Identification of Polar Constituents in the Decoction of Juglans mandshurica and in the Medicated Egg Prepared with the Decoction by HPLC-Q-TOF MS2

As a folk medicinal plant, Juglans mandshurica has been used for the treatment of cancer in China and Korea. Traditionally, J. mandshurica is decocted together with chicken eggs. Both the decoction and medicated eggs possess anti-tumor properties. Clarifying the constituents of the decoction and absorbed by the medicated eggs is essential for the investigation of the active principles of J. mandshurica. Herein, the medicated eggs were prepared by decocting raw chicken eggs, having unbroken shells, with the decoction of J. mandshurica. A systematic investigation of the chemical profile of the J. mandshurica decoction and the medicated egg extraction was conducted by HPLC-Q-TOF-MS2. In total, 93 peaks, including 45 tannins, 14 naphthalene derivatives, 17 organic acids, 3 diarylheptanoids, 4 lignans, 3 anthraquinones, 1 flavonoid glycoside, 3 amino acids, and 3 nitrogenous compounds, were tentatively identified in the decoction. In the medicated egg extraction, 44 peaks including 11 organic acids, 3 amino acids, 3 nitrogenous compounds, 8 naphthalene derivatives, 3 diarylheptanoids, 15 tannins, and 1 lignan were tentatively identified. The chemical profile presented provided a detailed overview of the polar chemical constituents in J. mandshurica and useful information for the research of bioactive compounds of this plant.


Introduction
The Manchurian walnut, Juglans mandshurica Maxim., belongs to the Juglandaceae family and is mainly distributed in northern and northeastern China [1].It is recorded to have effects of clearing heat, detoxification, astringing lung, and relieving asthma and cough in "Kaibao Bencao" (materia medica edited in the Song dynasty).For its heat clearing and detoxification effects, the decoction of Juglans mandshurica roots, bark and immature pericarps has been used for treating cancer [2].Today, the anti-tumor activity of this plant has been experimentally proven by pharmacological research.As reported, both ethanol and water extracts of J. mandshurica roots, bark, branches, leaves, and immature pericarps showed an inhibitory function on the growth of human cancer cell lines (HeLa cervical carcinoma cells and Bel-7402 hepatoma cells) in vitro [3,4] and on implanted murine tumors (H22 hepatoma and S180 solid tumor) in vivo [5,6].
For the research on the active principles of J. mandshurica, numerous compounds, including tannins [7,8], flavonoids [9,10], naphthalenes [11], diarylheptanoids [12], organic acids [13], anthracenes [14], triterpenes [15], lignans [16] and phenylpropanoids [17], were isolated from this plant.Some of the compounds isolated have been reported to have growth inhibitory effects on human cancer cell lines (HepG2 hepatoma cells, HL-60 leukemia cells, lung carcinoma cells, SGC-7901 gastric cancer cells, etc.) by the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) test in vitro [12,13,15,17].Juglone, which is the main naphthoquinone in J. mandshurica, has the most reports of anti-tumor activity.As reported, juglone inhibited growth and induced apoptosis in human HL-60 leukemia cells, HeLa cervical carcinoma cells, and LNCaP prostate cancer cells through different mechanism, including the mitochondria-or reactive oxygen species-dependent pathway and the downregulation of the expression of androgen receptor [18,19].However, juglone has been also reported to be toxic to human peripheral blood lymphocytes [20], human fibroblasts' [21] and golden fish [22].Moreover, it is generally accepted that multiple constituents could be responsible for the biological action in medicinal plants.Therefore, to our knowledge, the active compounds for the anti-tumor activity of J. mandshurica have still not been clearly demonstrated.
The discovery of artemisinin from Artemisia annua L. (Qing hao) by You-You Tu [23] demonstrates that more attention should be paid to the traditional usage in seeking the active principles of traditional medicine.Most traditional Chinese Medicine was used by decocting.Specially, J. mandshurica is decocted together with chicken eggs [24].As described by Dong and Luo in the journal "Zhongguo Minjian Liaofa", the medicated eggs should be initially administered and the decoction should be administered when there are no obvious side effects [25].This traditional usage hints that the decoction and medicated eggs might possess strong and moderate anti-tumor activities, respectively.The anti-tumor activities of the decoction and medicated eggs have been ascertained using the implanted tumor model in mice by our group [26,27].
As is well known, decocting the medicinal plant in boiling water may lead to changes in some constituents of the plant.Our group has revealed that juglone content in J. mandshurica obviously decreased with the increase of drying temperature [28].Juglone has not been detected in the J. mandshurica decoction by High performance liquid chromatography (HPLC) analysis [29].Meanwhile, some constituents like tannins may be absorbed by the eggs decocted with J. mandshurica and the compounds absorbed might be effective as anti-tumor compounds.Thus, clarifying the constituents absorbed by the medicated eggs is essential for the investigation of the active principles of J. mandshurica.To our knowledge, there are no data on the complete phytochemical profile of the decoction nor the medicated eggs of J. mandshurica.
The absence of juglone in the decoction, the anti-tumor activity of the medicated eggs and the ambiguity of the active principles stimulated us to identify the chemical constituents in the decoction of J. mandshurica and those absorbed by the medicated eggs decocted with this plant.This multi-constituent identification might provide useful and detailed information on further research of the active principles of J. mandshurica.Liquid chromatography coupled to quadrupole time-of-flight mass spectrometry is a powerful tool for rapid characterization of multiple compounds from traditional Chinese medicine [30].In the present paper, high performance liquid chromatography with diode array detector coupled with quadrupole time-of-flight mass/mass spectrometry through electrospray ionization interface (HPLC-DAD-Q-TOF-MS 2 ) was applied for multi-constituent identification.

