Abstract

The purpose of this study was to evaluate the physicochemical properties of piperine (PP) in ground mixtures (GMs) of PP with α-, β-, or γ-cyclodextrin (CD) under conditions of humidity, heat, and humidity-heat. In solid-state fluorescence measurements, the fluorescence maxima for GM (PP/αCD = 1/2), GM (PP/βCD = 1/1), and GM (PP/γCD = 1/1) were observed at 463, 472, and 469 nm, respectively. On the other hand, the humidified GMs exhibited maxima at 454, 460, and 465 nm, while the humidified-heated samples displayed fluorescence maxima at 455, 455, and 469 nm, respectively. Therefore, the molecular behavior of PP with α, β, and γCD was concluded to vary upon the coordination of water molecules. NIR and solid-state fluorescence measurements revealed that the molecular behavior of PP inside the α, β, and γCD cavity changed by water and heat factors depends on the mobility of the methylenedioxyphenyl group.

1. Introduction

Pepper is a household spice widely used in food additives and seasonings. In addition, pepper is an important component of traditional medicine in Asian countries. In recent years, diet food has been attracting great attention due to the continuous increase in obese population. Also, the demand for pepper is increasing with the rapid development of seasonings [1]. Piperine (PP) is the major pungent ingredient in Piperaceae pepper (Piper nigrum). The chemical structure of PP is (2E,4E)-1-[1,3-benzodioxol-5-yl)-1-oxo-2,4-pentadienyl] piperidine. Among its properties, PP has been found to significantly reduce serum triglyceride, total cholesterol, low-density lipoprotein cholesterol, and very low-density lipoprotein cholesterol levels in high fat-fed rats [2]. PP significantly increases high density lipoprotein cholesterol levels and its beneficial effects have been reported to reduce dyslipidemia [3]. In addition, PP displays beneficial food functions such as nutrient absorption promotion and anti-inflammatory and antidepressant action [46]. As a major component of pepper, PP is expected to have diverse applications. The geometry of the conjugated diene of PP may present several isomeric forms upon cis-trans isomerization: isopiperine = Z,E-(cis-trans)-piperine, chavicine = Z,Z-(cis-cis)-piperine, and isochavicine = E,Z-(trans-cis)-piperine [7]. Changes in the amide group of PP influence the intensity of its physiological function [8].

Cyclodextrins (CDs) are polysaccharides composed of D-glucopyranose linked by α-1,4 glycoside bonds. CDs are classified as α, β, and γCD according to the number of D-glucopyranose units (6 to 8). In the safety assessment by the FAO/WHO Joint Expert Committee on Food Additives (JECFA), the acceptable daily intake (ADI) was defined as ‘‘up to 5 mg/kg/day’’ for βCD. In the background review for cyclodextrins used as excipients (CPMP/463/00 Revi.1), the total daily dose for alpha and gamma CD is fixed to 6000 and 10000 mg/day, respectively. At high concentration, CDs can induce laxative effect due to osmotic activity. CDs present a hydrophobic cavity due to the ether group located inside cavity, while the outer ring is hydrophilic. CDs form inclusion complexes via hydrophobic interactions [9]. The secondary hydroxyl groups (C2-OH and C3-OH) of CDs are located on the broad annular rim, while the primary hydroxyl group (C6-OH) is located on the narrow annular rim. The C2 and C3 hydroxyl groups of CD form hydrogen bonds between adjacent glucose units. On the other hand, the C6-OH group presents free rotation. The adsorption of water molecules is faster in βCD than in αCD and γCD owing to their different number of glucose units [10]. The crystalline structure (channel-type, cage-type, etc.) of CD complexes has also been studied. For example, the crystalline structure of αCD/polyethylene glycol complex has been reported to present a channel-type arrangement, while βCD/propylene glycol displays a channel-type (head-to-head or head-to-tail) or cage-type structure, and γCD/salicylic acid or γCD/flurbiprofen complexes exhibit channel-type (tetragonal, hexagonal, and monoclinic) arrangements [1114]. The van der Waals forces and hydrogen bonds in the crystal structure of CD complexes have been reported to vary with the moisture and inclusion conditions [13]. In addition, a variety of methods, such as ground-mixing, freeze drying, and coprecipitation, are available for the preparation of inclusion complexes [15, 16]. The preparation of inclusion complexes using ground mixtures (GMs) is easy by exploiting mechanochemical effects. Inclusion complexes with molar ratios of PP/αCD = 1/2, PP/βCD = 1/1, and PP/γCD = 1/1 prepared by such ground-mixing methods were found to exhibit different dissolution behavior in distilled water [17, 18]. However, to date, the factors contributing to the molecular conformation of PP in PP/CD complexes have not been evaluated in detail.

