3 ‐ Isobutyl ‐ 5,5,7 ‐ tris(3 ‐ methylbut ‐ 2 ‐ en ‐ 1 ‐ yl) ‐ 1 ‐ phenyl ‐ 1,7 ‐ dihy ‐ dro ‐ 4H ‐ indazole ‐ 4,6(5H) ‐ dione

: Here we describe the functionalization of lupulone natural compound in obtaining 3 ‐ isobutyl ‐ 5,5,7 ‐ tris(3 ‐ methylbut ‐ 2 ‐ en ‐ 1 ‐ yl) ‐ 1 ‐ phenyl ‐ 1,7 ‐ dihydro ‐ 4H ‐ indazole ‐ 4,6(5H) ‐ dione. lupulone ‐ H ‐ indazole derivative was prepared with 75% yield through the reaction between lupulone and phenyl ‐ hydrazine employing SiO 2 /ZnCl 2 (30% m / m ) as a support solid in a solvent ‐ free condition. Based on the possibilities of products, a complete NMR structural characterization of this lupulone ‐ H ‐ indazole was performed by 1 H, 13 C{ 1 H}, COSY, HSQC and HMBC NMR experiments, showing an important contribution in producing the first results related to lupulone reactivity.


Introduction
Biomass is renewable organic material that comes from animals and plants [1]. These materials are getting the attention of researchers due to the chemical transformation ability, which can lead to molecules with therapeutic potential or great industrial applicability [1,2].
Humulus lupulus L. has long been used as a medicinal plant, and its benefits include blood purification, treatment of inflammation, and sedative properties [3]. The compounds present in the extracts or essential oil of this plant have also been explored regarding their synthetic potential [4].
Hop is a base material in the brewing process to provide flavor and aroma to beer. Hop essential oil is present in the glandular cells of the hop plant, Humulus lupulus (Cannabinaceae) [5]. Among the vast number of natural compounds in the hop extract [6] are humulone and lupulone (Figure 1), which exhibit biological activity against some human cancer cells and have antibiofilm properties [7,8]. Based on our interest in the evaluation of the pharmacological properties of natural products, [9,10] especially structural modification, [11][12][13][14] we isolated lupulone from the hop plant. In this sense, the derivation of lupulone containing heterocyclic nitrogen represents a consolidated strategy to improve the pharmacological properties [11].
On the basis of these recent findings, we report here the first results related to the derivatization of lupulone through reaction with phenyl-hydrazine. Considering the lupulone structure and the possibilities of products, a full structural characterization was performed, which confirmed the formation of a H-indazole ring through 1 H, 13 C{ 1 H}, COSY, HSQC, and HMBC NMR experiments.
Initially, the reaction between lupulone and phenyl-hydrazine was optimized. As seen in Table 1, the presence of an acid support solid was essential to produce the lupulone derivative, as the presence of the reagents only was not sufficient to detect a product. The heating of the reaction media increased the yield, with the use of 60 °C demonstrating the best performance (Table 1, entry 5). When an excess of phenyl-hydrazine was employed, the yield increased to 75% (Table 1, entry 6), although continuing to increase the amount of the phenyl-hydrazine did not enhance the reaction efficiency (Table 1, entry 6). The product highlighted in the Table 1 is the expected product in this functionalization. At this moment, the main product was isolated by column chromatography; however, several small by-products were also detected by thin-layer-chromatography of the crude reaction. Evaluation using mass spectrometry showed it was not possible to discriminate the product possibilities, because of mass similarities and the tautomerism effect ( Figure 2). Additionally, when employing 1 H and 13 C{ 1 H} NMR experiments, it was possible to eliminate the lupulone derivatives 1, 2, and 5 ( Figure 2), due the amount of aliphatic carbons, but this was not sufficient to clarify the lupulone derivatives 3, 4 and 6 (see Figure 2). Thus, a full assignment was performed, for which 2D NMR experiments were also necessary. Based on this structural elucidation, COSY, HSQC and HMBC NMR experiments were carried out, and the NMR data were interpreted according to the Table  2.

