Pillararenes as Promising Carriers for Drug Delivery

Since their discovery in 2008 by N. Ogoshi and co-authors, pillararenes (PAs) have become popular hosts for molecular recognition and supramolecular chemistry, as well as other practical applications. The most useful property of these fascinating macrocycles is their ability to accommodate reversibly guest molecules of various kinds, including drugs or drug-like molecules, in their highly ordered rigid cavity. The last two features of pillararenes are widely used in various pillararene-based molecular devices and machines, stimuli-responsive supramolecular/host–guest systems, porous/nonporous materials, organic–inorganic hybrid systems, catalysis, and, finally, drug delivery systems. In this review, the most representative and important results on using pillararenes for drug delivery systems for the last decade are presented.

The application of PAs as carriers for the targeted drug delivery systems is of particular interest [46][47][48], as, depending on the structure of PA-based carriers, disease type, and the nature of the drug, various factors for the drug activation/release can be utilized, such Wheat and co-authors described carboxylated P6As and P7As as hosts for various guests, such as memantine, chlorhexidine hydrochloride, and proflavine, to study the possible application of these PAs for drug delivery and biodiagnostic applications [68] (Figure 2).  Wheat and co-authors described carboxylated P6As and P7As as hosts for various guests, such as memantine, chlorhexidine hydrochloride, and proflavine, to study the possible application of these PAs for drug delivery and biodiagnostic applications [68]    The authors claimed that both PAs were able to form host-guest complexes with small guest molecules/drugs, and this was confirmed by means of 1 H NMR and theoretical modeling experiments. The encapsulation is promoted by the suitable cavity size along with the combinations of hydrophobic effects, hydrogen bonding, and electrostatic interactions at the portals. Based on the theoretical calculations and docking experiment, proflavine and P7A2 form a 2:1 host-guest complex with a binding affinity of −10.1 kcal/mol, while, with other guests, both PAs formed 1:1 inclusion complexes with binding affinity values varying from −2.9 to −8.9 kcal/mol. In addition, for the fluorescent proflavine, its encapsulation by P6A2 resulted in dramatic fluorescence quenching (a static quenching mechanism was suggested), and the observed fluorescence on/off were usable for biodiagnostics purposes.
In addition, the toxicity of P6As and P7As was examined using in vitro growth assays with the human embryonic kidney (HEK) cell line HEK293 and the human ovarian carcinoma cell line OVCAR3. According to the authors, both PAs are relatively nontoxic to the cells, although they inhibit proliferation at high doses (500 mM) and at extended time periods (over 78 h). Based on all information mentioned above, P6-7A1-2 may have an application in drug delivery.
Stoikov et al. reported synthesis of water-soluble cationic pillar [5]arenes P5A1-2 and studies of their inclusion complexes with p-toluenesulfonic acid (pTSA) [69] (Figure 3). The formation of a 1:1 "P5A*pTSA" inclusion complex was confirmed based on the data of 1D 1 H and 2D NMR spectroscopy and UV spectroscopy. The logK ass values of the complexes P5A1 and P5A2 with pTSA were 1.22 ± 0.08 and 1.43 ± 0.12, respectively. Owing to the ability of cationic PAs to inhibit biofilm formation reported by the authors, P5As may be used as possible carriers for the transport of the simplest antibiotics derived from pTSA, such as sulfanilamide (pTSAm) [70].
small guest molecules/drugs, and this was confirmed by means of 1 H NMR and theoretical modeling experiments. The encapsulation is promoted by the suitable cavity size along with the combinations of hydrophobic effects, hydrogen bonding, and electrostatic interactions at the portals. Based on the theoretical calculations and docking experiment, proflavine and P7A2 form a 2:1 host-guest complex with a binding affinity of −10.1 kcal/mol, while, with other guests, both PAs formed 1:1 inclusion complexes with binding affinity values varying from −2.9 to −8.9 kcal/mol. In addition, for the fluorescent proflavine, its encapsulation by P6A2 resulted in dramatic fluorescence quenching (a static quenching mechanism was suggested), and the observed fluorescence on/off were usable for biodiagnostics purposes. In addition, the toxicity of P6As and P7As was examined using in vitro growth assays with the human embryonic kidney (HEK) cell line HEK293 and the human ovarian carcinoma cell line OVCAR3. According to the authors, both PAs are relatively nontoxic to the cells, although they inhibit proliferation at high doses (500 mM) and at extended time periods (over 78 h). Based on all information mentioned above, P6-7A1-2 may have an application in drug delivery.
Stoikov et al. reported synthesis of water-soluble cationic pillar [5]arenes P5A1-2 and studies of their inclusion complexes with p-toluenesulfonic acid (pTSA) [69] (Figure 3). The formation of a 1:1 "P5A*pTSA" inclusion complex was confirmed based on the data of 1D 1 H and 2D NMR spectroscopy and UV spectroscopy. The logKass values of the complexes P5A1 and P5A2 with pTSA were 1.22 ± 0.08 and 1.43 ± 0.12, respectively. Owing to the ability of cationic PAs to inhibit biofilm formation reported by the authors, P5As may be used as possible carriers for the transport of the simplest antibiotics derived from pTSA, such as sulfanilamide (pTSAm) [70]. It is known that some bacteria such as Methicillin-resistant S. aureus (MRSA), by means of invading and colonizing inside phagocytes such as macrophages, can develop self-protection mechanisms to protect themselves against antibiotics, as well as to escape from host phagocytosis. In attempts to discover advanced therapeutics for bacterial infections and cancers, Xie, He, and co-authors reported self-assembled architectures of amphiphilic P5As (Man@AP5) with encapsulated vancomycin ("Man@AP5*Van") [71] (Figure 4). It is known that some bacteria such as Methicillin-resistant S. aureus (MRSA), by means of invading and colonizing inside phagocytes such as macrophages, can develop selfprotection mechanisms to protect themselves against antibiotics, as well as to escape from host phagocytosis. In attempts to discover advanced therapeutics for bacterial infections and cancers, Xie, He, and co-authors reported self-assembled architectures of amphiphilic P5As (Man@AP5) with encapsulated vancomycin ("Man@AP5*Van") [71] (Figure 4).
To target macrophages, which express high levels of mannose receptors [72], mannose moieties were introduced into P5As. Man@AP5 self-assembles to form a vesicle that encapsulates Van ("Man@AP5*Van"). The authors claimed that, inside the macrophages, "Man@AP5*Van" protonation takes place, and the Phe-Lys linker is cleaved by cathepsin B in the lysosome [73]. The photolysis of the "Man@AP5*Van" vesicle results in its degradation and release of Van to effectively inhibit intracellular MRSA growth ( Figure 2). According to the authors, the main advantages of Man@AP5 vesicles for Van delivery are (1) macrophage targeting for antibiotic accumulation with reduced side effects; (2) pH and cathepsin B dual responsivity for rapid drug release; (3) good biocompatibility and biodegradability. Van was selected by the authors owing to its high efficiency for the treatment of bacterial infections. Due to poor intracellular antibacterial activity [74] and low uptake by infected host cells, Van could be used to treat intracellular staphylococcal infections only at a high concentration (100 mg·mL −1 ), and it exhibited no significant activity against intracellular MRSA at low concentrations. Along with the mannose-substituted P5As "Man@AP5*Van", for the Van loading efficiency, PEG-substituted P5A-based vesicles were used ("mPEG@AP5*Van"), and the drug-loading efficiency of Van-loaded Man@AP5 ("Man@AP5*Van") or Van-loaded "mPEG@AP5" ("mPEG@AP5*Van") was 41.6% or 34.1% with the drug loading content of 25% or 25.4%, respectively. The encapsulation of Van by the Man@AP5 and mPEG@AP5 vesicles was confirmed by the data of transmission electron microscopes (TEM) ("Man@AP5*Van" and "mPEG@AP5*Van" vesicles showed darker interiors and were larger than the blank vesicles) and by dynamic light scattering (DLS) experiments. The efficient extracellular release of Van from "Man@AP5*Van" and "mPEG@AP5*Van" vesicles in acidic media (99% for both at pH 5.0 for 5 h, and pH 6.0 for 7 h) and upon the exposure to different concentrations of cathepsin B (the amount of free Van from "Man@AP5*Van" reached a maximum of 99% with 2.5 mg·mL −1 of cathepsin B after 50 min, and 1.5 mg·mL −1 of cathepsin B after 80 min) or, at the faster rate, upon the combined treatment, was observed. These results suggested the high sensitivity of "Man@AP5*Van" vesicles to cathepsin B cleavage for rapid Van release. According to the results of studies of extracellular antibacterial activity of Van-loaded vesicles, "Man@AP5*Van" and "mPEG@AP5*Van" did not inhibit the growth of MRSA WHO-2 at the same Van concentration (5 mg·mL −1 ), while, in the presence of cathepsin B (1.5 mg·mL −1 ) or at the pH of 5.0, "Man@AP5*Van" and "mPEG@AP5*Van" exhibited comparable bacterial inhibition to free Van (5 mg·mL −1 ) after 24 h, supporting that Van release could be triggered by the acidic pH or cathepsin B. Finally, the ability of "Man@AP5*Van" and "mPEG@AP5*Van" to inhibit intracellular bacteria was studied by counting the CFU of surviving intracellular bacteria after incubating these vesicles with MRSA WHO-2 strain-infected Raw264.7 cells. "Man@AP5*Van" exhibited a significantly stronger inhibition compared to "mPEG@AP5-Van" or free Van, and this could be accounted for by its efficient Van delivery to and Van release in bacterial-infected Raw264.7 cells. In addition, upon the incubation of MRSA-infected macrophages with free Van, "Man@AP5*Van", or "mPEG@AP5*Van" at 10 mg mL −1 , the "Man@AP5*Van" exhibited better intracellular inhibitory activity compared to "mPEG@AP5*Van" or free Van. Based on all the above, the authors conclude that the "Man@AP5*Van" was the best delivery system for the Van   . Schematic illustration of a Van-loaded mannosylated vesicle (Man@AP5-Van) and its targeted uptake, transport, degradation, Van release, and bacterial inhibition. Reproduced with the permission of reference [71]. Copyright © Royal Society of Chemistry 2020.
To target macrophages, which express high levels of mannose receptors [72], mannose moieties were introduced into P5As. Man@AP5 self-assembles to form a vesicle that encapsulates Van ("Man@AP5*Van"). The authors claimed that, inside the macrophages, "Man@AP5*Van" protonation takes place, and the Phe-Lys linker is cleaved by cathepsin B in the lysosome [73]. The photolysis of the "Man@AP5*Van" vesicle results in its deg- Figure 4. Schematic illustration of a Van-loaded mannosylated vesicle (Man@AP5-Van) and its targeted uptake, transport, degradation, Van release, and bacterial inhibition. Reproduced with the permission of reference [71]. Copyright © Royal Society of Chemistry 2020. Yang, He, and co-authors reported P5A-based nanoparticles for targeted antibiotic delivery for treating methicillin-resistant S. aureus [75]. To do that, mannose-modified pillar [5]arene was assembled for the preparation of a glutathione (GSH)-responsive multifunctional antibiotic delivery system ("WP5A*G") based on the host-guest interaction between P5A and a near-infrared (NIR) fluorescence receptor (G), which was successfully developed. "WP5A*G" could encapsulate hydrophobic antibiotics such as linezolid (LZD) to form drug-loaded nanoparticles ("LZD*WP5A*G"), improving the anti-intracellular MRSA activity of LZD with excellent biocompatibility. This easily prepared and flexible system could be employed for simultaneous non-invasive cellular imaging and real-time monitoring of antibiotic release, representing a novel strategy toward targeted antibiotic delivery into macrophages for treating intracellular bacterial infections.
The "WP5A*LZD" vesicles exhibited GSH-triggered LZD release, with up to 90% release in 40 min at 3 mM concentration of GSH.