Solid-state fluorescence spectroscopy is a well-known method for the evaluation of the inclusion behavior of guest components [19]. Such measurements allow the elucidation of the molecular conformation of a guest molecule inside the CD cavity, either as a monomer or excited dimer. For example, changes in molecular morphology due to interaction of 2,5-diphenyloxazole/γCD complexes have been evaluated by solid fluorescence measurement [20]. Therefore, solid-state fluorescence measurements are important for understanding the fluorescence properties that are closely related to conformation and sequence of molecules. However, to date, the molecular behavior of PP in the solid state has not been comprehensively evaluated. Therefore, in this study, the molecular behavior of PP in different PP/CD inclusion complexes (humidified, heated, and humidified-heated samples) was evaluated by detailed solid-state fluorescence measurements.

2. Materials and Methods

2.1. Materials

PP was purchased from FUJIFILM Wako Pure Chemical Co., Ltd. αCD, βCD, and γCD were kindly donated by CycloChem Co., Ltd. (Tokyo, Japan), and used after storage at 40°C with a relative humidity (RH) of 82% for seven days. The humidity was controlled to obtain αCD 6.6-hydrate, βCD 10.5-hydrate, and γCD 12-hydrate (Figure 1). All the other chemicals were used as received from FUJIFILM Wako Pure Chemical Co., Ltd.

2.2. Preparation of Inclusion Complexes

The molar ratio of PP/CD inclusion complexes has been previously reported to be PP/αCD = 1/2, PP/βCD = 1/1, and PP/γCD = 1/1, as obtained by the ground mixture method [17, 18]. Thus, PP/CD complexes were prepared at those optimal inclusion molar ratios. GMs were prepared by grounding the samples (1.0 g) for 60 min using a vibration rod mill (TI-500ET, CMT Co.) at molar ratios of PP/αCD 6.6-hydrate = 1/2, PP/βCD 10.5-hydrate = 1/1, and PP/γCD 12-hydrate = 1/1. Humidified GM (PP/CD) samples were prepared by humidifying (40°C, RH = 82%) the GMs for one week. Also, heated GM (PP/CD) samples were prepared by drying the GMs for 24 h at 105°C under vacuum (100 mbar abs.). Using a vacuum sample drying apparatus (VSD-95, ISHII SHOTEN Co.) humidified-heated GMs were prepared by humidifying (40°C, RH = 82%) the samples for one week, followed by drying for 24 h at 105°C under vacuum. Such humidified, heated, and humidified-heated GM (PP/CD) samples were prepared to evaluate the inclusion mechanisms in great detail.

2.3. Thermogravimetry (TG) Measurements

The thermal behavior of PP, CDs, and GMs was investigated by Thermo Gravimetry Analyzer (Thermo Plus Evo, Rigaku) under N2 gas flow rate of 200 mL/min and heating rate of 5°C/min. The samples (~5 mg) were placed in aluminum pans.

2.4. Solid-State Fluorescence Measurements

Fluorescence spectra in the solid state were recorded on a fluorescence spectrophotometer (RF-5300pc, Shimadzu). The measurement conditions were an excitation wavelength of 360 nm, excitation and fluorescence bandwidth of 5 nm, and measurement range from 380 to 600 nm.

2.5. Powder X-Ray Diffraction (PXRD) Measurements

The changes in the crystal diffraction pattern of the samples were observed using a powder X-ray diffractometer (MiniFlex II, Rigaku). The irradiation source was a Cu wire. The diffraction intensity was measured with NaI scintillation counter. Measurements were carried out at a voltage of 30 kV, current of 15 mA, scan range of 2θ = 3–35°, and scan rate of 4°/min.

2.6. Near-Infrared (NIR) Absorption Spectroscopy Measurements

NIR absorption spectra were recorded using a Fourier transform NIR spectrophotometer (NIRFlex N-500, Buchi). The measurement wavelengths and wavenumbers ranged from 1000 to 2500 nm and from 10000 to 4000 cm−1, respectively. The resolution was 8 cm−1 at a measurement temperature of 25°C. The second derivatives of the spectra were calculated.

