Synthesis of Two Novel Homologous Polyphosphoesters Containing Aminophosphonate Units and Cytotoxicity of Some Low-Molecular and Polymeric Aminophosphonate Derivatives

Kraicheva, Ivanka; Momekov, Georgi; Mihaylova, Rositsa; Topashka-Ancheva, Margarita; Tsacheva, Ivelina; Stoineva, Ivanka; Vodenicharova, Elitsa; Nedialkov, Paraskev

doi:https://doi.org/10.1155/2018/9565401

Advances in Materials Science and Engineering

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Abstract Introduction Results and Discussion Conclusion Experimental Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2018 | Article ID 9565401 | https://doi.org/10.1155/2018/9565401

Synthesis of Two Novel Homologous Polyphosphoesters Containing Aminophosphonate Units and Cytotoxicity of Some Low-Molecular and Polymeric Aminophosphonate Derivatives

Ivanka Kraicheva,¹Georgi Momekov,²Rositsa Mihaylova,²Margarita Topashka-Ancheva,³Ivelina Tsacheva,¹Ivanka Stoineva,⁴Elitsa Vodenicharova,¹and Paraskev Nedialkov⁵

Academic Editor: Claudio Pettinari

Received28 Mar 2018

Revised18 Jun 2018

Accepted24 Jun 2018

Published13 Aug 2018

Abstract

Two novel polyphosphoesters containing anthracene- and furan-derived aminophosphonate moieties, namely, poly[oxyethylene(aminophosphonate-co-H-phosphonate)]s P-12 and P-13, were synthesized through an addition of poly(oxyethylene H-phosphonate) to 9-anthrylidene-furfurylamine and characterized. The novel polyphosphoester P-12 and a series of previously described anthracene-derived compounds including Schiff bases S-1 and S-2, α-aminophosphonates A-3–A-6, bis-aminophosphonate B-6, two enantiomers A-5a and A-5b, and polyphosphoesters P-8–P-11 containing aminophosphonate units were screened for antitumor activity against a panel of human leukemic cell lines, using cisplatin as a reference cytotoxic agent. As concluded from the cytotoxicity assays, both precursors S-1 and S-2 presented similar cytotoxicity profiles that are cisplatin-like only in the REH cell line. Leader compound of the α-aminophosphonates is A-4 with cell death-inducing properties fully equaling those of the referent drug in all of the screened leukemic cell lines with the only exception being the AML histological subtype HL-60. Some of the polymeric analogues elicited moderate (P-10 and P-12) to low (P-11) cytotoxic activity, whereas the polyphosphoesters P-8 and P-9 produced in vitro antitumor effects largely surpassing cisplatin’s. The compounds P-8, P-9, and A-4 could be potential new materials for anticancer therapeutic purposed.

1. Introduction

The aminophosphonic acid derivatives are an interesting class of biologically active compounds, which possess diverse and useful properties, including herbicidal, antibacterial, antiviral, and antitumor activity [1–3]. They have found important applications, especially in the field of medicine and agriculture [1, 4, 5]. Thus, bisphosphonates are widely used in the treatment of cancer-induced bone diseases [6, 7]. They inhibit osteoclastic bone resorption and delay the further progression of bone metastases [7, 8]. The in vitro studies have revealed that the nitrogen-containing bisphosphonates (zoledronic acid, pamidronate, and incadronate) exert direct cytostatic and proapoptotic effects on human tumor cell lines, as myeloma, breast, prostate, and pancreas cancer cell lines [7, 8]. Radiolabelled complexes of aminophosphonate derivatives are used for diagnosis and treatment of tumors in humans and animals [4, 9, 10]. A number of novel aminophosphonate derivatives bearing heterocycles [11–15], dehydroabietic acid moiety [16], diacerein conjugates [17], and bis-CF₃ group [18] have been synthesized and evaluated for antitumor activity against different human cancer cell lines [11–18]. According to the data reported, many of these compounds show quite promising cytotoxic activity against the corresponding human cancer cell lines used in the biological assays [11, 12, 14–18].