Pillararene-Based Systems for the Targeted Chemotherapy of Cancer
For various cancers, the tumor microenvironment is characterized by hypoxia-driven higher levels of ROS, such as hypochlorous acid (HOCl), hydrogen peroxide (H 2 O 2 ), hydroxyl radicals (OH•), and singlet oxygen ( 1 O 2 ) [76,77], higher pH (7.4) [76] or lower pH (pH 5.5-6.0 in endosomes and pH 4.5-5.0 in lysosomes of tumor cells) [78], and, finally, overexpressed endogenous thiols, including glutathione (GSH), thioredoxin (Trx), cysteine (Cys), hydrogen sulfide (H 2 S) with 2-3 orders of magnitude higher than the levels in the extracellular environments [76,79], polyamines [80], adenosine triphosphate (ATP) [81], etc. Therefore, by means of proper synthetic design, one can construct PA-based transport systems, which are able to properly encapsulate drug or prodrug cytotoxic molecules and release them selectively inside the tumor microenvironment. Below, the various PA-based anticancer drug carriers are analyzed and arranged based on the stimuli for drug release.

(Bio)thiol-Triggered Pillararene Drug Delivery Systems
Pei and co-authors reported a nano-drug delivery system based on the supramolecular assembly of P5A-based Se-Se-linked dimeric molecules (SeSe-(P5) 2 ) with encapsulated mannose-based guests (Man-NH 3 + ) [82,83] ( Figure 5). In H 2 O/THF (10:1) solution, "SeSe-(P5) 2 *Man-NH 3 +" forms glyco-nanovesicles, which was confirmed by SEM and TEM, with hollow spherical morphology. Upon incubation with HepG2 human hepatoma cells, MCF-7 breast cancer cells, and 293T healthy human cells, even in high concentrations (200 mg × mL −1 ), "SeSe-(P5) 2 *Man-NH 3 + " glyco-nanovesicles did not show any cytotoxic activity. After the loading of doxorubicin hydrochloride (DOX), the glycol-nanovesicles changed their morphology to irregular nanoparticles, which was confirmed by SEM. After being incubated with GSH (10 mM) under neutral conditions, the DOX incapsulated into glycol-nanovesicles was inappreciably released with the cumulative release amount of 13% within 72 h, and a 2.5 mM GSH cumulative release amount of 62% was detected. This confirms the ability of PA5-based glyco-nanovesicles for GSH-responsive DOX release in tumor microenvironments. In addition, the in vitro anticancer efficiency of the DOXloaded glyconanovesicles was investigated with respect to HepG2 and MCF-7, and, based on the data of MTT tests, these "SeSe-(P5) 2 *Man-NH 3 + " glyco-nanovesicles demonstrated good targeting ability and cytotoxic effect against cancer cells, along with reducing the toxicity to normal cells.
Wang and co-authors reported a similar approach and obtained P5A-containing nanoparticles by using disulphide-bridged P5A and poly(vinyl alcohol) (bis-P5A) [84] ( Figure 6). The obtained NPs were loaded with paclitaxel to form paclitaxel-loaded NPs, and the drug encapsulation efficiency (DEE) and drug loading efficiency (DLE) of PTX-NPs were determined to be 84.5% and 11.5%, respectively. In the presence and in the absence of biothiol, such as GSH (10 mM), PTX-NPs exhibited excellent stability, with accumulated PTX release of less than 17% after incubation for 86 h. Similarly, when incubated with a polyamine, such as spermine (SPM), which is overexpressed in several types of cancer cells (e.g., prostate cancer, lung cancer, and breast cancer), taken at the concentration of 1 mM, the PTX-NPs exhibited excellent stability, with less than 11% of accumulative drug release. Finally, in the presence of both 10 mM GSH and 1 mM SPM (both are present inside cancer cells such as lung cancer cells) the authors observed a cumulative drug release of up to 65% after incubation for 86 h. In the presence of GSH (1 mM) and SPM (0.1 mM), which are simulated concentrations in non-cancerous cells, the PTX-NPs demonstrated PTX release of 27%, which is relatively slow. In addition, more rapidly, PTX was released in the presence of both 10 mM GSH and 1 mM SPM, with the cumulative drug release amount of up to 65% after 86 h incubation. Finally, models for in vitro experiments overexpressing GSH and SPM cancer cells were taken, such as A549 human lung cancer cells, as well as L02 healthy human liver cells. According to the authors, L02 cells exhibited comparable cellular viabilities with respect to both PTX and PTX-NPs with the IC 50 (50% of cell growth inhibition concentration) values of 16.95 nM (PTX) and 16.47 nM (PTX-NPs), respectively, while in case of GSH-and SPM-overexpressed A549 cells, IC 50 values for free PTX (22.23 nM) were about 10 times higher compared to PTX-NPs (2.76 nM), which is probably due to the precisely selective release of PTX inside these cancer cells, and that results in significantly improved cell death via the apoptosis mechanism.