3. Results and Discussion

3.1. Evaluation of Thermal Decomposition

TG measurements were performed to evaluate the thermal stability and weight losses of PP upon complex formation (Figure 2). The weight loss of free PP was observed at ~130°C. In addition, the weight loss for GM (PP/αCD = 1/2), GM (PP/βCD = 1/1), and GM (PP/γCD = 1/1) over the 50–100°C range was determined to be 3.7%, 4.1%, and 5.0%, respectively. The water loss from CD has been reported to occur up to 110°C [21]. Therefore, said weight losses in the inclusion complexes were concluded to arise from evaporation of the adsorbed water on the CDs. The weight of GM (PP/αCD = 1/2) decreased by 77.2% between 181 and 400°C, while that of GM (PP/βCD = 1/1) decreased by 78.7% in the same range. The weight of GM (PP/γCD = 1/1) dropped by 77.6% between 216 and 400°C. It has been reported that the decomposition temperature of the guest component increases when a complex is formed [22]. The PP weight losses for the PP/CD complexes were observed at temperatures higher than that for free PP (130°C). Since the decomposition temperature of GM (PP/γCD = 1/1) is higher than those of GM (PP/αCD = 1/2) and GM (PP/βCD = 1/1), it is suggested that GM (PP/γCD = 1/1) is able to suppress more effectively the decomposition of PP.

3.2. Evaluation of the Steric Behavior of Molecules

Depending on the molecular orientation of molecules in the solid state, the fluorescence wavelength is shifted by the energy difference from the excited state to the ground state [23]. There is a report that the fluorescence intensity decreases as the intermolecular interaction increases [24]. In addition, the oscillator strength affects the fluorescence intensity [25]. The greater the vibration and rotational motion of the molecule are, the more the energy of the excited electrons is consumed, so the fluorescence intensity decreases. That is, the solid-state fluorescence measurement is important for understanding the fluorescence characteristics closely related to the conformation and arrangement of molecules. Therefore, solid-state fluorescence measurements were carried out to determine whether the fluorescence wavelength would change with the different molecular behavior of PP. The fluorescence maximum of PP and PP ground was observed at 459 nm (Figure 3). On the other hand, the fluorescence maxima of the inclusion complexes GMs (PP/αCD = 1/2, PP/βCD = 1/1, and PP/γCD = 1/1) were observed at 463, 472, and 469 nm, which are shifted to longer wavelengths compared to that of PP alone (Figures 3(c), 3(d), and 3(e)). Since the fluorescence maximum of PP shifts to longer wavelengths, it can be concluded that the electron resonance state (intramolecular charge) of PP changes upon interaction with the CD molecules [26]. According to the PP single crystal data reported by Pfund et al. (2015), the PP electrons resonate from the amide group to the ether group of the methylenedioxyphenyl moiety. Moreover, increased bond rotation around the amide or carbonyl group has been reported as the resonance state changes [27]. That is, the electrons donated by the nitrogen of PP are not transferred to the ether group, and an energy change occurs. Furthermore, the intermolecular interactions between adjacent molecules are suppressed and the fluorescence intensity increases upon changing into a molecular arrangement in which the overlap of π-conjugate planes is small.

In the αCD systems, the fluorescence maxima of the GM (PP/αCD = 1/2) and heated GM (PP/αCD = 1/2) samples were observed at 463 and 457 nm, respectively. On the other hand, the humidified and humidified-heated GM (PP/αCD = 1/2) samples exhibited maxima at 454 and 455 nm, respectively, which are shifted to shorter wavelengths compared to that of GM (PP/αCD = 1/2) (Figure 4(a)). In the fluorescence spectra of GM (PP/αCD = 1/2), humidified GM (PP/αCD = 1/2), and humidified-heated GM (PP/αCD = 1/2), the donation of the nitrogen group of PP changes upon coordination of water molecules, which contributes to a fluorescence change for the complexes with αCD.

In the βCD systems, the fluorescence maxima of GM (PP/βCD = 1/1) and heated GM (PP/βCD = 1/1) are observed at 472 and 462 nm, respectively. In addition, the humidified and humidified-heated GM (PP/βCD = 1/1) samples exhibit maxima at 460 and 455 nm, respectively, which are shifted to shorter wavelengths relative to that of the untreated GM (Figure 4(b)). It was thus concluded that the molecular behavior of PP in GM (PP/βCD = 1/1) and humidified GM (PP/βCD = 1/1) contributes to fluorescence quenching. In the fluorescence spectra of the untreated, humidified, and humidified-heated GM (PP/βCD = 1/1) samples, the donation of the nitrogen group of PP changes upon coordination of water molecules, contributing to changes in the fluorescence properties of the βCD complexes.