The immobilization of aminophosphonate moieties to biodegradable polymer carriers is an effective way for the formation of new type of polymer prodrugs with improved properties [19, 20]. The polymer-drug conjugates seem to hold great potential to circumvent major disadvantages of the conventional drug therapy [21, 22].

Polyphosphoesters comprise a class of biodegradable and biocompatible phosphorus-containing polymers [23]. They degrade into nontoxic products through hydrolysis and enzymatic cleavage of their phosphoester bonds under physiological conditions [22, 24]. The poly(alkylene H-phosphonate)s contain reactive P-H groups, which allow for the chemical attachment of drug molecules to the polymer chain [22, 23].

In the present study, we report on the synthesis and spectroscopic characterization of two novel homologous polyphosphoesters containing anthracene- and furan-derived aminophosphonate units. One of them was evaluated for cytotoxicity against a panel of human leukemic cell lines, including HL-60, SKW-3, REH, and K-562 cells.

Low-molecular and polymeric aminophosphonates, synthesized earlier [20, 25–28], were also studied against the same tumor cell lines.

2. Results and Discussion

2.1. Chemistry

Novel homologous polyphosphoesters, namely, poly[oxyethylene (aminophosphonate-co-H-phosphonate)]s P-12 and P-13 (Scheme 1), which contain anthracene- and furan-derived aminophosphonate units, have been synthesized through an addition of poly(oxyethylene H-phosphonate) 1 to the Schiff base 9-anthrylidene-furfurylamine S-2. The polymer analogous reaction was carried out using an excess of the Schiff base and in the presence of CdI₂ as a catalyst. The polymer P-12 was obtained in a good yield (69%) by conventional heating of the reagents at 60^°C for 25 h. The preparation of the polymer P-13 was accomplished for a shorter reaction time (1 h) and in a higher yield (88%) with the assistance of microwave irradiation. The products P-12 and P-13 were obtained as viscous oils, soluble in common organic solvents (toluene, chloroform, methanol, and ethanol) and in water.