Number 1 H (ppm) 13 C (ppm) 1 H-13 C HMBC
3.89 (dd, J = 5.0 and 6.3 Hz) 46. 8  The 2D NMR experiments confirmed the formation of the H-indazole ring, according to the structural assignment ( Figure 2). First, the 1 H spectrum ( Figure S1) demonstrates a clear signal profile, with the aliphatic protons being easily identified ( H NMR signal in 3.9 ppm demonstrates a deshielded chemical shift due the proximity to nitrogen and carbonyl groups, or it could be derived from some hydroxyl group of the lupulone derivative 3 [18]. In a upfield region, it is possible to observe the aliphatic signals, considering the multiplicity standard (Table 2, numbers 10, 11, 14, 19 and 24). It is noteworthy that the protons 14 are diastereotopics with a distinct multiplicity profile ( Table 2, numbers 14 and 14', confirmed by HSQC), indicating the lupulone derivative 4 or its tautomer, with the lupulone derivative 6 as the possible product, due the presence of the aromatic ring near to these protons, which results in an anisotropic environment. Based on the COSY experiment, stronger correlations were observed between the protons 14 and 14' with the deshielded aliphatic proton (number 7), which confirms the lupulone derivative 4 and excludes the lupulone derivative 6.
According to the 13 (Table 2, numbers 4 and 6, 193.0 and 209.9 ppm, respectively, confirmed by HMBC), which allows us to discard the lupulone derivative 3 due to the presence of phenol groups in the main structure [18]. Additionally, the ortho and meta carbons can be identified from aromatic ring based on the signal intensity. However, no further identifications could be evidenced without the HSQC and HMBC 2D NMR experiments (see NMR spectra in SI).
Although the 1 H and 13 C NMR profile can provide good evidence for the lupulone derivative 4 (Figure 2), more proof is necessary to confirm the main structure. Thus, a full structural elucidation is necessary to identify all protons and carbons signals, and for this purpose, 2D NMR experiments were carried out. As can be seen in Table 2, proton-carbon correlations are valuable for recognizing all NMR signals. Additionally, interpreting the COSY NMR experiment (Figure 3), the methyl groups 12 and 13 and the proton 10 were identified by the correlation with proton 11 (2.25 ppm, nonet) containing eight neighbor protons. In the same NMR region, the diastereotopic protons 14 and 14' could be detected by the correlation between them and by a weak correlation with the vinylic proton 15, also confirming the methyl groups 17 and 18. The other two butene groups were recognized by the same correlation pattern, although no distinction among these groups was possible.  Next, the HSQC NMR spectrum was evaluated ( Figure S4). Based on the identification of the protons using proton-proton correlations, the carbons directly attached were detected. The aliphatic moiety was easily recognized, because there is only one quaternary carbon (Table 2, number 5). When the downfield region was checked, the vinylic carbons attached to the protons were identified (Table 2, numbers 15, 20 and 25) as were the ortho, meta and para carbons in the aromatic ring (Table 2, number 30, 31 and  32).
Finally, the HMBC NMR experiment was carried out to assign the quaternary carbons, confirming the main core of the lupulone derivative 4 ( Figures S5-S7). In this way, to carry out the 1 H-13 C HMBC experiment, 10 Hz was used for the long-distance parameter (SI, CNST13), although this long-range term could be optimized for a proper assignment. Based on the proximity of protons and carbons, especially considering the stronger 3 J1H-13C scalar coupling, the quaternary carbons were assigned. It is important to mention that the correlation between the diastereotopic protons 14 and 14' and the carbons C6, C7, C8, C15 and C16 were also visualized in the HMBC NMR spectrum.
Analysis of HMBC NMR spectrum in the downfield region supports the formation of the lupulone derivative 4 ( Figure 3). The quaternary carbon 3 was assigned by correlations with the protons 10 and 11, corroborating the typical 13 C chemical shift ( Table  2; number 3; 153.6 ppm). The carbon 4 (carbonyl) can be confirmed by 3 J correlation with the protons 24 and 19 ( Figure S7), but it does not have a correlation with the proton 7. The quaternary carbon-5 does not demonstrate correlation with the proton 7, which supports the lupulone derivative 4. The carbon 6 demonstrates a similar profile with the 3 J correlation with the protons 7, 19 and 24. When we evaluated the carbon 7, only weak correlations were observed with the diastereotopic protons 14 and 14'. The carbon 8 was clearly assigned by the correlation with the proton 7 and a weak correlation with the diastereotopic protons 14 and 14' (Figure S6). Finally, the carbon 9 was assigned by the correlations with the protons 7 and 10 ( Figure 3).