In the γCD systems, the fluorescence maxima of the untreated, heated, and humidified-heated GM (PP/γCD = 1/1) samples were observed at 469 nm. On the other hand, humidified GM (PP/γCD = 1/1) exhibited a maximum at 465 nm, slightly shifted toward shorter wavelengths relative to the value for the untreated GM (Figure 4(c)). Since the maximum fluorescence wavelength of GM (PP/γCD = 1/1) is similar to that of humidified and humidified-heated GM (PP/γCD = 1/1) samples, the molecular behavior is also similar. Therefore, it can be speculated that the conformation of PP molecules in humidified crystalline PP/CD inclusion complexes changes depending on the size of the CD cavity, where the coordination of water also contributes to the overall effect.

3.3. Examination of the Crystalline State

PXRD measurements confirmed the changes in the crystalline state of PP/CD complexes upon coordination of water molecules. The pattern of pure PP exhibits characteristic diffraction peaks at 2θ = 14.7° and 25.6°. In the TG measurement, since CD included PP, no weight loss of PP's residual crystals was confirmed in various complexes. it is reported that the melting point of PP alone disappears due to the formation of PP/CDs complex. Also, the PXRD pattern of PP and PP ground has been reported to be the same diffraction peak [17, 18]. It has been reported that PP/αCD, PP/βCD, and PP/γCD inclusion complexes prepared by ground-mixing afford a halo pattern [17, 18]. The heated, humidified, and humidified-heated GM (PP/CD) samples were used to identify changes in the diffraction patterns of the complexes.

In the αCD system, the diffraction profiles of the untreated and heated GM (PP/αCD = 1/2) systems exhibit a halo pattern (Figures 5(b) and 5(c)), while humidified GM (PP/αCD = 1/2) presents diffraction peaks at 2θ = 10.3°, 12.7°, and 19.6° suggesting a channel-type arrangement (Figure 5(d), Scheme 1). The humidified-heated GM (PP/αCD = 1/2) sample exhibits the characteristic diffraction peak of a dried channel-type structure (where both head-to-head and head-to-tail arrangements are mixed) at 2θ = 11.7° (Figure 5(e), Schemes 1(b) and 1(c)) [12]. No peaks corresponding to PP alone are observed in the humidified GM (PP/αCD = 1/2) and humidified-heated GM (PP/αCD = 1/2) pattern. It was suggested that there were few residual crystals of PP (Figures 5(d) and 5(e)). It was thus concluded that the fluorescence spectra of the humidified and humidified-heated GM (PP/αCD = 1/2) samples show similar features of a channel-type structure despite the different coordination of water molecules.

In the βCD system, the diffraction pattern of GM (PP/βCD = 1/1) presents a halo profile (Figure 5(f)). The pattern of the heated GM (PP/βCD = 1/1) sample shows the characteristic peak of PP at 2θ = 14.7° (Figure 5(g)). It is suggested that the PP/βCD complex dissociates into PP and βCD to some extent under heating. Such PP peak is not observed for the humidified GM (PP/βCD = 1/1) sample; however, the diffraction pattern shows the characteristic diffraction peaks of head-to-tail βCD at 2θ = 11.9°, 15.2°, and 17.5° (Figure 5(h)) [13, 14]. GM (PP/βCD = 1/1) changed from an amorphous state to a regular crystal sequence of head-to-tail by water molecules coordinating. Humidified GM (PP/βCD = 1/1) was shifted to the short wavelength compared with GM (PP/βCD = 1/1) (Figure 4(b)). This change suggests that the nitrogen donating property and motility of PP influence the molecular morphology and behavior because the molecular arrangement is different. The diffraction peak of CDs is influenced by the coordination of water molecule. It contributed to the interaction with PP, possibly affecting fluorescence. Furthermore, the humidified-heated GM (PP/βCD = 1/1) sample exhibits the characteristic diffraction peaks of a cage-type arrangement at 2θ = 11.9° and 17.9° (Figure 5(i)). That is, the humidified GM (PP/βCD = 1/1) sample changes from a head-to-tail structure to a cage-type one under heating. No peaks corresponding to PP alone are observed in the humidified GM (PP/βCD = 1/1) and humidified-heated GM (PP/βCD = 1/1) pattern. It was suggested that there were few residual crystals of PP. The humidified GM (PP/βCD = 1/1) sample is therefore concluded to involve an inclusion structure that readily changes upon adsorption of water molecules in the crystal.