The structure of the polyphosphoesters P-12 and P-13 was verified by means of IR and NMR spectral analysis. The IR spectra displayed absorption bands characteristic for stretching vibration of NH, PH, P=O, and P-O-C groups. ¹H NMR spectra of the products showed doublet signals at 5.68 and 5.71 ppm (P-12, in CDCl₃ and in DMSO-d₆, respectively) and 5.69 ppm (P-13, in CDCl₃) with ²J_PH about 23 Hz which can be assigned to the CHP proton from their units formed by addition reaction between the polymeric H-phosphonate and the Schiff base. The NH proton signal is masked in the spectra taken in CDCl₃ solution. In the spectrum of P-12 measured in DMSO-d₆, the signal of NH proton appears at 4.60 ppm as a broad singlet. The signals for the anthracene protons (AnthH) of P-12 and P-13 are found in the expected region of the spectra [20, 25]. ¹H NMR spectra of P-12 and P-13 reveal two different doublet signals with large coupling constants that are due to the PH proton from H-phosphonate repeating units and PH(O)OH end groups, respectively. ¹³C{¹H} NMR spectrum of P-12 shows the signal of CHP carbon atom as a doublet at 54.79 ppm with a large coupling constant (¹J_PC = 159.7 Hz). The spectrum exhibits three distinct doublet signals which belong to the methylene carbon of the POCH₂CH₂ fragment from H-phosphonate and aminophosphonate repeating units and of the POCH₂ group from H-phosphonate repeating units. The carbon signals of the nonequivalent POCH₂ groups from aminophosphonate repeating units appear as two doublets. The methylene CH₂Fur carbon gives a doublet signal at 44.36 ppm. The HSQC spectrum shows the connection between this doublet and the proton signals at 3.66 and 3.42 ppm. These two signals are overlapped with the complex multiplet attributed to the OCH₂CH₂, POCH₂CH₂, and OCH₃ proton signals of P-12. The signals for the furan protons (P-12 and P-13) and for the furan carbons (P-12) are also observed in the ¹H and ¹³C NMR spectra, respectively. The assignment of the anthracene carbons of P-12 is based on the analysis of the HSQC spectrum and is in accordance with the data of similar aminophosphonate derivatives [20, 25]. ³¹P{¹H} NMR spectra of the products, taken in CDCl₃ (P-12 and P-13) and DMSO-d₆ (P-12) solutions, display a singlet signal about 25 ppm and another singlet in the range of 9.26–9.81 ppm, which are due to the phosphorus atoms of CHP and PH groups from the aminophosphonate and H-phosphonate repeating units, respectively. Singlet signals for the phosphorus atom of CHP(O)H, PH(O)OCH₃, and PH(O)OH end groups are observed in the spectra. The monoester end groups are generated through the addition of the PH(O)OH end groups in the starting polymer to the Schiff base [20]. The signal of the nonreacted PH(O)OH groups is found up field (5.01–2.42 ppm) in the spectra. In the coupled spectra, this signal appears as a doublet with coupling constant (¹J_PH) 647–610 Hz, which indicates that these groups possess an ionic structure. The phosphorus atom from CHP diester end groups gives two distinct singlets with very close chemical shifts because of the presence of more than one diastereomeric species in the molecules of the products. On the basis of the ³¹P{¹H} NMR spectra is estimated the average degree of polymerization of the starting polyphosphoester 1 () and of the synthesized homologous polyphosphoesters P-12 (m + l = 5.4) and P-13 (m + l = 6). From the ³¹P{¹H} NMR spectral data is calculated the content of the aminophosphonate units in the products: 54% (P-12) and 81% (P-13). The fluorescence spectra of the synthesized homologues show that the emission maxima appear in the region 402–446 nm. The mass spectra of the polyphosphoesters P-12 and P-13 are performed using electron impact mass spectrometry of the products in acetonitrile/water solutions. The analysis of the spectra reveals that they undergo strong fragmentation processes, which cause cleavages of their polymer backbones. The most intense peak (basic peak) in both spectra observed at m/z = 286.1218 (P-12) and 286.1216 (P-13) can be assigned to the ion C₂₀H₁₆N⁺O (calcd 286.1226). The structure of this cation [C₁₄H₉CH=N⁺HCH₂C₄H₃O] corresponds to the protonated form of the starting Schiff base S-2: 9-anthrylidene-furfurylamine cation. The mass spectra of the polyphosphoesters P-8–P-11, studied previously [20], showed base peaks for an ion (C₂₂H₁₈N⁺) at about 296 Da which structure was identical with the structure of the protonated synthetic precursor (protonated Schiff base S-1) of these polymers. In both cases, an electron elimination at the nitrogen atom and a break of the C-P bond of the anthracene-containing aminophosphonate moiety lead to the formation of the protonated forms of the starting Schiff bases S-2 and S-1, respectively. Many other peaks are observed in the mass spectra of P-12 and P-13 due to the fragmentation of the polymeric chains.

Recently, we described the synthesis and the in vitro antitumor activity against a panel of human epithelial cancer cell lines and the in vitro and in vivo safety evaluation of anthracene-derived low-molecular and polymeric aminop‐hosphonates and their precursors [20, 25–28]: Schiff bases S-1 and S-2, α-aminophosphonates A-3–A-6, bis-aminopho‐sphonate B-6 (R, S diastereomer), and polyphosphoes‐ters P-8–P-11, containing aminophosphonate units (Figure 1). The α-aminophosphonates A-3 and A-4 [25] and the polyphosphoesters P-8–P-11 [20] have been synthesized from the anthracene-derived Schiff base S-1, while the compounds A-5 [25] and A-6 [28] have been prepared using the anthracene- and furan-containing Schiff base S-2. The racemic compound A-5 has been separated into its two enantiomers A-5a and A-5b by HPLC technique [28]. Among the studied compounds A-3–A-5, aminophosphonate A-5, bearing anthracene and furan ring, showed the best antitumor effects against all tested human epithelial cancer cell lines. This result provokes us to incorporate such aminophosphonate fragments, which contain anthracene and furan units, into polymer backbone to obtain novel polyphosphoesters P-12 and P-13. The polyphosphoesters P-8–P-13 have been synthesized on the basis of biodegradable polymer carriers, which possess repeating hydrolytically unstable phosphorus ester linkages in their backbone [22]. The polymers P-8 and P-10 are built only of aminophosphonate repeating units, while the copolymers P-9 and P-11–P-13 contain aminophosphonate and hydrophilic H-phosphonate links. The newly synthesized polyphosphoester P-12 and the previously synthesized anthracene-derived compounds, including Schiff bases S-1 and S-2, α-aminophosphonates A-3–A-6, bis-aminophosphonate B-6 (Figure 1), two enantiomers A-5a and A-5b, and polyphosphoesters P-8–P-11 (Figure 1), have been tested for cytotoxicity against a panel of human tumor cell lines: HL-60, SKW-3, REH, and K-562 (Table 1).