Optimization of the Sample Preparation Procedure and the HPLC-Q-TOF-MS Conditions
Referring to the traditional usage of J. mandshurica, the decoction was prepared by decocting branches of J. mandshurica in water.The medicated eggs were obtained by decocting them with the J. mandshurica decoction.After decocting, the color of the medicated eggs were dark brown due to the absorption of the constituents in the decoction of J. mandshurica.For thorough extraction of the constituents absorbed by the medicated eggs, the medicated eggs were lyophilized immediately after preparation to remove water in them and to obtain a fine powder, which increased the contact area with the extraction solvent and, therefore, improved the extraction efficiency.As previously reported by our group [31], the conditions for the extraction of the constituents absorbed by the medicated eggs, including the extraction method, extraction solvent, its volume and the extraction time, were optimized.Herein, the extraction conditions utilized were consistent with those optimized in the literature [31].
The decoction and the medicated and blank egg solutions were all subjected to HPLC-Q-TOF-MS 2 analysis.HPLC-Q-TOF-MS conditions were optimized to obtain good separation and an abundant response of multiple compounds in the decoction of J. mandshurica.Mobile phases consisting of acetonitrile and water both with 0.2% formic acid (v/v) were applied to obtain sharp peak shape for most phenolic compounds and a relatively stable baseline in the UV detector.The chromatographic separation efficiency of three different reversed-phase C18 columns, namely Agilent Zorbax SB-C18 (4.6 × 250 mm, 5 µm), Waters Spherisord ODS1 (4.6 × 250 mm, 5 µm) and Waters µBondapak C18 (3.9 × 300 mm, 10 µm), was evaluated for HPLC.The Agilent Zorbax SB-C18 column eluted with a gradient of acetonitrile-water with 0.2% formic acid (v/v) gave a good chromatographic separation for most constituents in the J. mandshurica decoction.MS spectra were conducted under negative-ion mode according to the literature [32] on the MS behavior of most of the phenolic compounds.To get almost all information on the chemical profile of the J. mandshurica decoction, non-targeted auto MS/MS was employed.The collision energy in MS/MS was optimized, and an energy of 20 eV was finally applied.