In the γCD system, the diffraction profile of GM (PP/γCD = 1/1) shows a halo pattern (Figure 5(j)). No peaks corresponding to PP alone are observed in the heated GM (PP/γCD = 1/1) pattern, but diffraction peaks corresponding to mixed hexagonal-type (2θ = 5.9°) and monoclinic-type (2θ = 16.7°) structures (Figure 5(k)) are discerned [15]. The characteristic diffraction pattern of the inclusion complex was thus confirmed. The humidified GM (PP/γCD = 1/1) sample was found to exhibit the characteristic diffraction peaks for tetragonal-type (2θ = 7.5°, 16.6°, and 21.4°), monoclinic-type (2θ = 5.6°), and hexagonal-type (2θ = 15.8°) arrangements (Scheme 1(f), Figure 5(l)). Furthermore, the pattern of humidified-heat GM (PP/γCD = 1/1) shows the characteristic diffraction peaks of hexagonal-type (2θ = 6.0°), tetragonal-type (2θ = 7.5°), and monoclinic-type (2θ = 16.7°) structures (Figure 5(m)). Tetragonal-type of γCD complexes has been reported to change into hexagonal or monoclinic-type structures by decreasing crystalline water [15]. However, the diffraction peaks for the heated, humidified, and humidified-heated GM (PP/γCD = 1/1) samples were those corresponding to mixed tetragonal-type, hexagonal-type, and monoclinic-type structures. No peaks corresponding to PP alone are observed in the humidified (PP/γCD = 1/1) and humidified-heated (PP/γCD = 1/1) pattern. Even if PP residual crystals remain, they are very few. The γCD complex exists in a disordered and distorted state due to the influence of the PP conformation, and it is therefore expected that sublimation of the crystallized water located between the γCD molecules and the subsequent progression from amorphous to crystalline state are difficult.

3.4. Examination of Intermolecular Interactions in Different Inclusion Complexes

In the TG measurements, the weight loss of PP was found to be suppressed upon formation of the PP/CD complexes. In the PXRD measurements, the crystal diffraction pattern of the PP/CD complexes was found to depend on the relative humidity and heating conditions. Thus, NIR spectroscopy would be the optimal method to evaluate the presence of free water in the solid state without interference from the included water molecules, where the stretching vibrations of OH and CH groups can be easily evaluated [28]. The CH2 bands of PP were observed at 5712, 5920, 8364, and 8668 cm−1. In addition, the CH bands of the conjugated double bond of the geometric isomer of PP were also found at 5848, 6004, and 8456 cm−1. Finally, the band corresponding to the aromatic CH moiety of PP was observed at 8816 cm −1 (Figures 68).

In the αCD system, the CH2 band (8364 and 8668 cm−1) of GM (PP/αCD = 1/2) was shifted to lower wavenumbers (8352 and 8648 cm−1) and the molecular vibrations of the conjugated diene and aromatic CH (8456 and 8816 cm−1) were decreased compared to those of PP alone. Thus, the molecular behavior of PP was confirmed to change upon complex formation (Figure 6(a)). In addition, the CH2 vibration bands (8364 and 8668 cm−1) of GM (PP/αCD = 1/2) decreased and those corresponding to conjugated diene and aromatic CH moieties (8456 and 8816 cm−1) were broader compared to those of PP alone. The mobility of the PP molecule therefore decreases upon changing from amorphous GM (PP/αCD = 1/2) to the columnar structure of humidified GM (PP/αCD = 1/2). It was concluded that the changes in the mobility of PP are influenced by distance of the αCD molecules allowing the formation of hydrogen bonds. Furthermore, the CH2 band (8456 cm−1) of the conjugated diene of GM (PP/αCD = 1/2) shifts to a lower wavenumber (8428 cm−1) compared to that of humidified GM (PP/αCD = 1/2) with a head-to-head crystal structure. The humidified-heated GM (PP/αCD = 1/2) sample exhibits the characteristic diffraction pattern of a dried channel-type structure (mixed head-to-head and head-to-tail) (Figures 5(d) and 5(e)). In the NIR measurements, the CH2 and aromatic CH bands of humidified and humidified-heated GM (PP/αCD = 1/2) were broader than those of GM (PP/αCD = 1/2) (Figure 6(a)). It is suggested that the molecular mobility of the conjugated diene of PP in humidified-heated GM (PP/αCD = 1/2) decreases owing to a reduction of the hydrogen bond length as αCD molecules become closer, fixing the PP molecules. That is, the resonance states of humidified and humidified-heated GM (PP/αCD = 1/2) change due to the interaction between the methylenedioxyphenyl group (aromatic ring moiety) of PP and αCD, and the fluorescence wavelength of PP shifts to shorter wavelengths (Scheme 2(b)).