(Bio)thiol-Triggered Pillararene Drug Delivery Systems
Pei and co-authors reported a nano-drug delivery system based on the supramolecular assembly of P5A-based Se-Se-linked dimeric molecules (SeSe-(P5)2) with encapsulated mannose-based guests (Man-NH3 + ) [82,83] (Figure 5). In H2O/THF (10:1) solution, "SeSe-(P5)2*Man-NH3 +" forms glyco-nanovesicles, which was confirmed by SEM and TEM, with hollow spherical morphology. Upon incubation with HepG2 human hepatoma cells, MCF-7 breast cancer cells, and 293T healthy human cells, even in high concentrations (200 mg × mL −1 ), "SeSe-(P5)2*Man-NH3 + " glyconanovesicles did not show any cytotoxic activity. After the loading of doxorubicin hydro- cells, as well as L02 healthy human liver cells. According to the authors, L02 cells exhibited comparable cellular viabilities with respect to both PTX and PTX-NPs with the IC50 (50% of cell growth inhibition concentration) values of 16.95 nM (PTX) and 16.47 nM (PTX-NPs), respectively, while in case of GSH-and SPM-overexpressed A549 cells, IC50 values for free PTX (22.23 nM) were about 10 times higher compared to PTX-NPs (2.76 nM), which is probably due to the precisely selective release of PTX inside these cancer cells, and that results in significantly improved cell death via the apoptosis mechanism. The same group reported a P6A-supported dual prodrug guest (G) system, in which two different anticancer drugs, camptothecin (CPT) and chlorambucil (Cb), were connected via disulfide linker and assembled with a water-soluble PA6-based host to form a The same group reported a P6A-supported dual prodrug guest (G) system, in which two different anticancer drugs, camptothecin (CPT) and chlorambucil (Cb), were connected via disulfide linker and assembled with a water-soluble PA6-based host to form a hostguest complex in a ratio of 1:10 with the drug-loading content of 63.8% [85] (Figure 7). The host-guest interactions occurred between P6A3 and the Cb moiety of the guest, and were confirmed based on 1D 1 H NMR and 2D NOESY experiments. According to the DLS, P6A3 and G aggregate to form nanovesicles with an average hydrodynamic diameter of 143 nm with a narrow size distribution, while, based on atomic force microscopy (AFM) and TEM data, "P6A3*G" aggregates possess hollow spherical morphology with diameters ranging from 70 nm to 120 nm. It was said that, at the GSH concentration of 10 mM, the disulfide linker cleavage occurs with the drug release up to 95.1% over a period of 72 h at pH 7.4. In addition, no vesicle structure could be observed from the TEM image. In addition, based on in vitro studies, it was shown that this dual-drug-loaded system has a comparable antitumor activity toward MCF-7 cancer cells as a 1:1 mixture of CPT and Cb. Ma et al. described a glutathione-responsive drug delivery system based on watersoluble PA6-based substituted 12 disulfide-containing moieties bearing carboxylic acid terminal groups (SS-P6A) for improving aqueous solubility and enhancing binding affinity with cationic guests, such as anticancer drugs, amines, and thiols [86] (Figures 8 and 9).
In phosphate-buffered saline, these SS-P6A exhibited high binding affinity to DOX, irinotecan, and spermine with up to 10 5 M −1 association constants. For the (bio) thiols (DTT, cysteine and GSH) and amino acid lysine, two orders of magnitude lower binding constants were observed. In addition to DOX, guest molecule SS-PA6 was able to incapsulate two DOX prodrugs, PD1 and PD2, bearing acid-labile hydrazone linkers, and one or two hydrophobic alkyl chains, and, according to TEM and DLS, vesicle architectures with an average vesicle size for "SS-P6A*PD1" of 49 nm and 135 nm for "SS-P6A*PD2" with a wall thickness of 12.1 nm and 9.3 nm, respectively, were obtained. In addition to DOX-based molecules, hydrophobic drug camptothecin (CPT) or Nile Red dye were encapsulated by SS-P6A to form supramolecular vesicles, and, in the presence of GSH, an efficient guest release was observed. For the DOX-prodrugs-loaded SS-PA6, the authors observed a pH-triggered (pH = 4.0) DOX release, while negligible DOX release was observed at neutral pH. Finally, in vitro studies using HeLa cancer cells and normal Chang liver cells were carried out, and the ability of CPT-loaded SS-P6A for the GSH-mediated release of CPT in HeLa cancer cells and for DOX-loaded SS-P6A to release DOX in lysosomes via endosome/lysosome-mediated endocytosis was confirmed.
(AFM) and TEM data, "P6A3*G" aggregates possess hollow spherical morphology with diameters ranging from 70 nm to 120 nm. It was said that, at the GSH concentration of 10 mM, the disulfide linker cleavage occurs with the drug release up to 95.1% over a period of 72 h at pH 7.4. In addition, no vesicle structure could be observed from the TEM image. In addition, based on in vitro studies, it was shown that this dual-drug-loaded system has a comparable antitumor activity toward MCF-7 cancer cells as a 1:1 mixture of CPT and Cb.  In phosphate-buffered saline, these SS-P6A exhibited high binding affinity to DOX, irinotecan, and spermine with up to 10 5 M -1 association constants. For the (bio) thiols (DTT, cysteine and GSH) and amino acid lysine, two orders of magnitude lower binding constants were observed. In addition to DOX, guest molecule SS-PA6 was able to incapsulate two DOX prodrugs, PD1 and PD2, bearing acid-labile hydrazone linkers, and one or two hydrophobic alkyl chains, and, according to TEM and DLS, vesicle architectures

Hypoxia-Driven Drug Release Pillararene-Based Systems
Ling and co-authors reported a P6A-based theranostic system constructed by means of self-assembly between a water-soluble P6A3 and a chlorambucil-based azobenzenecontaining prodrug (Azo-G) and combination with glucose oxidase (GOx) to form nanoparticles GOx@NPs for the aim of hypoxic tumor diagnosis and controlled therapy [43] ( Figure 10). Figure 10. Fabrication of the hypoxia-activatable P6A3-based drug delivery system. Reproduced with the permission of reference [43]. Copyright © Royal Society of Chemistry 2022.

Hypoxia-Driven Drug Release Pillararene-Based Systems
Ling and co-authors reported a P6A-based theranostic system constructed by means of self-assembly between a water-soluble P6A3 and a chlorambucil-based azobenzene-containing prodrug (Azo-G) and combination with glucose oxidase (GOx) to form nanoparticles GOx@NPs for the aim of hypoxic tumor diagnosis and controlled therapy [43] (Figure 10).  . Schematic illustration for the formation of supramolecular vesicles and GSH/acid-induced sequential cargo release. Reproduced with the permission of reference [86]. Copyright © Elsevier 2022.

Hypoxia-Driven Drug Release Pillararene-Based Systems
Ling and co-authors reported a P6A-based theranostic system constructed by means of self-assembly between a water-soluble P6A3 and a chlorambucil-based azobenzenecontaining prodrug (Azo-G) and combination with glucose oxidase (GOx) to form nanoparticles GOx@NPs for the aim of hypoxic tumor diagnosis and controlled therapy [43] ( Figure 10). Figure 10. Fabrication of the hypoxia-activatable P6A3-based drug delivery system. Reproduced with the permission of reference [43]. Copyright © Royal Society of Chemistry 2022. Figure 10. Fabrication of the hypoxia-activatable P6A3-based drug delivery system. Reproduced with the permission of reference [43]. Copyright © Royal Society of Chemistry 2022.
According to the authors, under hypoxia microenvironment of the tumor cells, GOx@NPs released both the free chlorambucil to provide inhibition of tumor growth and free red fluorescence dye for the tumor imaging ( Figure 10). Thus, nanoparticles, GOx@NPs, were nontoxic with respect to HL-7702 cells (normal cells) in vitro, while they expressed remarkable proliferation inhibition abilities against HT-29 cancer cells. In addition, GOx@NPs provided excellent fluorescence diagnosis capability toward hypoxic tumor cells in vivo though selective activation in tumor microenvironment.

ATP-Triggered Drug Release Pillararene-Based Systems
Li, Meng, and co-authors reported an ATP-triggered P6A-based drug delivery system for smart cancer therapy [87] (Figure 11). To do that, water-soluble pillar [6]arene (P6A4) was assembled with sodium decanesulfonate guest (G) to form a host-guest assembly, which was confirmed by 1 H NMR. Upon addition of adenosine triphosphate (ATP), the competitive release of G from "G*P6A4" and ATP encapsulation was observed with an association value of 5.67 ± 0.31 × 10 5 M −1 . In aqueous solution, the formation of vesiclestructured aggregates was confirmed based on TEM and DLS, with a diameter of ∼100 nm (TEM) to 122.4 nM (DLS). Upon addition of DOX, the morphology and diameter of vesicles changed: based on TEM data, ∼150 nm nanoparticles with dark interiors were formed, and, based on DLS results, their average diameter was 164.2 nm. Within tumor cells, the ATP level is increased to 1-10 mM [88], vs. 1-10 nM in normal tissues [89,90]. To study DOX release, 10 nM and 10 mM ATP concentrations were used, and, at 10 nM ATP, the accumulated DOX release of less than 10% within 16 h vs. 85.1% accumulated DOX release at 10 mM ATP was observed, which was accompanied by an enhancement of the fluorescence of the solution due to free DOX presence. It is worth mentioning that, in in vitro experiments, in the absence of ATP, the "G*P6A4", even at high concentration, did not exhibit any cytotoxicity towards HepG-2 and LO2 cells. According to the authors, under hypoxia microenvironment of the tumor cells, GOx@NPs released both the free chlorambucil to provide inhibition of tumor growth and free red fluorescence dye for the tumor imaging ( Figure 10). Thus, nanoparticles, GOx@NPs, were nontoxic with respect to HL-7702 cells (normal cells) in vitro, while they expressed remarkable proliferation inhibition abilities against HT-29 cancer cells. In addition, GOx@NPs provided excellent fluorescence diagnosis capability toward hypoxic tumor cells in vivo though selective activation in tumor microenvironment.