Identification of Compounds in Juglans Mandshurica Decoction
The total ion chromatograms (TIC) of the J. mandshurica decoction obtained by HPLC-ESI-Q-TOF-MS in negative-ion mode are shown in Figure 1.Multiple constituents were characterized by accurate mass analysis of the precursor and product ions and comparing their fragmentation patterns with those of reference compounds or those reported in the literature.As shown in Table 1, 93 peaks, in which configuration isomers were included, were tentatively identified in the J. mandshurica decoction.Those compounds with stereo centers which configuration can't be determined only by MS data was tentatively identified as the one that universally exist as natural products.For example, hexose present in tannins was characterized as glucose and 2,3,4-trihydroxybutanoic acid was characterized as threonic acid.The compounds identified consisted of tannins, naphthalene derivatives, organic acids, flavonoids, diarylheptanoids, lignans, and anthraquinones.The result and the fragmentation pattern of those compounds identified was consistent with our previous report on the chemical profile of ethanol extract of J. mandshurica [33].
Tannins were found to be the main constituents in the decoction and 45 tannins were characterized.The fragmentation pattern of these tannins was characterized by continuous loss of acyl and/or organic acid groups and presence of typical product ions of the corresponding organic acid (Figure S1a) [32,33].The organic acid and the polyol carbohydrate core in the structure of the tannins identified mainly consisted of gallic acid and glucose, respectively.Additionally, methyl gallic acid, syringic acid, vanillic acid, and phenol derivatives (as the polyol carbohydrate core) were also found in the structure of the identified tannins.These organic acids [34,35] and phenol derivatives [11,36,37] or compounds with these groups [38] have been reported to be found in J. mandshurica.More mono-and di-O-galloyl glucoses other than tetra-O-galloyl glucoses, which have been reported to commonly exist in J. mandshurica, were found in the decoction of J. mandshurica.This observation suggested that decocting in boiling water resulted in the hydrolysis of tannins with more galloyl groups [39].Both naphthoquinones, for example juglone [18], and naphthalene derivatives [11,35,40] were reported to exist in J. mandshurica.However, no naphthoquinone, but naphthalene derivatives, including 11 hydroxyl tetralone derivatives and three hydroxyl naphthalene derivatives were found in the J. mandshurica decoction.Based on this evidence, the anti-tumor effects of the J. mandshurica decoction might not be due to juglone alone.The absence of naphthoquinones in the decoction might be caused by volatilization during decocting [41].Of the naphthalene derivatives identified, nine were glycosides with glycosyl groups or galloyl/syrigoyl-substituted glycosyl moieties.According to MS 2 analysis, fragmentation of these naphthalene derivatives involved the loss of H 2 O and CO 2 from deprotonated aglycon ions (Figure S1b) [33,37].  Those compounds with stereo centers which configuration can't be determined only by MS data was tentatively identified as the one that universally exist as natural products; 4 The absorption ration was calculated using the following formula: Absorption ratio (%) = Peak area in medicated egg solution×0.1 Peak area in decoction×0.22 × 100%; 5 HHDP: hexahydroxy-diphenoyl; 6 Peaks that were undoubtedly identified by comparing with reference compounds; 7 Peaks that were tentatively identified due to the lack of reference compounds and mass data in literature; 8 Peaks that formed formiate adduct ions of [M + HCOO] − .Besides tannins and naphthalenes, organic acids were also the main compounds existing in J. mandshurica.Typical fragmentation of these organic acids involved the loss of CO 2 (Figure S1c), which was consistent with the results reported in the literature.Herein, 17 organic acids were identified by comparing their MS data with those reported in the literature [42][43][44].Organic acids that are present in the structure of tannins, such as gallic acid, syringic acid, and ellagic acid, were included.Additionally, compounds with groups of coumaric acid, caffeic acid, ferulic acid and quinic acid, which have been reported to be found in J. mandshurica [45,46], were also included in the organic acids identified.However, some compounds with threonic acid (Peak 48, 57, 59, 70, 74 and 82), which has not been found in J. mandshurica, were tentatively identified in this plant for the first time.
Besides tannins and naphthalenes, organic acids were also the main compounds existing in J. mandshurica.Typical fragmentation of these organic acids involved the loss of CO2 (Figure S1c), which was consistent with the results reported in the literature.Herein, 17 organic acids were identified by comparing their MS data with those reported in the literature [42][43][44].Organic acids that are present in the structure of tannins, such as gallic acid, syringic acid, and ellagic acid, were included.Additionally, compounds with groups of coumaric acid, caffeic acid, ferulic acid and quinic acid, which have been reported to be found in J. mandshurica [45,46], were also included in the organic acids identified.However, some compounds with threonic acid (Peak 48, 57, 59, 70, 74 and 82), which has not been found in J. mandshurica, were tentatively identified in this plant for the first time.1.
Flavonoids [9], diarylheptanoids [47], lignans [48] and anthraquinones [14,49], which were reportedly isolated from J. mandshurica, were also detected in the decoction.One flavonoid, namely quercetin-3-O-α-L-rhamnoside, was identified by its identical retention time and fragment pattern with the reference compound.One lignan, together with its pentoside, was identified by comparing its MS data with that reported in the literature [50].In addition, three diarylheptanoids (Peaks 86, 89, and 90), two lignans (Peaks 38 and 92), and three anthraquinones (Peaks 87, 91, and 93) were tentatively identified in the decoction due to the lack of reference compounds and mass data in the literature.Accurate mass analysis and retrieval in SciFinder for possible compounds, which was consistent with the MS 2 data, were employed in those tentative identifications.The report of isolation of peaks 38 [51], 86 [2], 87 [14], 89 [52], and 90 [53] form Juglans genus made the tentative identification of these compounds more reasonable.The MS 2 data and proposed fragmentation pattern of those eight compounds tentatively identified were supplied as supplementary materials (Figure S2).
Six nitrogenous compounds, namely uric acid (Peak 4), uridine (Peak 9), tyrosine (Peak 11), phenylalanine (Peak 19), pantothenic acid (Peak 22), and tryptophan (Peak 33), were identified in the decoction.These compounds, with some of which are mainly found in the metabolites of animals, have been proven to exist in plants [44].The fragmentation patterns and even the retention order in the column of these compounds were consistent with those in the literature [44].