In the βCD system, the CH2 bands (8364 and 8668 cm−1) of the conjugated diene of GM (PP/βCD = 1/1) shift to lower wavenumbers (8344 and 8652 cm−1) compared to those of PP alone. In addition, the absorption band (8816 cm−1) of the aromatic CH of GM (PP/βCD = 1/1) decreases compared to that of PP alone. The molecular behavior of PP was observed to change upon complex formation (Figures 7(a) and 7(c)). The absorption intensity of the CH2 bands (5712 and 5920 cm−1) of humidified GM (PP/βCD = 1/1) decreases, and the aromatic CH band (8816 cm−1) shifts to a higher wavenumber (8832 cm−1) relative to that of PP alone. The molecular mobility of PP is reduced upon changing from amorphous GM (PP/βCD = 1/1) to the columnar structure of humidified GM (PP/βCD = 1/1). It is concluded that the molecular mobility of PP decreases due to the formation of hydrogen bonding between βCD and changes in the van der Waals forces. In addition, the CH band (5848 cm−1) corresponding to the conjugated diene of humidified-heated GM (PP/βCD = 1/1) was broader than that of humidified GM (PP/βCD = 1/1). Since the humidified-heated GM (PP/βCD = 1/1) sample exhibits the crystal diffraction pattern of a cage-type structure, it is considered that the distance between βCD units is reduced compared to that in humidified GM (PP/βCD = 1/1) and that the molecular mobility of the conjugated diene of PP is subsequently also reduced. From the solid-state fluorescence measurements, the resonance state of the humidified and humidified-heated GM (PP/βCD = 1/1) samples is concluded to change under the interaction of the methylenedioxyphenyl CH band (5848 cm−1) of PP, which shifts to shorter wavelengths. Furthermore, when the CH band (5848 cm−1) of the conjugated diene of humidified-heated GM (PP/βCD = 1/1) broadens, its fluorescence maximum wavelength shifts toward those of humidified and humidified-heated GM (PP/αCD = 1/2). That is, the molecular mobility of the methylenedioxyphenyl group and conjugated diene CH is strongly suppressed upon PP interaction with the CD; the said PP molecular behavior contributes to fluorescence quenching (Scheme 2(c)).

In the γCD system, the CH2 bands (8364 and 8668 cm−1) and the conjugated diene CH bands (5848 and 8456 cm−1) of GM (PP/γCD = 1/1) broaden and shift to lower wavenumbers (8448 cm−1) compared to those of unprocessed PP (Figures 8(a) and 8(c)). Moreover, the aromatic CH band (8816 cm−1) of GM (PP/γCD = 1/1) shifts to higher wavenumbers (8828 cm−1) (Figure 8(a)). Suppression of the molecular mobility of PP thus occurs upon complex formation. The absorption intensity of the CH2 bands (5712, 8364, and 8668 cm−1) of humidified GM (PP/βCD = 1/1) decreases, and the aromatic CH band (8816 cm−1) shifts to a higher wavenumber relative to that of PP alone (Figures 8(a) and 8(c)). Changes in the molecular mobility of PP arise upon moving from the amorphous structure of GM (PP/γCD = 1/1) to the columnar arrangement of humidified GM (PP/γCD = 1/1). It is concluded that the changes in the molecular mobility of PP are influenced by the formation of hydrogen bonding between γCD molecules and changes in the van der Waals forces. The interaction between PP methyl group and CD hydroxyl group in humidified-heated GM (PP/γCD = 1/1) is similar to that observed in humidified GM (PP/γCD = 1/1). Therefore, it was confirmed that, in γCD with a large annular size, the molecular behavior of PP in the channel-type inclusion structure is not remarkably suppressed (Scheme 2(d)). The molecular mobility of PP is reduced upon changing from the amorphous GM (PP/CD) systems to the columnar structures of the humidified GM (PP/CD) samples. The mobility of PP does not change even with changes in the crystal structure of humidified-heated GM (PP/γCD), which is a dried humidified GM (PP/γCD) sample. On the other hand, the motility of PP was confirmed to easily change in humidified-heated GM (PP/αCD = 1/2) and humidified-heated GM (PP/βCD = 1/1). Therefore, it was confirmed that the molecular behavior of PP varies depending on the ring size. It is reported that the stability constant of PP/CD systems increases in the order αCD < βCD < γCD [18]. The stability constant is a representation of the distance between the hydroxyl group of the ether group of PP and the cavity diameter of CD and the ability to form hydrogen bond. The molecular behavior of PP in these crystal structures is shown to be fixed in the cases of αCD and βCD.