ATP-Triggered Drug Release Pillararene-Based Systems
Li, Meng, and co-authors reported an ATP-triggered P6A-based drug delivery system for smart cancer therapy [87] (Figure 11). To do that, water-soluble pillar [6]arene (P6A4) was assembled with sodium decanesulfonate guest (G) to form a host-guest assembly, which was confirmed by 1 H NMR. Upon addition of adenosine triphosphate (ATP), the competitive release of G from "G*P6A4" and ATP encapsulation was observed with an association value of 5.67 ± 0.31 × 10 5 M -1 . In aqueous solution, the formation of vesicle-structured aggregates was confirmed based on TEM and DLS, with a diameter of ∼100 nm (TEM) to 122.4 nM (DLS). Upon addition of DOX, the morphology and diameter of vesicles changed: based on TEM data, ∼150 nm nanoparticles with dark interiors were formed, and, based on DLS results, their average diameter was 164.2 nm. Within tumor cells, the ATP level is increased to 1-10 mM [88], vs. 1-10 nM in normal tissues [89,90]. To study DOX release, 10 nM and 10 mM ATP concentrations were used, and, at 10 nM ATP, the accumulated DOX release of less than 10% within 16 h vs. 85.1% accumulated DOX release at 10 mM ATP was observed, which was accompanied by an enhancement of the fluorescence of the solution due to free DOX presence. It is worth mentioning that, in in vitro experiments, in the absence of ATP, the "G*P6A4", even at high concentration, did not exhibit any cytotoxicity towards HepG-2 and LO2 cells. Figure 11. Schematic illustration of the fabrication of a "G*P6A4*DOX" drug delivery system. Reproduced with the permission of reference [87]. Copyright © American Chemical Society 2021.

pH-Controlled Pillararene-Based Systems
Wang, Hu, and coauthors reported P6A-based assembly for controllable pH-controlled drug release [91] (Figure 12). To do that, the DOX molecule was conjugated via an acid-cleavable hydrazone bond with a flexible alkyl chain (G1) or a short ethylene glycol (G2) containing a pyridinium termini. In a weak alkaline phosphate buffer solution, P6A3 formed amphiphilic host-guest complexes with G1 or G2, which were confirmed by means of 1 H NMR and fluorescence studies. According to the Tyndall effect and DLS and TEM data, both complexes formed nanoparticles of spherical morphology with an average diameter of 278 and 366 nM, respectively, and with good stability. An extremely high DOX loading content (70 wt %(G2) and 85 wt % (G1)) and good stability under physiological and weakly alkaline conditions were observed. Both types of nanoparticles exhibited good stability at pH 8.0, with the cumulative DOX release of less than 3% within 6 h, while, under simulated physiological conditions (PBS, pH 7.4), the cumulative release of DOX was less than 12% within 6 h. Under the simulated endolysosomal environment (pH Figure 11. Schematic illustration of the fabrication of a "G*P6A4*DOX" drug delivery system. Reproduced with the permission of reference [87]. Copyright © American Chemical Society 2021.

pH-Controlled Pillararene-Based Systems
Wang, Hu, and coauthors reported P6A-based assembly for controllable pH-controlled drug release [91] (Figure 12). To do that, the DOX molecule was conjugated via an acidcleavable hydrazone bond with a flexible alkyl chain (G1) or a short ethylene glycol (G2) containing a pyridinium termini. In a weak alkaline phosphate buffer solution, P6A3 formed amphiphilic host-guest complexes with G1 or G2, which were confirmed by means of 1 H NMR and fluorescence studies. According to the Tyndall effect and DLS and TEM data, both complexes formed nanoparticles of spherical morphology with an average diameter of 278 and 366 nM, respectively, and with good stability. An extremely high DOX loading content (70 wt %(G2) and 85 wt % (G1)) and good stability under physiological and weakly alkaline conditions were observed. Both types of nanoparticles exhibited good stability at pH 8.0, with the cumulative DOX release of less than 3% within 6 h, while, under simulated physiological conditions (PBS, pH 7.4), the cumulative release of DOX was less than 12% within 6 h. Under the simulated endolysosomal environment (pH 5.5), a very quick DOX release (100% within 30 min) from "P6A3*G1" and "P6A3*G2" was observed as a result of acid-promoted hydrolysis of hydrazone bonds. According to the authors, at low "P6A3*G1" and "P6A3*G2" concentration (a drug equivalent dosage of 0.1 µg·mL −1 ), the cell viability was more than 80% after 32 h, while, at higher concentration (DOX equivalent dosage of 10.0 µg·mL −1 ), the cell viability decreased significantly. Finally, according to intracellular localization experiments, both types of nanoparticles were taken up by SKOV3 cancer cells (smaller "DOX*P6A3*G1" nanoparticles exhibited faster internalization) via endocytosis, followed by endolysosomal escape and subsequent released DOX distribution in the cytosol and nucleus. It was said that these nanoparticles could efficiently inhibit the proliferation of cancer cells and exhibit potent antitumor activity.
Int. J. Mol. Sci. 2023, 24, x FOR PEER REVIEW 14 of 33 5.5), a very quick DOX release (100% within 30 min) from "P6A3*G1" and "P6A3*G2" was observed as a result of acid-promoted hydrolysis of hydrazone bonds. According to the authors, at low "P6A3*G1" and "P6A3*G2" concentration (a drug equivalent dosage of 0.1 μg·mL −1 ), the cell viability was more than 80% after 32 h, while, at higher concentration (DOX equivalent dosage of 10.0 μg·mL −1 ), the cell viability decreased significantly. Finally, according to intracellular localization experiments, both types of nanoparticles were taken up by SKOV3 cancer cells (smaller "DOX*P6A3*G1" nanoparticles exhibited faster internalization) via endocytosis, followed by endolysosomal escape and subsequent released DOX distribution in the cytosol and nucleus. It was said that these nanoparticles could efficiently inhibit the proliferation of cancer cells and exhibit potent antitumor activity. Hu, Schmuck et al. reported DOX-decorated tumor-targeting nanocarriers based on host-guest recognition between a novel pillar [5]arene-based prodrug "P5A3-DOX" with an acid-cleavable linker and an Arg-Gly-Asp (RGD)-modified sulfonate guest RGD-SG [92] (Figure 13). In phosphate-buffered saline, "P5A3-DOX" self-assembled into nanoparticles, which exhibited a notable Tyndall effect along with dramatic quenching of DOX fluorescence. In the presence of RGD-SG, the authors observed a fluorescence enhancement due to the formation of two different types of aggregates, with a "P5A3-DOX/RGD-SG" ratio of either 5:1 or 1:3. Based on TEM and DLS data, at the host to guest ratio of 5:1, large vesicular structures with diameters around 190 (DLS) or 160 to 200 (TEM) nm were observed, while, at the ratio of 1:3, smaller aggregates with diameters around 10 (DLS) or 4 to 8 (TEM) nm were formed. According to molecular dynamics simulations, the volume ratio of the hydrophilic portion to the volume ratio between the hydrophilic and hydrophobic portions of "P5A3-DOX" is responsible for the aggregate formation. It was further demonstrated that the hydrazone linkage in "P5A3-DOX" is cleavable under the acidic condition, such as extracellular (pH 6.5) and endolysosomal environments (pH 5.0) of cancer cells. According to the authors, both the vesicles and micelles were stable under physiological conditions (pH 7.4), while DOX release was observed at lower pH: 40% DOX was released within 10 h at pH 6.5, and, at pH 5.0, the cumulative release of DOX was almost Hu, Schmuck et al. reported DOX-decorated tumor-targeting nanocarriers based on host-guest recognition between a novel pillar [5]arene-based prodrug "P5A3-DOX" with an acid-cleavable linker and an Arg-Gly-Asp (RGD)-modified sulfonate guest RGD-SG [92] ( Figure 13). In phosphate-buffered saline, "P5A3-DOX" self-assembled into nanoparticles, which exhibited a notable Tyndall effect along with dramatic quenching of DOX fluorescence. In the presence of RGD-SG, the authors observed a fluorescence enhancement due to the formation of two different types of aggregates, with a "P5A3-DOX/RGD-SG" ratio of either 5:1 or 1:3. Based on TEM and DLS data, at the host to guest ratio of 5:1, large vesicular structures with diameters around 190 (DLS) or 160 to 200 (TEM) nm were observed, while, at the ratio of 1:3, smaller aggregates with diameters around 10 (DLS) or 4 to 8 (TEM) nm were formed. According to molecular dynamics simulations, the volume ratio of the hydrophilic portion to the volume ratio between the hydrophilic and hydrophobic portions of "P5A3-DOX" is responsible for the aggregate formation. It was further demonstrated that the hydrazone linkage in "P5A3-DOX" is cleavable under the acidic condition, such as extracellular (pH 6.5) and endolysosomal environments (pH 5.0) of cancer cells. According to the authors, both the vesicles and micelles were stable under physiological conditions (pH 7.4), while DOX release was observed at lower pH: 40% DOX was released within 10 h at pH 6.5, and, at pH 5.0, the cumulative release of DOX was almost 100%. Finally, in in vitro and in vivo experiments, the higher cytotoxicity and more efficient tumor-targeting effect of prodrug micelles on HepG2 and HeLa cancer cells compared to the prodrug vesicles was demonstrated.
100%. Finally, in in vitro and in vivo experiments, the higher cytotoxicity and more efficient tumor-targeting effect of prodrug micelles on HepG2 and HeLa cancer cells compared to the prodrug vesicles was demonstrated. Very recently, Hu et al. reported a pH-responsive P5A-based tandem drug delivery system [93] (Figure 14). Thus, ester bond-linked betulinic acid (BA)-based quaternary ammonium salt amphiphile (BA-D) was combined with P5A4 to form vesicles, which were loaded with DOX. BA is known to possess a good cytotoxicity toward various type of cancers, while it has a good biocompatibility toward normal cells. The authors claimed that the DOX-loaded "P5A4*BA-D" assembly in acidic media (pH = 5.0) efficiently disassembles and realizes both DOX and BA-D, which was observed by using TEM and DLS data. In in vivo experiments with MCF-7 and HepG2 cancer cells, it was confirmed that the loading with DOX of "P5A4*BA-D" assembly enhances its antitumor efficacy due to the synergistic effect of DOX and BA-D with the IC50 value for the HepG2 cancer cells of 0.  Very recently, Hu et al. reported a pH-responsive P5A-based tandem drug delivery system [93] (Figure 14). Thus, ester bond-linked betulinic acid (BA)-based quaternary ammonium salt amphiphile (BA-D) was combined with P5A4 to form vesicles, which were loaded with DOX. BA is known to possess a good cytotoxicity toward various type of cancers, while it has a good biocompatibility toward normal cells. The authors claimed that the DOX-loaded "P5A4*BA-D" assembly in acidic media (pH = 5.0) efficiently disassembles and realizes both DOX and BA-D, which was observed by using TEM and DLS data. In in vivo experiments with MCF-7 and HepG2 cancer cells, it was confirmed that the loading with DOX of "P5A4*BA-D" assembly enhances its antitumor efficacy due to the synergistic effect of DOX and BA-D with the IC 50   Li, Meng, Sessler, and co-authors reported a pH-responsive tandem drug delivery system combined with water-soluble P6A2, oxaliplatin (OX)-type Pt(IV) prodrug (PtC10), and DOX [94] (Figure 15). Based on fluorescence titration experiments at pH 7.4, P6A2 readily binds PtC10 with a Ka value of (1.2 ± 0.03) × 10 4 M −1 , while, at pH 5.0, a lower Ka of 1.73 ± 0.15 × 10 3 M −1 was observed, which confirms the pH sensitivity of "P6A2* PtC10". It was observed that the pH values 7.4 and 5.0 reflect those of normal physiological environment and lysosomes. In aqueous solutions, "P6A2* PtC10" forms aggregates in a 1:2 ratio, which was confirmed by fluorescence studies by a notable Tyndall effect. Based on TEM and DLS, the formation of hollow supramolecular vesicles with diameters ranging from 50 nm to 90 nm (TEM) or 91.3 nm (DLS) with the outer wall thickness of 6 nm (TEM) was observed. The obtained hollow vesicles were able to accommodate DOX to form nanoparticles of 100 nm (TEM) or 122 nm (DLS) diameter with dark interiors (TEM), which were stable up to 3 days in water. The acid-triggered DOX-release behavior of "DOX* P6A2* PtC10" was then investigated. It was observed that, at pH 7.4, approximately 7% of the bound DOX was released from "DOX* P6A2 * PtC10" over the course of 24 h, while about 80% within 24 h was seen at pH 5.0. For PtC10, about 6% was released at pH 7.4 and around 70% was released at pH 5.0. It was also found that "DOX* P6A2* PtC10" could enter HepG-2 cells via endocytosis to result in intercellular DOX release in the cell nucleus. According to the authors, using "DOX* P6A2 * PtC10" provides a synergistic cell cytotoxicity against HepG-2 cancer cells, which is comparable to either PtC10 or DOX. Finally, in in vivo tests, the "DOX* P6A2 * PtC10" exhibited higher therapeutic efficiency and engendered less body weight loss in HepG-2 tumor xenografts bearing nude mice as compared to various controls. Li, Meng, Sessler, and co-authors reported a pH-responsive tandem drug delivery system combined with water-soluble P6A2, oxaliplatin (OX)-type Pt(IV) prodrug (PtC10), and DOX [94] (Figure 15). Based on fluorescence titration experiments at pH 7.4, P6A2 readily binds PtC 10 with a Ka value of (1.2 ± 0.03) × 10 4 M −1 , while, at pH 5.0, a lower Ka of 1.73 ± 0.15 × 10 3 M −1 was observed, which confirms the pH sensitivity of "P6A2* PtC 10 ". It was observed that the pH values 7.4 and 5.0 reflect those of normal physiological environment and lysosomes. In aqueous solutions, "P6A2* PtC 10 " forms aggregates in a 1:2 ratio, which was confirmed by fluorescence studies by a notable Tyndall effect. Based on TEM and DLS, the formation of hollow supramolecular vesicles with diameters ranging from 50 nm to 90 nm (TEM) or 91.3 nm (DLS) with the outer wall thickness of 6 nm (TEM) was observed. The obtained hollow vesicles were able to accommodate DOX to form nanoparticles of 100 nm (TEM) or 122 nm (DLS) diameter with dark interiors (TEM), which were stable up to 3 days in water. The acid-triggered DOX-release behavior of "DOX* P6A2* PtC 10 " was then investigated. It was observed that, at pH 7.4, approximately 7% of the bound DOX was released from "DOX* P6A2 * PtC 10 " over the course of 24 h, while about 80% within 24 h was seen at pH 5.0. For PtC 10 , about 6% was released at pH 7.4 and around 70% was released at pH 5.0. It was also found that "DOX* P6A2* PtC 10 " could enter HepG-2 cells via endocytosis to result in intercellular DOX release in the cell nucleus. According to the authors, using "DOX* P6A2 * PtC 10 " provides a synergistic cell cytotoxicity against HepG-2 cancer cells, which is comparable to either PtC 10 or DOX. Finally, in in vivo tests, the "DOX* P6A2 * PtC 10 " exhibited higher therapeutic efficiency and engendered less body weight loss in HepG-2 tumor xenografts bearing nude mice as compared to various controls. Figure 15. Schematic representation of the pH-responsive P6A2-based dual drug delivery system. Reproduced with the permission of reference [94]. Copyright © Royal Society Chemistry 2020.