Identification of Compounds in Medicated Eggs Decocted with the Juglans Mandshurica Decoction
For the identification of constituents absorbed by the medicated eggs, the TIC of medicated and blank egg solutions were fully compared and peaks that were present in both the medicated egg solution and the decoction, but absent in the blank egg solution, were ascertained to be constituents absorbed from the decoction.Those peaks only present in the medicated egg solution, but absent in both the blank egg solution and the decoction, which might have been caused by the chemical changes of the eggs after the interaction with J. mandshurica, were not taken into account in this paper.
When decocted with eggs, the constituents in the decoction were selectively absorbed by the eggs.The constituents absorbed by the medicated eggs were extracted with 70% acetone (v/v) by reflux.The extraction was subjected to HPLC-Q-TOF-MS 2 analysis, and the TIC of medicated and blank egg solutions are shown in Figure 2a.By comparing the TIC, extracted ion chromatograms (EIC, Figure 2b, Figures S3a and S4) and MS/MS data (Figure S3b) of the medicated egg solutions with those of the blank egg solutions and decoction, 44 peaks were identified as absorbed constituents.These absorbed peaks included 11 organic acids, 3 amino acids, 3 nitrogenous compounds, 8 naphthalene derivatives, 3 diarylheptanoids, 15 tannins and 1 lignan.Except for flavonoids and anthraquinones, many kinds of compounds detected in the decoction were absorbed.Most compounds were absorbed in a concentration dependent manner.An obvious selectivity was observed for tannins.Only tannins with less than two galloyl groups (or equivalent groups) were detected in the medicated egg solutions.For example, several compounds of mono-O-galloyl-glucose were found (Figure 2b), but no di-O-galloyl-glucose was detected (Figure S4) in the medicated egg solutions.According to the property that tannins co-predicate with protein, the absence of di-O-galloyl-glucose might have been partially due to its binding with protein.At the same time, these big molecular tannins might not be absorbed by the eggs.For confirmation, further investigation of the reference tannins will be required.
The absorption ratio of constituents absorbed by the medicated eggs was determined by semi-quantitative analysis.The concentration of the decoction for analysis and for the preparation of medicated eggs remained constant and was 0.1 g/mL for the crude drug.The concentration of the medicated egg solutions for analysis was 0.22 g/mL for the crude drug.According to the HPLC-DAD analysis, the reproducibility of the retention time and peak area for the decoction (obtained from six decoction samples) and the medicated egg solutions (obtained from three egg samples) was found to be relatively consistent, with an RSD of less than 7%.The reproducibility of the peak area was important for semi-quantitative analysis of the absorption ratio of the constituents absorbed by the medicated eggs.The absorption ratio was calculated using the following equation:  1.
As obtained by semi-quantitative analysis, the absorption ratio of most absorbed compounds was within the range of 1.0-9.0%(Table 1).The absorption ratios of three amino acid, uric acids, uridine, pantothenic acid and citric acid were >15%, with the biggest being 1706.8%(tyrosine).Most of these compounds also existed in eggs in different forms; for example, amino acids were combined as protein [54].During decocting, the interaction of the eggs and the J. mandshurica decoction might have led to the chemical changes in the eggs, and therefore those aforementioned compounds were produced and extracted from the medicated eggs, which resulted in a large absorption ratio.

