Synthesis of a water-soluble 2,2′-biphen[4]arene and its efficient complexation and sensitive fluorescence enhancement towards palmatine and berberine

A water-soluble 2,2′-biphen[4]arene (2,2’-CBP4) containing eight carboxylato moieties was synthesized and characterized. Its complexation behavior towards two alkaloids, palmatine (P) and berberine (B), was investigated by means of fluorescence and 1H NMR spectroscopy in aqueous phosphate buffer solution (pH 7.4). In the presence of 2,2’-CBP4, 1H NMR signals of P and B displayed very large upfield shifts, indicating the formation of inclusion complexes with strong binding affinities. Fluorescence titration experiments showed that P and B exhibited dramatic fluorescence enhancement of more than 600 times upon complexation with 2,2’-CBP4. Particularly, the fluorescence intensity is strong enough to be readily distinguished by the naked eye. Although the two guests have similar structures, the association constant of B with 2,2’-CBP4 (Ka = (2.29 ± 0.27) × 106 M−1) is 3.9 times larger than that of P (Ka = (5.87 ± 0.24) × 105 M−1).

For example, our group demonstrated a direct host-guest complexation-based drug delivery system for oxaliplatin by carboxylatopillar [6]arene [36]. The encapsulation could not only improve the drug's stability in the blood stream, but also be effectively dis-assembled in the acidic tumor environment, and thus improve the anticancer activity of oxaliplatin in vivo.
To date, the complexation of biological and pharmaceutical molecules by biphen[n]arenes in water have not been reported.
In this work, we wish to report the synthesis of the first watersoluble 2,2'-biphen [4]arene bearing multiple carboxylato moieties, 2,2'-CBP4 (Scheme 1), and its binding behavior and fluorescent spectrum characteristic towards two alkaoilds, palmatine (P) and berberine (B), in water solution. In particular, the fluorescence intensities of the two guests have been considerably enhanced after complexation. As a member of isoquinoline alkaloids' family, P and B can produce singlet oxygen ( 1 O 2 ) and oxide biological substrates under light, and thereby have applications in photodynamic therapy (PDT) [48][49][50]. However, their low quantum yields limit such applications, which could be potentially improved or restored by the present encapsulation-induced fluorescence enhancement.

H NMR spectra
1 H NMR experiments of P and B with 2,2'-CBP4 in deuterated phosphate buffer (pD 7.4) were carried out to examine the host-guest complexation (Figure 1 and Figure S9 in Supporting Information File 1). From Figure 1, upon addition of the host, all the peaks of alkaloid B displayed upfield shifts and broadening compared with the free guest. Especially, the chemical shifts for the middle protons, H1-6 , and H10-11, are larger than those for the ending H7-9. These results indicate that berberine was engulfed by the cavity of 2,2'-CBP4 to form a pseudorotaxane-type inclusion complex. Similar complexation-induced NMR changes were observed for the host-guest mixture of P and 2,2'-CBP4 (Supporting Information File 1, Figure S9), suggesting a similar binding mode of an inclusion complex.
The host-guest encapsulation was then confirmed by 2D NOESY experiments, as shown in Figures S10 and S11, Supporting Information File 1. For example, in the 2D NOESY spectra of host-guest mixture of 2,2'-CBP4 and B, NOE correlations were clearly observed between the middle protons H1 and H10 of B with the methylene H c of 2,2'-CBP4, and between the aromatic protons (H b ) of 2,2'-CBP4 and H2 of B (Supporting Information File 1, Figure S11).
To examine the fluorecence behavior and to quantitatively assess the complexation of the two alkaloids and 2,2'-CBP4, spectral titrations of P/B and 2,2'-CBP4 were performed in the phosphate buffer solution of pH 7.4 at 298 K. As can be seen from Figure 2 and Supporting Information File 1, Figure S10, compounds P and B alone only displayed fairly feeble fluorescence emission. Upon addition of 2,2'-CBP4, the fluorescence intensity was remarkably improved more than 600 times (Figure 2 and Supporting Information File 1, Figure S10). This was due to the effect of lowering polar microenvironment when P or B was included by 2,2'-CBP4; the guest emits stronger fluorescence in a more hydrophobic microenvironment [48]. Combined with NMR results, we can unambiguously conclude the alkaloid molecules must insert into the hydrophobic cavity of 2,2'-CBP4 to form inclusion complexes. Interestingly, the emission intensities can be easily identified by the naked eye under UV light of 365 nm. As can be seen from Figure 3, P, B and 2,2'-CBP4 alone are almost nonfluorescent; the host-guest mixture shows very strong yellow fluorescence.
Through analyzing the sequential changes about fluorescence intensity (ΔF) of guest that occurred with changes in host concentration, the association constants (K a ) could be calculated. The complexation stoichiometry for each binding event was de-  termined to be 1:1 by Job plot analysis (Supporting Information File 1, Figures S13 and S14). The nonlinear least-squares curvefitting method was used to analysis. For each host-guest pair, an excellent fit with an R value larger than 0.99 was obtained. It was found that 2,2'-CBP4 formed stable complexes with the two positively charged alkaloids, giving K a values of (5.87 ± 0.24) × 10 5 M −1 and (2.29 ± 0.27) × 10 6 M −1 for P and B, respectively. π···π interactions, hydrophobic interactions and electrostatic attractions should play important roles in the association process. Although having similar structures, these two guests gave very different association constants. The substitution of 1,3-dioxole for two methoxy groups in P, affording B, considerably increases the K a value of 3.9 times (Table 1). One possible reason is that the size of B with 1,3-dioxole, smaller than that for P with two methoxy groups, matches better with the cavity of 2,2'-CBP4.

Conclusion
In summary, we have synthesized a water-soluble 2,2'biphen [4]arene, 2,2'-CBP4, for the first time and studied its complexation towards two alkaloid guests, P and B. 1 H NMR and fluorescence results indicate the formation of inclusion complexes with strong stability. The association constants are in the magnitude of 10 5 -10 6 M −1 . Upon complexation with 2,2'-CBP4, both alkaloid guests exhibit a significant fluorescence intensity enhancement and the intensity is strong enough to be distinguished by the naked eye. The easy accessibility, good water-solubility and nice binding properties make 2,2'-CBP4 be applicable in the biomedical field, for example, chemical sensors, drug delivery, supramolecular amphiphiles, etc.
Experimental 2,2'-OEtBP4 was synthesized according to our previously reported method [47]. P and B were purchased from Shanghai Aladdin Bio-Chem Technology Co.,LTD. 1 H NMR and 13 C NMR spectra were recorded on a Bruker AV500 instrument. The fluorescence emission spectra were determined with a SHIMADZU RF5301 spectrometer. Deuterated phosphate buffer solutions (20 mM) of pD 7.4 for 1 H NMR experiments were prepared by mixing K 2 DPO 4 deuterium oxide solution (20 mM) and KD 2 PO 4 deuterium oxide solution (20 mM) according to the calculated volume ratios. The pH/pD values of the buffer solutions were verified on a pH-meter calibrated with two standard buffer solutions.

Supporting Information
Supporting Information File 1 Experimental details and the 1 H and 13 C NMR spectra of 2,2'-biphen [4]arene derivatives, additional 1 H NMR spectra of host-guest mixture, job plots, and the determination of the association constants.