Spermine-Driven Drug Release Pillararene-Based Systems
As it was mentioned above, in certain types of cancers (lung, colorectal, etc.), the biological amines, such as spermine, are overexpressed. In addition, spermine accommodates readily into the cavity of PAs. Keeping both of these facts in mind, Sun, Zhang, and co-authors reported an assembly between anionic pillar [6]arene host and oxaliplatin (OxPt) as a possible candidate for colorectal cancer chemotherapy [95] (Figure 16).

Spermine-Driven Drug Release Pillararene-Based Systems
As it was mentioned above, in certain types of cancers (lung, colorectal, etc.), the biological amines, such as spermine, are overexpressed. In addition, spermine accommodates readily into the cavity of PAs. Keeping both of these facts in mind, Sun, Zhang, and co-authors reported an assembly between anionic pillar [6]arene host and oxaliplatin (OxPt) as a possible candidate for colorectal cancer chemotherapy [95] (Figure 16). Reproduced with the permission of reference [94]. Copyright © Royal Society Chemistry 2020.

Spermine-Driven Drug Release Pillararene-Based Systems
As it was mentioned above, in certain types of cancers (lung, colorectal, etc.), the biological amines, such as spermine, are overexpressed. In addition, spermine accommodates readily into the cavity of PAs. Keeping both of these facts in mind, Sun, Zhang, and co-authors reported an assembly between anionic pillar [6]arene host and oxaliplatin (OxPt) as a possible candidate for colorectal cancer chemotherapy [95] (Figure 16). Figure 16. Schematic representation of the spermine-responsive P6A2-based OxPt delivery system. Reproduced with the permission of reference [95]. Copyright © American Chemical Society 2018. Figure 16. Schematic representation of the spermine-responsive P6A2-based OxPt delivery system. Reproduced with the permission of reference [95]. Copyright © American Chemical Society 2018.
The authors claimed that the encapsulation of OxPt into the cavity of P6A2 would reduce its cytotoxicity to the normal cells along with more efficient drug release in the tumor cell microenvironment. At physiological pH 7.4, OxPt forms a 1:1 inclusion complex with P6A2, which was confirmed based on 1 H NMR data and Job-plot titration experiments, and, according to the isothermal titration calorimetry (ITC) experiments, the calculated association constant was 1.66 × 10 4 M −1 . By using the same approaches, the 1:1 inclusion complex "SPM*P6A2" was confirmed with an association constant of 2.58 × 10 7 M −1 . Owing to high cytotoxicity, free OxPt to normal colorectal cells, and low or no cytotoxicity of P6A, the 1:2 "P6A*OxPt" complex was selected for further studies. Moreover, a three-orders-of-magnitude higher binding constant for the "P6A2*SPM" complex compared with the "P6A2*OxPt" one and the competitive binding of SPM by P6A2 with a simultaneous release of OxPt was expected. According to 1 H NMR data, the addition of 1.0 equiv SPM to "P6A2*OxPt" results in the release of free OxPt and the formation of a "P6A2*SPM" complex. In in vitro tests with SPM-overexpressed colorectal cancer HCT116 cells, "P6A2*OxPt" exhibited higher anticancer bioactivity than OxPt itself, with an increased amount of about 20% with calculated IC 50 values for OxPt and "P6A2*OxPt" of about 23.3 and 13.7 µM, respectively, which suggest a notably improved cytotoxicity of "P6A2*OxPt" against colorectal cancer HCT116 in vitro.