2.2. Pharmacology

As evidenced by the data presented in Table 1, in all of the screened leukemic lines calculated IC₅₀ values of the tested compounds vary substantially both within and between the series. Comparable cytotoxicity was noted only for the precursors (anthracene-based Schiff bases S-1 and S-2) with the highest sensitivity of the ALL (REH) cells. The encountered inhibitory concentrations of both compounds are similar to cisplatin’s, whereas HL-60, SKW-3, and K-562 cells retained a far greater proliferative capacity under the same conditions. α-Aminophosphonates (A3-A6) showed lesser consistency in the produced growth inhibitory effect against the tested leukemic cells. Highest cytotoxic potential in all in vitro tumor models was encountered with α-aminophosphonate A-4 whose IC₅₀ estimates correlate with those of the referent drug. The other anthracene-derivative carrying an identical aminophosphonate residue, that is, A-3, produced an in-between inhibitory effect inferior to cisplatin’s in HL-60, SKW-3, and REH test systems, whereby the estimated equieffective concentration for the K-562 cells was 10- to 15-fold that of the referent drug. The racemic compound A-5, obtained from the anthracene- and furan-containing Schiff base S-2, appeared least effective in terms of growth inhibition, whereas both corresponding enantiomers (A-5a and A-5b) achieved markedly lower IC₅₀ values, especially in the leukemic subtypes of lymphoid origin (SKW-3 and REH cells). The other anthracene- and furan-carrying α-aminophosphonate congener, that is, A-6, delivered a moderate anticancer efficacy ranging between that of A-5 and both chiral isomers A-5a and A-5b. The cytostatic activity of the same compound is evidenced to be essentially invariable in all of the tested cell lines (closely comparable IC₅₀ values).

The bis-aminophosphonate B-6 (meso form) showed negligible cytostatic activity in all of the screened leukemic variants (IC₅₀ > 100).

In line with the A-4 toxicity profile, the polymeric derivatives, that is, polyphosphoesters P-8 and P-9, yielded distinctly lower equally effective concentrations in all four tumor lines as compared to the newly synthesized P-12. Cytotoxicity of both P-8 and P-9 is largely surpassing that of cisplatin in HL-60 and SKW-3 and 2-fold higher (P-8) or equal (P-9) to the referent in REH cells, whereas the chronic myeloid cell line K-562 displayed 2-fold lower chemosensitivity towards P-8 as compared to the referent drug. The same leukemic line showed a slightly lower responsiveness towards the P-9 analogue, however estimated IC₅₀ value remaining in the range of cisplatin's. The other two polyphosphoesters, namely, P-10 and P-11, bearing the same aminophosphonate residue and a shorter length of the PEG (4 units) chain demonstrated poor cytostatic activity, whereby the K-562 cell line was rated again as the least sensitive one. The newly synthesized P-12 showed consistently lower cytotoxicity than cisplatin that was oddly most pronounced in the CML K-562 cells, followed by the SKW-3, REH, and HL-60 myeloproliferative cell lines.