3.5. Influence of CD-Containing Water Molecules and Evaluation of OH Group Interactions

The influence of the water molecules adsorbed on the CDs and the interactions of the OH groups were evaluated by NIR spectroscopy. Since PP bears no OH groups and is a lipophilic drug, bands corresponding to water molecules and hydroxyl groups were not observed in its spectrum in the ranges of 5300–5000 and 7200–6900 cm−1 (Figures 68). In the case of αCD, C2-OH (5180, 7056 cm−1), C6-OH (6984 cm−1), and free water (5244 cm−1) bands were observed (Figures 6(b) and 6(d)). The C2-OH of βCD tends to adsorb water molecules, for which a band is observed at 5188 cm−1 (Figure 7(d)). In contrast, it was difficult to evaluate the C2-OH bands in the 7200–6900 cm−1 region. In addition, bands for the C6-OH moiety (6960 cm−1) and free water (5256 cm−1) in βCD were observed. γCD has a noncoplanar and more flexible structure and the OH groups can be easily approached by water molecules [29]. Therefore, the C2-OH (5164 and 7024 cm−1), C6-OH (6972 cm−1), and free water (5240 cm−1) bands are all observed in the spectrum of γCD (Figures 8(b) and 8(d)).

In the αCD system, the free water bands for GM (PP/αCD = 1/2) decrease compared to those of αCD alone (Figure 6(d)). The bands for C2-OH (5180 and 7056 cm−1) and C6-OH (6984 cm−1) were broadened and that of C2-OH (7056 cm−1) was shifted to lower wavenumbers (7032 cm−1). It has been reported that the four units of glucose of αCD present hydrogen bonding between the C2-OH and C3-OH moieties. The bands corresponding to C2-OH, C6-OH, and free water in the case of humidified GM (PP/αCD = 1/2) were broader than those of GM (PP/αCD = 1/2) (Figures 6(b) and 6(d)). It is suggested that αCD forms a hydrogen bonding network with other αCD molecules in addition to PP. The C2-OH band (7056 cm−1) of humidified-heated GM (PP/αCD = 1/2) was broader and slightly shifted to lower wavenumbers compared to that of humidified GM (PP/αCD = 1/2). Therefore, it is suggested that the distance between αCD molecules decreases and stronger hydrogen bonds are formed with the decreasing number of water molecules.

In the βCD system, the band corresponding to free water in the case of GM (PP/βCD = 1/1) decreased compared to that for βCD alone. Furthermore, the C2-OH band was observed at 7032 cm−1 and that of C6-OH disappeared at 6960 cm−1 (Figures 7(b) and 7(d)). βCD presents strong hydrogen bonding between the C2-OH and C3-OH moieties of glucose, and the absorption intensity decreases upon adsorption of water molecules, reducing the molecular mobility of βCD. That is, the adsorption of water molecules on the C2-OH moieties of GM (PP/βCD = 1/1) decreases upon inclusion of PP in the βCD cavity. The free water band (5256 cm−1) of humidified GM (PP/βCD = 1/1) decreases and the C2-OH band (7032 cm−1) becomes sharper compared to those of GM (PP/βCD = 1/1). Therefore, the reduction of the number of water molecules and C2-OH band suggests the formation of hydrogen bonding between PP and βCD and between βCD molecules. In addition, the free water band (5256 cm−1) of humidified-heated GM (PP/βCD = 1/1) decreases and the C2-OH band (7032 cm−1) shifts to higher wavenumbers (7028 cm−1) relative to those of humidified GM (PP/βCD = 1/1). The cage-type structure, which is the crystal structure of βCD complexes, has been reported to exhibit strong van der Waals forces and weak hydrogen bonding, and the head-to-tail column-type has been associated with weak van der Waals forces and moderate hydrogen bonding [13]. Therefore, the C2-OH band of humidified-heated GM (PP/βCD = 1/1) shifts to higher wavenumbers due to the weakening of hydrogen bonding.