Chemicals
Acetone (AR grade) used for extraction was purchased from Tianjin Kemiou Chemical Reagent Co., Ltd.(Tianjin, China) HPLC grade acetonitrile, methanol, and formic acid utilized in HPLC-MS analysis were purchased from Honeywell (Morris, NJ, USA).Water used for the HPLC mobile phase and extraction solvent was purchased from Hangzhou Wahaha Group Co., Ltd.(Hangzhou, China).

Plant Materials
Branches of Juglans mandshurica Maxim.were collected from "Laobai Shan" nearby Lianshan village of Pulandian county, Liaoning Province, northeast China, in May 2013.The identity of the plant species was confirmed by Prof. Yan-Jun Zhai.The fresh samples were sliced into approximately 0.5 cm pieces and dried at room temperature (20-23 °C) in the shade.Dry raw materials were stored at room temperature in sealed plastic bags before analysis.A voucher specimen (Zhi130503) was deposited in the Herbarium of Liaoning University of Traditional Chinese Medicine.1.
As obtained by semi-quantitative analysis, the absorption ratio of most absorbed compounds was within the range of 1.0-9.0%(Table 1).The absorption ratios of three amino acid, uric acids, uridine, pantothenic acid and citric acid were >15%, with the biggest being 1706.8%(tyrosine).Most of these compounds also existed in eggs in different forms; for example, amino acids were combined as protein [54].During decocting, the interaction of the eggs and the J. mandshurica decoction might have led to the chemical changes in the eggs, and therefore those aforementioned compounds were produced and extracted from the medicated eggs, which resulted in a large absorption ratio.

Chemicals
Acetone (AR grade) used for extraction was purchased from Tianjin Kemiou Chemical Reagent Co., Ltd.(Tianjin, China) HPLC grade acetonitrile, methanol, and formic acid utilized in HPLC-MS analysis were purchased from Honeywell (Morris, NJ, USA).Water used for the HPLC mobile phase and extraction solvent was purchased from Hangzhou Wahaha Group Co., Ltd.(Hangzhou, China).

Plant Materials
Branches of Juglans mandshurica Maxim.were collected from "Laobai Shan" nearby Lianshan village of Pulandian county, Liaoning Province, northeast China, in May 2013.The identity of the plant species was confirmed by Prof. Yan-Jun Zhai.The fresh samples were sliced into approximately 0.5 cm pieces and dried at room temperature (20-23 • C) in the shade.Dry raw materials were stored at room temperature in sealed plastic bags before analysis.A voucher specimen (Zhi130503) was deposited in the Herbarium of Liaoning University of Traditional Chinese Medicine.