Overall tumor-inhibiting activity of the studied anthracene derivatives varies by compound and cell line, albeit some correlation was observed between cancer chemosensitivity and number and type of polymer units. The promyelocytic and T-cell leukemic cell lines (HL-60 and SKW-3 cells, respectively) were generally more sensitive to the α-aminophosphonates A-3 and A-4 than to the Schiff bases, whereas the latter exerted substantially stronger cytotoxic effects against the B-cell lymphoma cell line (REH). The most potent low-molecular analogue in the tested panel of human leukemic cell lines was the α-aminophosphonate A-4, whereas highest cytotoxicity among the polymeric species was determined for the corresponding polyphosphoester P-8. In the K-562 cell line, the newly synthesized polyphosphoesters P-12 demonstrated cytotoxicity matching that of the leader polymers P-8 and P-9 as well as the reference drug, while a few-fold variability in tumor cell response was established for the rest of the leukemic lines. The data for P-12, given in Table 1, show that the immobilization of anthracene- and furan-containing aminophosphonate units into the polymer chain results in a higher cytotoxicity of the polymer against the tested human leukemic cell lines compared to that of its low-molecular analogues A-5 and A-6. However, polymer P-12 exhibits moderate cytotoxicity compared to polymers P-8 and P-9. The novel polyphosphoesters P-12 and P-13 will be of interest for future investigation on human epithelial cancer cell lines, based on the results of their low-molecular analogue (A-5) obtained from its study with such cancer cell lines [25].

Among the all tested compounds, we considered that aminophosphonate A-4 and, especially, polymers P-8 and P-9 appear very promising new materials for development of anticancer drugs.

3. Conclusion

Two novel homologous polyphosphoesters containing anthracene- and furan-derived aminophosphonate moieties, poly[oxyethylene(aminophosphonate-co-H-phosphonate)]s P-12 and P-13, were synthesized through an addition of poly(oxyethylene H-phosphonate) 1 to the Schiff base 9-anthrylidene-furfurylamine S-2. The reaction was carried out by conventional heating (P-12) and under microwave irradiation (P-13) of the reagents. It was conducted using an excess of the Schiff base and in the presence of a catalytic amount of CdI₂. The structure of the polyphosphoesters was studied by means of spectral methods: IR, NMR (¹H, ¹³C, and ³¹P), fluorescence, and mass spectra. The average degree of polymerization of the starting polyphosphoester 1 and of the synthesized polyphosphoesters P-12 and P-13 and the ratio between the aminophosphonate and the H-phosphonate units in the products were estimated from their ³¹P{¹H} NMR spectral data.

The novel polyphosphoester P-12 and some anthracene-derived compounds, among them, the α-aminophosphonates A-3–A-6, their precursors the Schiff bases S-1 and S-2, the bis-aminophosphonate B-6, the two enantiomers A-5a and A-5b of the racemic A-5, and the polyphosphoesters P-8–P-11, containing aminophosphonate units, have been tested for cytotoxicity against a panel of human tumor cell lines: HL-60, SKW-3, REH, and K-562. Both precursors S-1 and S-2 presented similar cytotoxicity profiles that are cisplatin-like only in the REH lymphoid cell line. Leader compound of the α-aminophosphonates A-3–A-6 is A-4 with cell death-inducing properties fully equaling those of the referent drug. Some of the polymeric analogues elicited moderate (P-10 and P-12) to low (P-11) cytotoxic activity, whereas the polyphosphoesters P-8 and P-9 produced in vitro antitumor effects largely surpassing cisplatin’s potency. Three of the tested compounds, namely, P-8, P-9, and A-4, appear quite promising as new materials for the development of drug in chemotherapy of malignant leukemic diseases.