In the γCD system, the C6-OH band (6972 cm−1) of GM (PP/γCD = 1/1) broadens and shifts to lower wavenumbers, while the C2-OH band (5164, 7024 cm−1) broadens and shifts to higher wavenumbers (7040 cm−1) compared to those of γCD alone (Figures 8(b) and 8(d)). It was inferred that the hydrogen bonding via the C2-OH moieties of GM (PP/γCD = 1/1) decreases upon complex formation and that hydrogen bonding between C6-OH and PP is established. The humidified GM (PP/γCD = 1/1) sample exhibits broadband for the C6-OH (6972 cm−1) and C2-OH (5164 and 7024 cm−1) moieties, while the free water band of γCD decreases compared to that of GM (PP/γCD = 1/1). That is, a hydrogen bond network is generated between γCD molecules. The free water band of humidified-heated GM (PP/γCD = 1/1) is similar to that of humidified GM (PP/γCD = 1/1). However, the C2-OH band (7024 cm−1) shifts to lower wavenumbers (7020 cm−1) compared to that of humidified GM (PP/γCD = 1/1), and so a difference in the molecular mobility is noted. Since the C2-OH band shifts to higher wavenumbers, it is inferred that the hydrogen bonding extent decreases due to changes in the crystal structure. The CH group (aromatic and conjugated diene) mobility in humidified GM (PP/γCD = 1/1) is similar to that in humidified-heated GM (PP/γCD = 1/1). However, it was confirmed that the C2-OH molecular behavior in humidified GM (PP/γCD = 1/1) is different (Figure 8). Even when changing from GM (PP/γCD = 1/1) to humidified GM (PP/γCD = 1/1) and humidified-heated GM (PP/γCD = 1/1), the motility of the aromatic ring CH of the methylenedioxyphenyl group of PP embedded in γCD does not change. Moreover, even if the crystal structure of the γCD complex changes, the molecular mobility of the aromatic CH of the methylenedioxyphenyl group of PP is not suppressed compared to that in the αCD and βCD complexes. The reason behind this lies in differences in the moisture adsorption and crystallization of αCD, βCD, and γCD. The maximum fluorescence wavelengths of humidified and humidified-heated αCD and βCD inclusion complexes shift toward that of PP alone. The reason is that the molecular motion of the aromatic ring CH of the methylenedioxyphenyl group of PP is fixed inside αCD and βCD, contributing to changes in the electron resonance. Therefore, solid fluorescence and NIR measurements have demonstrated that the molecular behavior of PP is influenced by the presence or absence of water molecules in the CD structure.

4. Conclusions

By solid-state fluorescence measurements, it was demonstrated that the conformation of PP inside α, β, and γCD is influenced by the resonance from the nitrogen group to the ether group upon coordination of water. Moreover, it was revealed that the γCD complexes are disordered and distorted in nature due to the influence of the conformation of PP, resulting in a mixture of crystal structures, as compared to the systems with αCD and βCD. The molecular behavior of PP inside CD changes its fluorescence behavior by suppressing the motion of the aromatic CH center of the methylenedioxyphenyl group. Furthermore, molecular behavior of PP also varies with the coordination of water and the cavity size. Therefore, from the results of solid-state fluorescence and NIR measurements, it has been demonstrated that the transfer of electrons from the nitrogen group to the ether group depends on the mobility of the aromatic CH moiety of the methylenedioxyphenyl group. The detailed molecular behavior of PP in these complexes has thus been revealed.

Abbreviations

PP:Piperine
CD:Cyclodextrin
GM:Ground mixture
PM:Physical mixture
RH:Relative humidity
(PP/CD):GM (PP/CD) sample humidified (40°C, RH = 82%) for one week
(PP/CD):GM (PP/CD) sample dried for 24 h at 105°C under vacuum
Humidified-heated :GM (PP/CD) sample humidified (40°C, RH = 82%) for one week, followed by drying for 24 h at 105°C under vacuum
C2-OH:Hydroxyl group attached to the carbon at position 2 of glucose
C6-OH:Hydroxyl group attached to the carbon at position 6 of glucose
TG:Thermogravimetry
PXRD:Powder X-ray diffraction
NIR spectroscopy:Near-infrared spectroscopy.

Data Availability

The data used to support the findings of this study are included within the article. Previously reported data were used to support this study and are available at DOI: 10.1155/2016/8723139 and DOI: 10.1208/s12249-017-0908-9. These prior studies are cited at relevant places within the text as [17, 18].

Conflicts of Interest

The authors declare no conflicts of interest.

Acknowledgments

The authors wish to acknowledge CycloChem Co., Ltd., for kindly donating α, β, and γCD and thank Dr. Toshiyasu Tarumi at Buchi Labortechnik AG for providing support during the NIR spectroscopy measurements.