The NMR experimental data completely support the lupulone derivative 4. Although the possible tautomers of lupulone derivative 4 ( Figure 2; tautomers 1 and 2) can change the chemical shift profile, their structures were not detected in the NMR spectra. Thus, to improve the discussion regarding the reactivity of the lupulone starting material, we propose a plausible mechanism (Figure 4) [19]. Initially, a keto-enol tautomerism justifies the formation of an aliphatic carbon in the main structure. The first step is the formation of imine from the reaction between ketone and amine organic functions, eliminating a water molecule. Afterward, a cyclization is favored, derived from the proximity between carbonyl and amine groups, followed by the elimination of the hydroxyl group (E1cB type). Finally, the base present in the media provides the formation of another carbonyl group, establishing the H-indazole ring and producing another water molecule. The formation of a heteroaromatic ring by the tautomerism effect affords the product lupulone derivative 4, probably derived from the stability gain by the aromaticity (Figure 4). In addition, the lupulone derivative 2 was not observed; however, the ring contraction is a possible pathway, derived from an isomerization process [20]. Based on this mechanism, it is possible to visualize the formation of various other products derived from the different pathways in this reaction ( Figure S8, lupulone derivatives 1 and 3), justifying the need to perform a full structural assignment, as varying the reaction conditions could produce distinct products.

Materials and Methods
The reactions were monitored by TLC carried out on pre-coated TLC sheets ALUGRAM ® Xtra SIL G/UV254 by using UV light as the visualization agent and the mixture of 5% vanillin in 10% H2SO4 under heating conditions as the developing agent. Silica gel (particle size 63-200 μm) was used for flash chromatography. The reagents, solvents and chromatographic materials were purchased from Sigma-Aldrich ® Brazil. The nuclear magnetic resonance (NMR) data were collected on a Bruker Avance III HD spectrometer (Bruker ® , Atibaia, Brazil) operating at 400.0 MHz for 1 H and 100 MHz for 13 C. NMR data were recorded at 25 °C, with chemical shifts δ reported in parts per million and coupling constants J in Hertz. The NMR sample was prepared employing 5 mg of the respective lupulone derivative 4 in 600 μL deuterated chloroform. Chemical shifts of 1 H and 13 C{ 1 H} NMR experiments were referenced by TMS (tetramethylsilane) at δ = 0.0 ppm. Two-dimensional NMR experiments COSY, HSQC, and HMBC were performed using the standard Bruker pulse sequence with gradient. The relaxation delay, 90° pulse, spectral width, and number of data points for 1 H NMR were 1 s, 9.43 μs, 5580 Hz, and 64 K, respectively. The corresponding parameters for the 13 C NMR experiments were 0.5 s, 10.0 μs, 26,041 Hz, and 64 K, respectively. Two-dimensional experiments, including COSY, HSQC, and HMBC, were performed with 4 K × 512 (t2 × t1) data points. The long-range coupling time for 1 H-13 C HMBC was 10 Hz. All data were analyzed using Bruker software (Topspin 3.6, Bruker ® , Atibaia, Brazil). Low-resolution mass spectra (MS) were obtained with a Shimadzu GC-MS-QP2010 mass spectrometer (São Paulo, Brazil). The HRMS analyses were performed in a Bruker micrOTOF-QII spectrometer equipped with an APCI source operating in positive mode. The samples were solubilized in acetonitrile and analyzed by direct infusion at a constant flow rate of 180 μL/min. The acquisition parameters were capillary: 4000 V, end plate offset: −500 V, nebulizer: 1.5 bar, dry gas: 1.5 L min −1 , and dry heater: 180 °C. The collision cell energy was set to 5.0 eV. The massto-charge ratio (m/z) data were processed and analyzed using Bruker Daltonics software: Compass Data Analysis and Isotope Pattern.
Experimental Procedure to obtain the Lupulone Derivative 4: The 3-isobutyl-5,5,7-tris(3methylbut-2-en-1-yl)-1-phenyl-1,7-dihydro-4H-indazole-4,6(5H)-dione was obtained through the reaction between lupulone (0.5 mmol) and phenyl-hydrazine (0.6 mmol) employing 20 mg (0.277 mmol) of SiO2/ZnCl2 (30% m/m) [17] as a support solid in a solvent-free condition. The reaction media was heated to 60 °C for 20 h. The conventional heating was removed and the heterogenous catalyst was filtred using a small amount of ethyl acetate (2.0 mL). Then, the solvent was removed without an extraction step, and the sample obtained was directly purified by column chromatography. The lupulone derivative 4 was isolated in a moderate yield (75%) by column chromatography, employing a mixture of n-hexane/ethyl acetate in a 94:04 ratio. The product is a yellow oil with a pleasant smell.