4. Experimental

4.1. Synthesis

Dimethyl H-phosphonate (Sigma-Aldrich Chemie GmbH, Steinheim, Germany) was purified by vacuum distillation. Poly(ethylene glycol) with average molecular weight 600 Da (PEG 600) was purchased from Fluka and dried prior to use. All solvents were freshly distilled before use. IR spectra were taken on an IRAffinity-1 spectrophotometer. ¹H, ¹³C{¹H}, and HSQC NMR spectra of polymer P-12 in CDCl₃ were recorded on an Avance 600 MHz spectrometer at room temperature and tetramethylsilane (TMS) was used as an internal standard. ¹H NMR spectra of P-12 in DMSO-d₆ and P-13 in CDCl₃ were taken on a Bruker DRX-250 250 MHz spectrometer at room temperature and TMS was used as an internal standard. ³¹P NMR spectra of P-12 in CDCl₃ and DMSO-d₆ solutions and of P-13 in CDCl₃ were registered on an Avance 600 MHz (P-12) and on a Bruker DRX-250 250 MHz (P-13) spectrometers, using 85% H₃PO₄ as an external standard. Fluorescence spectra were recorded on a JascoFp 6600 fluorometer (220–750 nm excitation range/220–1010 nm emission range). Microwave-assisted reaction was carried out in Microwave Reactor ROTOSYNTH Rotativ Solid Phase purchased from Milestone, Bergamo, Italy. The mass spectra were taken on Thermo Scientific Q Exactive Plus (Bremen, Germany) equipped with heated electrospray probe HESI-II in positive mode. The instrument operated in fullscan mode in m/z range 200–3000 at resolution 280000 (at m/z 200). The instrument parameters were as follows: spray voltage 3.5 kV, sheath gas 36 psi, auxiliary gas 11 a.u., ion transfer tube temperature 320°C, and HESI-II vaporizer temperature 320°C. Data acquisition and processing was done using Thermo Scientific Xcalibur ver. 3. All solvents were of LC-MS grade and were purchased from Thermo Fisher Scientific (Waltham, USA).

4.1.1. Schiff Bases S-1 and S-2

9-Anthrylidene-p-toluidine S-1 [25, 29] and 9-anthrylidene-furfurylamine S-2 [25, 28] were prepared following previously described procedures.

4.1.2. α-Aminophosphonates A-3–A-6

N-methyl(dimethoxyphosphonyl)-1-(9-anthryl)]-p-toluidine A-3 [25], [N-methyl(diethoxyphosphonyl)-1-(9-anthryl)]-p-toluidine A-4 [25], [N-methyl(diethoxyphosphonyl)-1-(9-anthryl)]furfurylamine A-5 [25], and [N-methyl(dimethoxyphosphonyl)-1-(9-anthryl)]furfurylamine A-6 [28] were obtained according to procedures described earlier.

4.1.3. Enantiomers A-5a and A-5b

The enantioseparation of the racemic α-aminophosphonate A-5 into its enantiomers A-5a and A-5b was reported in a previous paper [28] A-5a, [α]_D²³ = −14.30° (c = 1.00, CHCl₃) and A-5b, [α]_D²³ = +16.90° (c = 1.00, CHCl₃).

4.1.4. Bis-aminophosphonate B-6

4.4′-Bis[N-methyl(diethoxyphosphonyl)-1-(9-anthryl)]diaminodiphenylmethane B-6 was prepared as previously described [26].

4.1.5. Polyphosphoesters Containing Anthracene-Derived Aminophosphonate Units P-8–P-11: Poly(oxyethylene aminophosphonate)s P-8 and P-10 and Poly[oxyethylene(aminophosphonate-co-H-phosphonate)]s P-9 and P-11

The polymers P-8–P-11 were obtained through an addition reaction of poly(oxyethylene H-phosphonate)s to the Schiff base S-1 using synthetic procedures reported previously [20]. The polymers P-8 and P-9 were synthesized from polymeric H-phosphonate based on PEG 600 and polymers P-10 and P-11 based on PEG 200. The content of the aminophosphonate units in the polymers is as follows: 90% (P-8), 100% (P-10), 43% (P-9), and 13% (P-11).

4.1.6. Polyphosphoesters Containing Anthracene- and Furan-Derived Aminophosphonate Units P-12 and P-13

(1) Poly(oxyethylene H-phosphonate) 1. Poly(oxyethylene H-phosphonate) 1 (x = 13, average degree of polymerization , number average molecular weight Mn = 4550 Da) was prepared via a polytransesterification reaction of dimethyl H-phosphonate and poly(ethylene glycol) with number average molecular weight 600 Da (PEG 600) according to literature methods [30, 31].