Redox-Responsive Drug Release Pillararene Systems
Y. Pei, Z. Pei, and co-authors reported ferrocenium-capped amphiphilic supramolecular assembly, which is ferrocenium-capped amphiphilic pillar [5]arene (FCAP) based on pillar [5]arene P5A5 for the simultaneous delivery of DOX as cytotoxic drug component and siRNA (MRP1 siRNA) to restore drug sensitivity of cells for more effective chemotherapy via knocking down of drug resistance genes [17] (Figure 17).
FCAP were prepared via azide-alkyne cycloaddition (CuAAC) of azide-modified P5A. The following oxidation of the ferrocenyl groups with FeCl 3 resulted in the formation of amphiphilic FCAP, which were able to form regular aggregates in water. According to the SEM, TEM, and DLS data, as well as the observed Tyndall effect, FCAP formed stable (in water solution at 300 K for one week) spherical vesicles with the average diameter of 91.9 nm and polydispersity index of 0.298. Thus, the obtained FCAP vesicles demonstrated a strong response to GSH (as reductant), which was accompanied by a disappearance of the Tyndall effect. Based on an MTT cell-survival assay, the relative cell viability of 293T cells (normal cells) incubated with unloaded FCAP vesicles in the concentrations of 10 µM after 24 h was over 85%, which confirms low toxicity to FCAP of normal cells. Next, the experiment on loading FCAP with DOX was carried out, and, based on SEM and DLS data, the formation of DOX-loaded vesicles of 79 nm and with a polydispersity index of 0.232 was observed, with DOX encapsulation and loading efficiency calculated to be 67.0% and 9.1% (according to the data of UV/Vis-spectroscopy). Along with good drug loading, the FCAP cationic vesicles exhibited GSH-triggering (10 mM concentration of GSH was used, which is relevant to the GSH concentration in cancer cells (1-11 mM) [96]), and DOX release was observed with the amount of DOX up to 92% along with disassembly of DOX-loaded vesicles, while, without GSH exposure, only 39% of DOX was released in the same period. In addition, based the results of in vitro anticancer activity studies using 293T cells and HeLa cells, as well SKOV-3 and KM-12 cells, it was suggested that there is higher cytotoxicity of DOX-loaded FCAP against cancer cells, while its cytotoxicity to normal cells was effectively reduced. Finally, siRNA (MRP1 siRNA) was used to fabricate DOX-loaded MRP1 siRNA/cationic vesicle complexes for the co-delivery study to assess the drug resistance gene silencing of SKOV-3 cells. According to the authors, in the case of negative siRNA, used as the control, the cell death and apoptosis of SKOV-3 cells after being incubated with DOX-loaded negative siRNA/cationic vesicle complexes was 37.9%, vs. 52.8% for DOX-loaded MRP1 siRNA/cationic vesicle complexes with an IC 50  FCAP were prepared via azide-alkyne cycloaddition (CuAAC) of azide-modified P5A. The following oxidation of the ferrocenyl groups with FeCl3 resulted in the formation of amphiphilic FCAP, which were able to form regular aggregates in water. According to the SEM, TEM, and DLS data, as well as the observed Tyndall effect, FCAP formed stable (in water solution at 300 K for one week) spherical vesicles with the average diameter of 91.9 nm and polydispersity index of 0.298. Thus, the obtained FCAP vesicles demonstrated a strong response to GSH (as reductant), which was accompanied by a disappearance of the Tyndall effect. Based on an MTT cell-survival assay, the relative cell viability

Light-Triggered Drug Release Pillararene Systems
The main challenge for drug delivery systems is their ability to target the tumor and selectively track the process of translocation, drug release, and excretion of the cytotoxic drug. The easiest approach to this involves using fluorescence as an analytic signal and UV/vis irradiation (light) to initiate the drug-release process. Unfortunately, most of the commonly used anticancer drugs are non-or low fluorescent [97][98][99] and cannot be used as fluorescent reporters. The most common approach to solve this issue involves the use of theranostic tools, such as photoactivated drugs [97][98][99], in which the prodrug molecule contains cytotoxic drug combined with a fluorescent reporter molecule by means of a photocleavable linker.
Following this strategy, Huang and co-authors reported a ternary DDS consisting of photodegradable prodrug (Py-Cbl), in which anticancer drug chlorambucil was combined with pyrene as fluorophore encapsulated into an anionic water-soluble P6A [100] ( Figure 18). To enhance membrane permeability, a cationic hydrophilic diblock copolymer methoxy-poly(ethylene glycol) 114 -block-poly( L -lysine hydrochloride) 200 (PEG-b -PLKC) was introduced into the system of the "P6A3*Py-Cbl" host-guest inclusion complex. The formation of "P6A3*Py-Cbl" with the benzene ring of chlorambucil that penetrated into the P6A cavity was suggested based on DFT calculation of the energy-minimized structure of the host-guest complex. Based on DLS and TEM data, the spherical nanostructures (which were quite stable in buffer for several weeks) from PEG-b-PLKC and "P6A3*Py-Cbl" with anaverage size of 80 to 160 nm (TEM) or 127 nm (DLS) were observed. Sharp color contrast between the periphery and central parts of these aggregates suggests their micellar structure. The photo-triggered release of free chlorambucil was confirmed based on the fluorescence studies and the 1 H NMR experiments. To study the effectiveness of the P6A-based assembly, the A549 cell imaging studies were carried out, and, upon irradiation of UV light after the 24 h incubation of A549 cells with "P6A3*Py-Cbl", notable changes in spectroscopic behavior and color were monitored due to the photodegradation of Py-Cbl into PyOH and chlorambucil, which resulted in a color change of the cells. Controllable release of Cbl in vitro was verified by using the MTT assay, and the higher cytotoxicity of micelles compared to "P6A3*Py-Cbl" and Cbl and their highest level of toxicity (about 59.7% in comparison to the control) was confirmed.
Wang and co-authors reported two types of supramolecular assemblies, based on water-soluble pillar [6]arene P6A3 and azobenzene derivatives G1 or G2. Supramolecular micelles formed by P6A3 with G1 were gradually transformed into layered structures with liquid-crystalline properties, while P6A and G2 formed supramolecular vesicles as photoand pH-responsive drug delivery systems [101] (Figure 19).
Due to G1 and G2 poor water solubility, to study the host-guest complexation in the D 2 O model, guests G3 and G4 were used, and, based on the results of 1 H NMR, 1 H-1 H COSY, and 2D ROESY spectroscopy, the formation of "P6A3*G3" and "P6A3*G4" 1:1 inclusion complexes was observed with association constants of (1.03 ± 0.24)×10 4 M −1 and (2.06 ± 0.88) × 10 4 M −1 , respectively. The amphiphilic "P6A3*G1" and "P6A3*G2" supramolecular complexes were further prepared. Based on the observed Tyndall effect and TEM and DLS data, there was formation of "P6A3*G1" aggregates as solid spherical micelles of about 220 nm average diameter (DLS), and, for the "P6A3*G2", the formation of vesicles of hollow spherical morphology with a diameter of 160 nm (DLS), or from 100 to 200 nm (TEM), was confirmed. According to the authors, in "P6A3*G2", the Tyndall effect disappeared after adjusting the solution pH to 6.2 and no vesicles were detected in TEM image, and, after adjusting the pH value to 7.4, the re-formation of the vesicle was observed, which was confirmed by DLS data. As for proto-response, according to TEM data, upon irradiation of the "P6A3*G2"with UV light at 365 nm, most of the vesicles collapsed due to the E/Z isomerization (trans-to cis-) of the azabenzene moiety of G2, and only a few irregular aggregates could be observed, while, upon irradiation with visible light at 435 nm, re-formation of the vesicle was observed, which was confirmed by DLS data. After loading of "P6A3*G2"vesicles with Mitoxantrone (MTZ), based on TEM data, the authors detected the MTZ loading into the vesicle cavities with the formation of MTZ-loaded "P6A3*G2"of larger size (≈364 nm), compared to MTZ-free vesicles (≈160 nm), and, based on UV/Vis absorption spectra, the MTZ encapsulation efficiency was calculated to be 76%. The authors claimed that, under simulated physiological conditions (pH 7.4), the cumulative leakage of MTZ from MTZ-loaded vesicles was less than 8% within 12 h, while 44% and 93% were detected at pH 6.4 and pH 4.4 within 12 h with an intensive MTZ release in the first 2 h. In addition, under UV irradiation with UV light, the cumulative amount of released drug was about 60% after 4 h. In in vitro tests with MCF-7 cancer cells, the relative cell viability of cancer cells with UV irradiation was only 20% after 96 h, which showed similar therapeutic effects to the free MTZ (17%), whereas without irradiation was about 27%. In addition, MTZ-loaded "P6A3*G2"vesicles could induce apoptosis in MCF-7 cells and, after 48 h, the quantity of apoptotic cells of the whole tested MCF-7 cells was about 47.2%, while, after 96 h, the ratio of apoptotic cells significantly increased to 70.2% and the majority of apoptotic cells were the early apoptotic cells. Wang and co-authors reported two types of supramolecular assemblies, based on water-soluble pillar [6]arene P6A3 and azobenzene derivatives G1 or G2. Supramolecular micelles formed by P6A3 with G1 were gradually transformed into layered structures with liquid-crystalline properties, while P6A and G2 formed supramolecular vesicles as photo-and pH-responsive drug delivery systems [101] (Figure 19). Figure 19. Schematic illustration of the construction of supramolecular micelles "P6A3*G1" or vesicles "P6A3 *G2" and the application of supramolecular vesicles in drug delivery. Reproduced with the permission of reference [101]. Copyright © Wiley 2015.
Due to G1 and G2 poor water solubility, to study the host-guest complexation in the D2O model, guests G3 and G4 were used, and, based on the results of 1 H NMR, 1 H-1 H COSY, and 2D ROESY spectroscopy, the formation of "P6A3*G3" and "P6A3*G4" 1:1 inclusion complexes was observed with association constants of (1.03 ± 0.24)×10 4 M −1 and (2.06 ± 0.88) × 10 4 M −1 , respectively. The amphiphilic "P6A3*G1" and "P6A3*G2" supramolecular complexes were further prepared. Based on the observed Tyndall effect and TEM and DLS data, there was formation of "P6A3*G1" aggregates as solid spherical micelles of about 220 nm average diameter (DLS), and, for the "P6A3*G2", the formation of vesicles of hollow spherical morphology with a diameter of 160 nm (DLS), or from 100 to 200 nm (TEM), was confirmed. According to the authors, in "P6A3*G2", the Tyndall effect disappeared after adjusting the solution pH to 6.2 and no vesicles were detected in TEM Figure 19. Schematic illustration of the construction of supramolecular micelles "P6A3*G1" or vesicles "P6A3 *G2" and the application of supramolecular vesicles in drug delivery. Reproduced with the permission of reference [101]. Copyright © Wiley 2015.

