micelles, i.e., micelles "stick together" through the bridges from protonated water molecules, which leads to an increase in the size of polymer associates and to the compaction of micelles [34]. In this case, such "sticking" leads to the effective concentration of TPPF20 and the substrate within the sticky micelles and a certain increase in activity. Whereas in the case of TPP (less disaggregated in comparison with TPPF20), the interaction of micelles does not lead to effective concentration of PS. On the contrary, when PS-unfilled micelles "stick together", the substrate is spatially distant from PS, which is observed at high AP concentrations. The invariability of the state of PS themselves is confirmed by the unchanged fluorescence spectra of solubilized tetraphenylporphyrins upon addition of chitosan (Figure 7).

Methods for Studying Supramolecular Interactions in the PS-AP-CT100 System
To predict the nature of interactions between the components of the PS-AP-CT100 system in solution, ξ-potentials of individual F127 and CT100, as well as TPPF20 solubilized by F127, in the absence and presence of CT100 were measured. Table 1 demonstrates that F127 in a neutral solution is characterized by a low negative value of the ξ-potential (-8 mV). In an acetic acid solution, the ξ-potential of F127 remains low; however, its sign changes to the opposite (+5 mV), which confirms the formation of the pseudo-polycation of Pluronic micelles in acetic acid. Chitosan molecules with a high degree of deacetylation in an acidic medium are characterized by a high positive charge due to protonation of amino groups (+53 mV). Micelles TPPF20-F127 have a small positive charge (+4 mV), which practically corresponds to the charge of F127 in an acidic solution. In the ternary system TPPF20-F127-CT100, the value of the ξ-potential is +36 mV, which is significantly lower than that of free chitosan. This effect may indicate the interaction of chitosan with TPPF20+F127 micelles (1%). It is unlikely that this interaction is of an electrostatic nature, since the components have the same charge. It is most likely that the interaction is of a hydrophobic nature (the available hydrophobic surface of the chitosan molecule is ≈50%),