(2) Poly[oxyethylene(aminophosphonate-co-H-phosphonate)] P-12. Poly(oxyethylene H-phosphonate) 1, Mn = 4550 Da (3.38 g, 5.31 mmol repeating units) dissolved in toluene (20 ml), and CdI₂ (0.04 g, 0.11 mmol) were placed in a flask equipped with a magnetic stirrer, a thermometer, an inlet for inert gas, and a reflux condenser. The mixture was stirred for a half an hour at room temperature for dissolving the catalyst. Then a solution of 9-anthrylidene-furfurylamine S-2 (1.94 g, 6.80 mmol) in toluene (10 ml) was added and the reaction mixture was heated at 60°C for 25 h with stirring. After removal of the toluene in vacuum and cooling to room temperature, the crude product was washed with dry diethyl ether, precipitated three times in dry diethyl ether from a toluene solution, and dried under reduce pressure to constant weight. The polymer P-12 is viscous oil. Yield: 3.40 g (69%); aminophosphonate units = 54%; Mn = 5800. IR (neat), ν (cm⁻¹): 3343 (ν_NH), 2355 (ν_PH), 1248 (ν_P=O), 1095 (ν_P-O-C). Fluorescence spectrum: Ex 395 nm-λ_max = 402 nm, 422 nm, 445 nm. ¹H NMR, δ (ppm), J_HH (Hz), J_PH (Hz). Solvent CDCl₃: 9.24 (d, ³J = 9.0, AnthH-α), 8.37 (AnthH-10), 8.04 (d, ³J = 8.7, AnthH-α), 7.93 (AnthH-α), 7.92 (AnthH-α), 7.42 (m, AnthH-β), 7.16 (FurH-5), 6.88 (d, ¹J = 714.4, PH repeating unit), 6.77 (d, ¹J = 647.4, PH(O)OH end group), 6.12 (FurH-4), 5.82 (FurH-3), 5.68 (d, ²J = 23.5, CHP), 4.20–3.76 (m, POCH₂), 3.68–2.96 (m, OCH₂CH₂, POCH₂CH₂, CH₂Fur, OCH₃). Solvent DMSO-d₆: 9.22 (AnthH-α), 8.61 (AnthH-10), 8.12 (AnthH-α), 8.10 (AnthH-α), 8.08 (AnthH-α), 7.54 (m, AnthH-β), 7.46 (dd, ³J = 1.8, ⁴J = 0.8, FurH-5), 6.85 (d, ¹J = 726.7, PH repeating unit), 6.64 (d, ¹J = 587.0, PH(O)OH end group), 6.32 (dd, ³J = 3.1 and 1.8, FurH-4), 6.03 (FurH-3), 5.71 (d, ²J = 23.4, CHP), 4.60 (br.s, NH), 4.13, 3.68, and 3.17 (3 m, POCH₂, OCH₂CH₂, POCH₂CH₂, CH₂Fur, OCH₃). ¹³C{¹H} NMR (CDCl₃), δ (ppm), J_PC (Hz): 152.85 (FurC-2), 141.96 (FurC-5), 129.34 (AnthC-α), 128.93 (d, ⁵J = 4.5, AnthC-10), 128.88 (AnthC-α), 127.44 (AnthC-α), 126.26, 125.55, 125.24, and 124.68 (AnthC-β), 123.68 (AnthC-α), 110.04 (FurC-4), 108.04 (FurC-3), 70.53 and 70.42 (OCH₂CH₂), 70.15 (d, ³J = 5.4, POCH₂CH₂, H-phosphonate unit), 69.81 (d, ³J = 5.9, POCH₂CH₂, aminophosphonate unit), 65.54 and 65.40 (2d, ²J = 7.2 and 7.2, POCH₂, aminophosphonate unit), 64.70 (d, ²J = 6.1, POCH₂, H-phosphonate unit), 54.79 (d, ¹J = 159.7, CHP), 44.36 (d, ³J = 16.0, FurCH₂). ³¹P{¹H} NMR, δ (ppm). Solvent CDCl₃: 26.23 and 26.11 (2 s, CHP diester end group), 25.44 (s, CHP repeating unit), 22.40 (s, CHP(O)OH end group), 10.00 (s, PH(O)OCH₃ end group), 9.31 (s, PH repeating unit), 4.88 (s, PH(O)OH end group). Solvent DMSO-d₆: 25.94 (s, CHP diester end group), 25.01 (s, CHP repeating unit), 21.80 (s, CHP(O)OH end group), 9.81 (s, PH repeating unit), 2.42 (s, PH(O)OH end group). ES-MS: m/z = 286.1218 C₂₀H₁₆N⁺O (calcd 286.1226).