Multi-Response Drug Release Pillararene Systems
Du and co-workers reported a quintuple stimulated drug delivery system based on pillar [6]arene P6A3 [102] (Figure 20). In this system, P6A3 was assembled with disulfidelinked benzimidazolium amphiphiles G1-G3 to form amphiphilic vesicles. Up to five stimuli for the encapsulated drug release were reported by the authors, such as glutathione, which could break the S-S bond in the surfactant, pH or CO 2 , which could change COO − group to COOH group, Zn 2+ , which was able to chelate with P6A3, and, finally, hexanedi-amine (HDA), which existed in deprotonated form under these conditions and blocked the cavity of P6A3. Int

Insulin Delivery Systems Based on Pillararenes
Type 1 diabetes mellitus (T1DM), juvenile diabetes, or insulin-dependent diabetes, is an autoimmune disease that leads to the destruction of insulin-producing pancreatic beta cells, causing an absolute deficiency of insulin. People with T1DM require life-long insulin replacement therapy along with blood glucose level monitoring. The insulin replacement therapy is provided via multiple daily insulin injections, or, more preferably, via continuous subcutaneous insulin infusion by using an insulin pump. In addition, oral insulin is still a main challenge for research and development due to the physiological barriers to its absorption, its low bioavailability, low biopotency, and others [103]. Therefore, the insulin delivery systems combined with real-time glucose monitoring devices are of high demand. As a first example of such kinds of systems, Wang, Hu, and co-authors reported a supramolecular assembly based on water-soluble pillar [5]arene (P5A6) and pyridine boronic acid with a pyridinium moiety bearing at N1 atom long aliphatic chains as an amphiphilic part (G) [104] (Figure 21). The authors suggested the possibility of the inclusion of the alkyl chain and partial pyridine group of G into the hydrophobic cavity P5A6 and the formation of "P5A6*G" inclusion complex, and that was confirmed by the 1 H NMR experiment in D2O using a modified pyridinium salt (MG) with a shorter butyl chain at

