Excretion, Metabolism, and Tissue Distribution of Gelsemium elegans (Gardn. & Champ.) Benth in Pigs

Abstract

Gelsemium elegans (Gardn. & Champ.) Benth is a toxic flowering plant in the family Loganiaceae used to treat skin diseases, neuralgia and acute pain. The high toxicity of G. elegans restricts its development and clinical applications, but in veterinary applications, G. elegans has been fed to pigs as a feed additive without poisoning. However, until now, the in vivo processes of the multiple components of G. elegans have not been studied. This study investigates the excretion, metabolism and tissue distribution of the multiple components of G. elegans after feeding it to pigs in medicated feed. Pigs were fed 2% G. elegans powder in feed for 45 days. The plasma, urine, bile, feces and tissues (heart, liver, lung, spleen, brain, spinal cord, adrenal gland, testis, thigh muscle, abdominal muscle and back muscle) were collected 6 h after the last feeding and analyzed using high-performance liquid chromatography coupled to quadrupole time-of-flight mass spectrometry. Five natural products in plasma, twelve natural products and five metabolites in urine, and three natural products in feces were characterized, suggesting that multiple components from G. elegans were excreted in the urine. However, ten natural products and four metabolites were detected in bile samples, which suggested that G. elegans is involved in enterohepatic circulation in pigs. A total of seven of these metabolites were characterized, and four metabolites were glucuronidated metabolites. Ten natural products and six metabolites were detected in the tissues, which indicates that G. elegans is widely distributed in tissues and can cross the blood-brain barrier. Among the characterized compounds, a highly toxic gelsedine-type alkaloid from G. elegans was the main compound detected in all biological samples. This is the first study of the excretion, metabolism and tissue distribution of multiple components from G. elegans in pigs. These data can provide an important reference to explain the efficacy and toxicity of G. elegans. Additionally, the results of the tissue distribution of G. elegans are of great value for further residue depletion studies and safety evaluations of products of animals fed G. elegans.

1. Introduction

Gelsemium is a genus of flowering plants in the Loganiaceae family [1]. There are four species in this genus: the Asian species, Gelsemium elegans (Gardn. & Champ.) Benth (G. elegans) and G. rankii Small and two North American species (Gelsemium sempervirens (L.) J.St.-Hil. and Gelsemium rankinii Small) [2]. The use of Gelsemium sempervirens traces back to the 19th century as a homeopathic agent to reduce anticipatory anxiety [3]. Pharmacological reports of Gelsemium rankinii Small are scarce because it is a rare species from the southeastern United States [4]. In China, G. elegans has been reported for its analgesic and anti-inflammatory effects and has been used to treat skin diseases, neuralgia and acute pain [1]. However, the high toxicity of G. elegans is the main limiting factor for its clinical applications. Generally, limb weakness, vomiting, arrhythmia, coma and other symptoms will occur after intoxication, and severe poisoning could lead to death [5]. However, G. elegans has growth-promoting effects in pigs in traditional Chinese medicine, so G. elegans could be added to feed [6]. However, this will cause G. elegans residue in products of animal origin and pose a threat to the safety of consumers, so it is necessary to study the excretion, metabolism and tissue distribution of G. elegans.

There are many compounds in G. elegans. Up to now, a total of 121 alkaloids, 25 iridoids, and several other compounds from a wide spectrum of secondary metabolite classes have been found in G. elegans. Based on the chemical structures of the alkaloids, they have been classified into the following six types: gelsedine-type, gelsemine-type, humantenine-type, koumine-type, sarpagine-type and yohimbane-type [7,8,9]. Among them, the contents of koumine and gelsemine are high, and these types can be rapidly absorbed and widely distributed in tissues and can pass through the blood-brain barrier in rats. Moreover, their toxicity is low, with LD₅₀ values of 99 mg/kg and 56.2 mg/kg [1], respectively. The toxicity of gelsenicine is high, with an LD50 of 0.185 mg/kg [1], and it also has the characteristics of fast absorption, wide distribution, and the ability to cross the blood-brain barrier in rats and mice [10]. A previous study characterized CYP3A4/5 as the main metabolic enzyme of G. elegans alkaloids, which can reduce the toxicity of G. elegans alkaloids through metabolism [11]. In addition, our previous studies investigated the pharmacokinetics of a G. elegans extract in pigs and found that G. elegans alkaloids were characterized by fast absorption and wide distribution, which are similar characteristics to single alkaloids in rats and mice [12]. However, the metabolism and tissue distribution of G. elegans in pigs have not been studied.