(3) Poly[oxyethylene(aminophosphonate-co-H-phosphonate)] P-13. Poly (oxyethylene H-phosphonate) 1, Mn = 4550 Da (1.66 g, 2.61 mmol repeating units) dissolved in toluene (15 ml), and CdI₂ (0.02 g, 0.05 mmol) were placed in a flask equipped with a magnetic stirrer, a thermometer, an inlet for inert gas, and a reflux condenser. The catalyst was dissolved by stirring at room temperature for a half an hour. Then a solution of 9-anthrylidene-furfurylamine S-2 (0.95 g, 3.33 mmol) in toluene (10 ml) was added and the reaction mixture was microwave irradiated (250 W) at a hold temperature 34°C (read by IR thermometer) in an open vessel for an hour. After removal of the toluene in vacuum and cooling to room temperature, the crude product was purified following the procedure given for P-12. The polymer P-13 is viscous oil. Yield: 2.11 g (88%); aminophosphonate units = 81%; Mn = 6700. IR (neat), ν (cm⁻¹): 3339 (ν_NH), 2361 (ν_PH), 1247 (ν_P=O), 1093 (ν_P-O-C). Fluorescence spectrum: Ex 375 nm-λ_max = 403 nm, 425 nm, 446 nm. ¹H NMR (CDCl₃), δ (ppm), J_HH (Hz), J_PH (Hz): 9.24 (d, ³J = 9.1, AnthH-α), 8.37 (d, ⁶J = 2.4, AnthH-10), 8.04 (d, ³J = 7.9, AnthH-α), 7.94 (AnthH-α), 7.91 (AnthH-α), 7.43 (m, AnthH-β), 7.16 (FurH-5), 6.88 (d, ¹J = 716.3, PH repeating unit), 6.74 (d, ¹J = 674.1, PH(O)OH end group), 6.12 (dd, ³J = 3.0 and 1.9, FurH-4), 5.82 (d, ³J = 3.0, FurH-3), 5.69 (d, ²J = 23.6, CHP), 4.26–3.69 (m, POCH₂), 3.67–2.80 (m, OCH₂CH₂, POCH₂CH₂, CH₂Fur, OCH₃), ³¹P{¹H} NMR (CDCl₃), δ (ppm): 26.23 and 26.11 (2 s, CHP diester end group), 25.44 (s, CHP repeating unit), 22.39 (s, CHP(O)OH end group), 10.00 (s, PH(O)OCH₃ end group), 9.26 (s, PH repeating unit), 5.01 (s, PH(O)OH end group). ES-MS: m/z = 286.1216 C₂₀H₁₆N⁺O (calcd 286.1226).

4.2. Pharmacology

4.2.1. MTT Dye Reduction Assay

Anticancer activity of the investigational compounds was determined using a standard MTT-based colorimetric assay for evaluating cell viability. In brief, exponential-phased suspension leukemic cells were harvested and seeded (100 µl/well) in 96-well plates at the appropriate density, that is, 3 × 10⁵. Following a 24 h incubation, cells were treated with serial dilutions of the tested substances in an appropriate concentration range. Following exposure time of 72 h, filter sterilized MTT substrate solution (5 mg/ml in PBS) was added to each well of the culture plate. A further 1- to 4-hour incubation allowed formation of purple insoluble precipitates of the formazan dye. The latter were dissolved in isopropyl alcohol solution containing 5% formic acid prior to absorbance measurement at 550 nm. Collected absorbance values were blanked against MTT and isopropanol solution and normalized to the mean value of untreated control (100% cell viability).

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request. All information about the materials and data is available from the collaborating scientists involved with the research submitted for publication upon request.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

Acknowledgments

Thanks are due to the Bulgarian National Science Fund of Ministry of Education and Science for the financial support (Contract no. DTK-02/34).

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Copyright © 2018 Ivanka Kraicheva et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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