Preparation of the Decoction of Juglans Mandshurica
Dry branches of J. mandshurica were ground into a powder, weighed (100 g), and decocted in water at a 1:10 ratio (w/w) of plant material to solvent.During decocting, the appropriate amount of water was occasionally added to maintain a constant quantity of water.After decocting for 2 h, the decoction together with the plant material decocted were weighed, and water was added to accurately recover the weight loss.The decoction was separated by centrifugation at 1500× g for 5 min.After filtration through a 0.45 µm syringe filter (Agilent Technologies, Palo Alto, CA, USA), the decoction was subjected to HPLC-Q-TOF-MS 2 analysis.

Preparation of Blank and Medicated Eggs and Blank and Medicated Egg Solutions
Chicken eggs were purchased from Tesco supermarket.For the preparation of medicated eggs, one of the raw eggs with an unbroken shell was weighed and decocted in J. mandshurica decoction (1:10, w/v) prepared by the aforementioned method.For the preparation of blank eggs, one of the raw eggs with an unbroken shell was weighed and decocted in water (1:10, w/v).The decocting procedure of these two eggs was the same as that of the powder of J. mandshurica branches.After the addition of water to recover the weight loss, these two eggs were pulled out and their shells discarded.The unshelled eggs were separately rinsed and blended with water.The mixture of ground egg and water was frozen and lyophilized by an ALPAI1-4/LSC freeze drier purchased from Marin Christ Corporation (Osterode am Harz, Germany) at −50 • C under 6 Pa to get a fine powder of blank eggs (16.7%, w/w) and medicated eggs (18.3%, w/w).
Powder (0.5 g) of the blank and medicated eggs was separately extracted with 25 mL of 50% acetone (v/v) under reflux for 2 h.The extraction was filtrated, and 10 mL of the filtration were dried at room temperature using a nitrogen evaporator.The residue was redissolved in 5 mL of 10% methanol (v/v).Prior to injection, the solution was filtrated through 0.45 µm syringe filters (Agilent Technologies, Palo Alto, CA, USA).

Figure 1 .
Figure 1.Total ion chromatograms (TIC) in negative-ion mode (from HPLC-ESI-Q-TOF-MS) of the Juglans mandshurica decoction (a) within 0-30 min and (b) 30-60 min.The peak numbering in each TIC relates to the numbered compounds listed in Table1.

Figure 1 .
Figure 1.Total ion chromatograms (TIC) in negative-ion mode (from HPLC-ESI-Q-TOF-MS) of the Juglans mandshurica decoction (a) within 0-30 min and (b) 30-60 min.The peak numbering in each TIC relates to the numbered compounds listed in Table1.

Figure 2 .
Figure 2. (a) Total ion chromatograms (TIC) in negative-ion mode (from HPLC-ESI-Q-TOF-MS) of medicated and blank egg solutions and (b) extracted ion chromatograms (EIC) of the Juglans mandshurica decoction and blank and medicated egg solutions at m/z 331 ± 0.5 in MS.The peak numbering in TIC and EIC relates to the numbered compounds listed in Table1.

Figure 2 .
Figure 2. (a) Total ion chromatograms (TIC) in negative-ion mode (from HPLC-ESI-Q-TOF-MS) of medicated and blank egg solutions and (b) extracted ion chromatograms (EIC) of the Juglans mandshurica decoction and blank and medicated egg solutions at m/z 331 ± 0.5 in MS.The peak numbering in TIC and EIC relates to the numbered compounds listed in Table1.

Table 1 .
Constituents tentatively identified in Juglans mandshurica decoction and those absorbed by medicated eggs using HPLC-Q-TOF-MS 2 .
1Data were acquired over a range of m/z 100-2000 for MS; 2 Data were acquired over a range of m/z 50-2000 for MS/MS;