Methods for Studying Supramolecular Interactions in the PS-AP-CT 100 System
To predict the nature of interactions between the components of the PS-AP-CT 100 system in solution, ξ-potentials of individual F127 and CT 100 , as well as TPPF20 solubilized by F127, in the absence and presence of CT 100 were measured. Table 1 demonstrates that F127 in a neutral solution is characterized by a low negative value of the ξ-potential (−8 mV). In an acetic acid solution, the ξ-potential of F127 remains low; however, its sign changes to the opposite (+5 mV), which confirms the formation of the pseudo-polycation of Pluronic micelles in acetic acid. Chitosan molecules with a high degree of deacetylation in an acidic medium are characterized by a high positive charge due to protonation of amino groups (+53 mV). Micelles TPPF20-F127 have a small positive charge (+4 mV), which practically corresponds to the charge of F127 in an acidic solution. In the ternary system TPPF20-F127-CT 100 , the value of the ξ-potential is +36 mV, which is significantly lower than that of free chitosan. This effect may indicate the interaction of chitosan with TPPF20+F127 micelles (1%). It is unlikely that this interaction is of an electrostatic nature, since the components have the same charge. It is most likely that the interaction is of a hydrophobic nature (the available hydrophobic surface of the chitosan molecule is ≈50%), and the decrease in surface charge of the interaction product is due to the rearrangement of the surface of micelle.
As can be seen from Figure 8, for TPPF20 solubilized with F127 in the presence of CT 100 , there is a change in the characteristic sizes of porphyrin associates (Table 1, line 9, 10). As shown above, such changes can be associated with the interaction of Pluronic micelles with chitosan macromolecules. It is obvious that the presence of hydrophobic PSs in Pluronic micelles promotes the interaction of micelles with chitosan macromolecules, most likely due to hydrophobic interactions. The relative measurement error was no more than 5%.
As can be seen from Figure 8, for TPPF20 solubilized with F127 in the presence of CT100, there is a change in the characteristic sizes of porphyrin associates (Table 1, line 9, 10). As shown above, such changes can be associated with the interaction of Pluronic micelles with chitosan macromolecules. It is obvious that the presence of hydrophobic PSs in Pluronic micelles promotes the interaction of micelles with chitosan macromolecules, most likely due to hydrophobic interactions. The size of chitosan associates in a 0.2% acetic acid solution in the presence and absence of AP and PS was also studied by the method of dynamic light scattering (Table 1). It was found that the sizes of AP associates in a joint solution of AP and CT100 remain unchanged (Table 1, line 1, 6, 7 and line 4,6,8). In this case, the size of CT100 associates increases in a joint solution with AP, which is associated with the "salting out" effect. The size of chitosan associates in a 0.2% acetic acid solution in the presence and absence of AP and PS was also studied by the method of dynamic light scattering (Table 1). It was found that the sizes of AP associates in a joint solution of AP and CT 100 remain unchanged (Table 1, line 1, 6, 7 and line 4,6,8). In this case, the size of CT 100 associates increases in a joint solution with AP, which is associated with the "salting out" effect. From the data obtained, it follows that the interactions between AP and CT 100 in a 0.2% acetic acid solution are negligible.
To identify interactions in PS-AP-CT 100 systems, where water-soluble dimegin acted as PS, AFM and XRD studies were carried out. The methods of preparing films for XRD and AFM studies are given in the Materials and Methods section. X-ray diffraction data indicate that chitosan and PVP in films obtained by evaporation of acetic acid aqueous solutions containing both of these polymers form two separate polymer phases ( Figure 9) and DMG can be localized in significant amounts in a finely dispersed form in the PVP phase, leading to small changes in the structure of PVP ( Figure 10).
To identify interactions in PS-AP-CT100 systems, where water-soluble dimegin acted as PS, AFM and XRD studies were carried out. The methods of preparing films for XRD and AFM studies are given in the Materials and Methods section. X-ray diffraction data indicate that chitosan and PVP in films obtained by evaporation of acetic acid aqueous solutions containing both of these polymers form two separate polymer phases ( Figure 9) and DMG can be localized in significant amounts in a finely dispersed form in the PVP phase, leading to small changes in the structure of PVP ( Figure 10). Figure 9. Experimental X-ray diffraction pattern of a chitosan-PVP film (1) with a mass ratio of these polymers of 1:2 and a model X-ray diffraction pattern of such film (2) obtained by summation of X-ray scattering intensity of chitosan and PVP films taken in a 1:2 proportion. Logarithmic scale along the abscissa axis. The presence of two polymer phases in films obtained from joint solutions of chitosan and PVP was also confirmed by the AFM method. The local mechanical characteristics (deformation, Young's modulus and adhesion) of films of a mixture of chitosan polymers and PVP with a thickness of 100 nm were measured in 5 × 5 μm areas in the PeakForce QNM mode. Microinhomogeneities are formed on the surface of thick films of binary mixtures, and phase separation is observed on a nanoscale ( Figure 11). It turned out that the Figure 9. Experimental X-ray diffraction pattern of a chitosan-PVP film (1) with a mass ratio of these polymers of 1:2 and a model X-ray diffraction pattern of such film (2) obtained by summation of X-ray scattering intensity of chitosan and PVP films taken in a 1:2 proportion. Logarithmic scale along the abscissa axis.
acetic acid solution are negligible.
To identify interactions in PS-AP-CT100 systems, where water-soluble dimegin acted as PS, AFM and XRD studies were carried out. The methods of preparing films for XRD and AFM studies are given in the Materials and Methods section. X-ray diffraction data indicate that chitosan and PVP in films obtained by evaporation of acetic acid aqueous solutions containing both of these polymers form two separate polymer phases ( Figure 9) and DMG can be localized in significant amounts in a finely dispersed form in the PVP phase, leading to small changes in the structure of PVP ( Figure 10). Figure 9. Experimental X-ray diffraction pattern of a chitosan-PVP film (1) with a mass ratio of these polymers of 1:2 and a model X-ray diffraction pattern of such film (2) obtained by summation of X-ray scattering intensity of chitosan and PVP films taken in a 1:2 proportion. Logarithmic scale along the abscissa axis. The presence of two polymer phases in films obtained from joint solutions of chitosan and PVP was also confirmed by the AFM method. The local mechanical characteristics (deformation, Young's modulus and adhesion) of films of a mixture of chitosan polymers and PVP with a thickness of 100 nm were measured in 5 × 5 μm areas in the PeakForce QNM mode. Microinhomogeneities are formed on the surface of thick films of binary mixtures, and phase separation is observed on a nanoscale ( Figure 11). It turned out that the The presence of two polymer phases in films obtained from joint solutions of chitosan and PVP was also confirmed by the AFM method. The local mechanical characteristics (deformation, Young's modulus and adhesion) of films of a mixture of chitosan polymers and PVP with a thickness of 100 nm were measured in 5 × 5 µm 2 areas in the PeakForce QNM mode. Microinhomogeneities are formed on the surface of thick films of binary mixtures, and phase separation is observed on a nanoscale ( Figure 11). It turned out that the local mechanical characteristics of the film surface in microinhomogeneities differ, which indicates the presence of two phases. Young's modulus value for the soft phase was 1.8 GPa, while for the harder phase it was 2.4 GPa. For the film obtained from the acetic acid solution of chitosan, Young's modulus was 2.4 GPa, which corresponds to the value of Young's modulus of the harder phase of the polymer mixture film. local mechanical characteristics of the film surface in microinhomogeneities differ, which indicates the presence of two phases. Young's modulus value for the soft phase was 1.8 GPa, while for the harder phase it was 2.4 GPa. For the film obtained from the acetic acid solution of chitosan, Young's modulus was 2.4 GPa, which corresponds to the value of Young's modulus of the harder phase of the polymer mixture film.

Conclusions
It was shown that photosensitizing systems based on water-soluble porphyrins and polyvinylpyrrolidone in the presence of chitosan (molecular weight ~ 100 kDa) exhibit high photocatalytic activity, reaching the corresponding values observed for binary PS-AP systems. Hydrophobic porphyrins (TPP and TPPF20), solubilized by Pluronic F127, showed a higher efficiency in the generation of singlet oxygen (in the process of photooxidation of tryptophan) in the presence of chitosan (Mw ~ 100 kDa), than in its absence. According to AFM and X-ray data, chitosan and amphiphilic polymer form separate phases in solid films. Different methods, such as DLS in solution, AFM and XRD in solid films confirmed that CT100 does not interact with amphiphilic polymers F127 and PVP. At the same time, according to X-ray diffraction data for the DMG-PVP-CT100 systems, dimegin was localized in a finely dispersed state in the PVP phase.

Data Availability Statement:
The data presented in this study are available on request from the corresponding author.