Insulin Delivery Systems Based on Pillararenes
Type 1 diabetes mellitus (T1DM), juvenile diabetes, or insulin-dependent diabetes, is an autoimmune disease that leads to the destruction of insulin-producing pancreatic beta cells, causing an absolute deficiency of insulin. People with T1DM require life-long insulin replacement therapy along with blood glucose level monitoring. The insulin replacement therapy is provided via multiple daily insulin injections, or, more preferably, via continuous subcutaneous insulin infusion by using an insulin pump. In addition, oral insulin is still a main challenge for research and development due to the physiological barriers to its absorption, its low bioavailability, low biopotency, and others [103]. Therefore, the insulin delivery systems combined with real-time glucose monitoring devices are of high demand. As a first example of such kinds of systems, Wang, Hu, and co-authors reported a supramolecular assembly based on water-soluble pillar [5]arene (P5A6) and pyridine boronic acid with a pyridinium moiety bearing at N1 atom long aliphatic chains as an amphiphilic part (G) [104] (Figure 21). The authors suggested the possibility of the inclusion of the alkyl chain and partial pyridine group of G into the hydrophobic cavity P5A6 and the formation of "P5A6*G" inclusion complex, and that was confirmed by the 1 H NMR experiment in D 2 O using a modified pyridinium salt (MG) with a shorter butyl chain at N1. The ability of "P5A6*G" supra-amphiphile to form higher-order aggregates in the aqueous phase was confirmed based on the Tyndall effect, DLS experiments, and TEM images: the obtained aggregates showed a hollow spherical morphology with a diameter from 120 nm (according to the data of TEM) to 132 nm (DLS). Boronic acids are commonly used for the recognition of carbohydrates at physiological conditions [105][106][107], and, therefore, the boronic acid pyridinium moiety in "P5A6*G" could form a stable boronate ester with the glucose. The response of "P5A6*G" to D-glucose was confirmed by means of 1 H and 11 B NMR. In addition, due to the strong bonding between boric acid ligand G and D-glucose, the authors observed no "P5A6*G" vesicles in the TEM image and the disappearance of the Tyndall effect. Along with D-glucose binding, the obtained "P5A6*G" demonstrated the ability to accumulate DOX, which is better than in the absence of D-glucose. More importantly, "P5A6*G" vesicles exhibited the ability to encapsulate insulin to form insulinloaded vesicles, and, according to TEM and DLS results, these vesicles were much larger (ca. 320 nm) compared to unloaded "P5A6*G" (ca. 132 nm) and the vesicles adopted an irregular morphology. In the in vitro insulin-release experiments, the authors observed almost no insulin release under physiological conditions (pH 7.4). In addition, in the normal blood glucose level (1.0 mg·mL −1 ), the cumulative release amount of insulin was only about 20% within 60 min, indicating that unwanted insulin release would not occur under normal blood glucose levels, and the cumulative release efficiency increased to ca. 60% at 11.1 mM glucose and ca. 70% at 30.5 mM glucose. In in vitro tests, "P5A6*G" exhibited good cytocompatibility for MRC-5 normal cells. Based on all the above, these vesicles can be used as nanocarriers for insulin delivery. N1. The ability of "P5A6*G" supra-amphiphile to form higher-order aggregates in the aqueous phase was confirmed based on the Tyndall effect, DLS experiments, and TEM images: the obtained aggregates showed a hollow spherical morphology with a diameter from 120 nm (according to the data of TEM) to 132 nm (DLS). Boronic acids are commonly used for the recognition of carbohydrates at physiological conditions [105][106][107], and, therefore, the boronic acid pyridinium moiety in "P5A6*G" could form a stable boronate ester with the glucose. The response of "P5A6*G" to D-glucose was confirmed by means of 1 H and 11 B NMR. In addition, due to the strong bonding between boric acid ligand G and D-glucose, the authors observed no "P5A6*G" vesicles in the TEM image and the disappearance of the Tyndall effect. Along with D-glucose binding, the obtained "P5A6*G" demonstrated the ability to accumulate DOX, which is better than in the absence of D-glucose. More importantly, "P5A6*G" vesicles exhibited the ability to encapsulate insulin to form insulin-loaded vesicles, and, according to TEM and DLS results, these vesicles were much larger (ca. 320 nm) compared to unloaded "P5A6*G" (ca. 132 nm) and the vesicles adopted an irregular morphology. In the in vitro insulin-release experiments, the authors observed almost no insulin release under physiological conditions (pH 7.4). In addition, in the normal blood glucose level (1.0 mg·mL −1 ), the cumulative release amount of insulin was only about 20% within 60 min, indicating that unwanted insulin release would not occur under normal blood glucose levels, and the cumulative release efficiency increased to ca. 60% at 11.1 mM glucose and ca. 70% at 30.5 mM glucose. In in vitro tests, "P5A6*G" exhibited good cytocompatibility for MRC-5 normal cells. Based on all the above, these vesicles can be used as nanocarriers for insulin delivery.  The same group recently reported a nanovesicle based on water-soluble pillar [5]arene P5A6, pyrene fluorophores connected with a long alkyl-chain quaternary ammonium salt bearing two phenyl boronic acid moieties appended and loaded with insulin and glucose oxidase (GOx) [108] (Figure 22). According to the authors, the obtained insulin-GOx-loaded supramolecular assembly can serve as selective glucose excimeric fluorescence turn-on sensor and a controlled insulin delivery actuator, as insulin and GOx are simultaneously encapsulated in the vesicles. In the presence of glucose, the structure disruption of this supramolecular assembly occurs to result in an efficient encapsulated insulin. It was observed that the entrapped insulin release could be triggered by either high glucose concentration or in situ-generated H 2 O 2 and acid microenvironment due to the GOxpromoted glucose oxidation to result in gluconic acid. In the experiments on insulin release, the authors observed the slow release of insulin at the glucose concentration of (100 mg·dL −1 ), while, at the concentration of glucose of 250 mg·dL −1 mM, the most efficient insulin release (40%) was observed, which confirms the sensitivity of insulin-GOx-loaded vesicles were unsensitive to a normal concentration of glucose and quite sensitive to the condition of hyperglycemia. The same group recently reported a nanovesicle based on water-soluble pillar [5]arene P5A6, pyrene fluorophores connected with a long alkyl-chain quaternary ammonium salt bearing two phenyl boronic acid moieties appended and loaded with insulin and glucose oxidase (GOx) [108] (Figure 22). According to the authors, the obtained insulin-GOx-loaded supramolecular assembly can serve as selective glucose excimeric fluorescence turn-on sensor and a controlled insulin delivery actuator, as insulin and GOx are simultaneously encapsulated in the vesicles. In the presence of glucose, the structure disruption of this supramolecular assembly occurs to result in an efficient encapsulated insulin. It was observed that the entrapped insulin release could be triggered by either high glucose concentration or in situ-generated H2O2 and acid microenvironment due to the GOx-promoted glucose oxidation to result in gluconic acid. In the experiments on insulin release, the authors observed the slow release of insulin at the glucose concentration of (100 mg·dL −1 ), while, at the concentration of glucose of 250 mg·dL −1 mM, the most efficient insulin release (40%) was observed, which confirms the sensitivity of insulin-GOx-loaded vesicles were unsensitive to a normal concentration of glucose and quite sensitive to the condition of hyperglycemia. Another example of a glucose-responsive PA-based insulin delivery/release system was reported by Tong, Cen, and co-authors [109] (Figure 23). To construct this nanocarrier Another example of a glucose-responsive PA-based insulin delivery/release system was reported by Tong, Cen, and co-authors [109] (Figure 23). To construct this nanocarrier pillar [5]arene, P5A7 was assembled with paraquat-terminated poly(phenylboronic acid) (PPBA-G) with a binding constant of (8.20 ± 1.70) × 10 4 M −1 . According to the DLS data in phosphate-buffered saline (PBS) solution (pH = 7.4), the formation of supramolecular polymer vesicles (PVs) of 50 nm was detected. It was observed that the presence in these PVs of glucose-responsive PPBA-G and pH-responsive P5A results in dual-responsiveness of the obtained PVs. Thus, according to DLS data, at the normal glucose concentration (100 mg·dL −1 ), the PVs did not show any changes, while they totally disappeared at hyperglycemic conditions, namely at the 400 mg·dL −1 glucose concentration. On the other hand, by changing solution pH levels, the authors observed the disassociation of "P5A7*PPBA-G" host−guest assembly, resulting in solid spheres (PPBA-G) at pH 5.0 and the reconstruction of the PVs structure at the physiological pH of 7.4. After both insulin and GOx are simultaneously encapsulated within the PVs, their insulin-release ability was studied. According to the authors, the obtained insulin-Gox-loaded PVs demonstrated fast insulin release (90%) under the hyperglycemia conditions (400 mg·dL −1 ), as well as at pH levels of 5.0 (60%), which confirms their dual-stimuliresponse. In addition, in cell survival tests, the cell viability of 3T3 mouse fibroblast cells cultured with the above-mentioned PVs were all above 90%, implying the low cytotoxicity of all drug-loaded PVs. Finally, the ability of these PVs for transdermal insulin delivery by using PVA/PVP microneedle patches was carried out and the appealability of this platform, probably for the treatment of diabetes in vivo, was suggested.  [5]arene, P5A7 was assembled with paraquat-terminated poly(phenylboronic acid) (PPBA-G) with a binding constant of (8.20 ± 1.70) × 10 4 M −1 . According to the DLS data in phosphate-buffered saline (PBS) solution (pH = 7.4), the formation of supramolecular polymer vesicles (PVs) of 50 nm was detected. It was observed that the presence in these PVs of glucose-responsive PPBA-G and pH-responsive P5A results in dual-responsiveness of the obtained PVs. Thus, according to DLS data, at the normal glucose concentration (100 mg·dL −1 ), the PVs did not show any changes, while they totally disappeared at hyperglycemic conditions, namely at the 400 mg·dL −1 glucose concentration. On the other hand, by changing solution pH levels, the authors observed the disassociation of "P5A7*PPBA-G" host−guest assembly, resulting in solid spheres (PPBA-G) at pH 5.0 and the reconstruction of the PVs structure at the physiological pH of 7.4. After both insulin and GOx are simultaneously encapsulated within the PVs, their insulin-release ability was studied. According to the authors, the obtained insulin-Gox-loaded PVs demonstrated fast insulin release (90%) under the hyperglycemia conditions (400 mg·dL −1 ), as well as at pH levels of 5.0 (60%), which confirms their dual-stimuliresponse. In addition, in cell survival tests, the cell viability of 3T3 mouse fibroblast cells cultured with the above-mentioned PVs were all above 90%, implying the low cytotoxicity of all drug-loaded PVs. Finally, the ability of these PVs for transdermal insulin delivery by using PVA/PVP microneedle patches was carried out and the appealability of this platform, probably for the treatment of diabetes in vivo, was suggested.

Conclusions and Perspectives
In summary, pillararenes represent a promising class of molecular hosts for targeted drug delivery. Due to a possibility for the modification of both ends of the pillararene cavity, neutral, cationic, anionic, or amphiphilic pillararenes can be easily prepared.
In some cases, the pillararenes themselves can exhibit a certain biological activity, for instance, antibiofilm activity. For the construction of pillararenes-based targeted drug delivery systems and the following drug delivery mechanism, two main strategies are involved: (1) direct formation of a host-guest inclusion complex with small drug-like, drug, or prodrug molecules and (2) the initial formation of amphiphilic pillarene-guest complexes with their following aggregation to result in vesicles or micelles, which are able to encapsulate drug molecules of various geometry and size. The first approach, however, is very limited by the guest molecule size and/or geometry and the drug loading degree. The mechanism for the encapsulated drug release involves the cleavage of the linker moiety of prodrug under external stimuli, such as chemical reaction or photochemical transformation, or by means of competitive binding with other guest molecules, for instance, compounds presented in pathological microenvironments.
The second approach involves the encapsulation of drug molecules within the pillararene-based supramolecular vesicles or micelles and the following disaggregation of these drug-loaded aggregates under external stimuli, such as light, oxidants, or chemicals present in the paralogical processes microenvironment. The advantages of such an approach are high drug loading value, multi-stimuli response, as well as possibility for encapsulation of drug/pre-drug molecules of various nature, geometry, and size. At the same time, these pillararene-based supramolecular delivery systems are silent under normal physiological conditions. At the moment, various pillararenes-based systems for the delivery of different cargoes are reported from antibiotics and anti-cancer drugs to siRNAs and insulin.
In many cases, targeting groups are not used in reported pillararene-based drug delivery systems, except the several examples of insulin delivery systems, in which boronic acids moieties are used to target sugars [104][105][106][107][108][109]. In the case of other pillararene-based drug delivery systems, the macrocycle ring substitution is used for improving their performance, and not for targeting. It is worth to mention that Hu, Schmuck et al. [92] reported a pillararene-based DOX nanocarrier with an incorporated Arginylglycylaspartic acid (RGD) targeting moiety, which was recognized and bound by the cell adhesion proteins, integrins. In addition, several small-molecule-based or macrocyclic systems [113][114][115], including a pillarerene-based one [116], bearing mitochondria targeting triphenylphosphonium moieties, were reported as diagnostic and therapeutic tools for various types of cancers. Thus, these moieties may be suggested to be introduced in pillararene-based anticancer drug delivery systems.
As for future perspectives on pillararene-based drug delivery systems, one also can mention the lack of reports on the application of pillararenes as carriers for antiviral drug delivery, while antiviral drugs carriers were reported for other classes of macrocycles [117,118]. Additionally, due to a wide range of binding motifs, pillararenes offer the potential to interact directly with viruses and inhibit infection, for instance, it was reported for human papillomavirus [119]. To date, the use of other macrocycles as antivirals is also limited by few examples [120,121], including a recent report on the inhibition of a large variety of viruses, including herpes simplex virus 2 (HSV-2), respiratory syncytial virus (RSV), and SARS-CoV-2, by cucurbit[n]urils via host-guest supramolecular interactions between viral surface proteins and the cavity of cucurbit[n]urils [122].