Significant differences have been observed between species with respect to the toxicity of G. elegans. According to the existing studies, it has been speculated that the differences in G. elegans toxicity may be closely related to metabolism [11,13]. Many studies have found differences in the metabolism of koumine and gelsemine in liver microsomes of pigs and rats in vitro. However, these previous studies have all been based on the metabolism of single alkaloids in vitro, which cannot completely reflect the metabolism and distribution of multiple components of G. elegans in vivo. Only one study by our team has reported the metabolic profile of multiple components of G. elegans in goats. Therefore, it is important to investigate the in vivo excretion, tissue distribution, and metabolic profile of G. elegans in pigs.

The present study characterized the multiple components of G. elegans in pig plasma, urine, bile, feces, and tissues by using high-performance liquid chromatography coupled to quadrupole time-of-flight mass spectrometry (HPLC/QqTOF-MS). This study explored the excretion, metabolism and tissue distribution of G. elegans in pigs. These results may play an important role in explaining the toxicological and pharmacological effects of G. elegans. In addition, the tissue distribution data may provide a reference for further study on the elimination of tissue residues of G. elegans and the safety of products of animal origin, ensuring the safety of consumers.

2. Results

Recently, metabolism studies of G. elegans in goats were reported by our team [14]. The current study’s naming and analysis strategies of the characterized natural products and metabolites were consistent with the previously reported publication. As a result, twenty natural products and seven metabolites were characterized in plasma, urine, bile, feces and tissues. Information on these compounds is shown in

Table 1. Retention time, formula, observed mass, mass error, fragment ion and biotransformation of twenty natural products and their metabolites in pigs as detected by HPLC/QqTOF-MS.

Compound	RT (min)	Molecular Formula	[M + H]+ (m/z)	Error (ppm)	Fragment Ions (m/z)	Compound Class	Name	Proposed Metabolism	Source
H1	5.0	C19H20N2O2	309.1579	6.02	236.1023, 191.0609, 91.0533, 56.0469	Alkaloid, Gelsemine-type	Unknown		B
H2	5.2	C20H22N2O2	323.1750	1.26	236.1076, 115.0551, 77.0367, 70.0641	Alkaloid, Gelsemine-type	Gelsemine		B
H6	13.4	C20H20N2O3	337.1565	−5.45	236.1052, 91.0501	Alkaloid, Gelsemine-type	21-Oxogelsemine		B, U
H6-M1	6.0	C20H22N2O3	339.1667	10.7	206.0973, 77.0389			+2H	B
H6-M2	9.8	C20H20N2O4	353.1500	−1.18	218.0893, 180.0933, 91.0536, 77.0355			+O	U
H6-M3	13.4	C26H28N2O9	513.1845	4.41	337.1425, 91.0490, 77.0335			+GlcA	B, U
H10	5.4	C19H22N2O5	359.1604	−0.7	311.11170, 80.0467, 68.0465	Alkaloid, Gelsedine-type	11,14-Dihydroxygelsenicine		(B), U
H11	5.6	C19H22N2O4	343.1634	5.36	312.1356, 281.1184, 108.0689, 96.0817, 80.0452	Alkaloid, Gelsedine-type	11-Hydroxygelsenicine		B, U, P
H11-M1	2.4	C25H30N2O10	519.1978	−0.92	312.1504, 281.1258, 108.0839, 80.0476			+GlcA	B, U
H12	6.6	C19H22N2O4	343.1640	3.61	312.1428, 80.0491	Alkaloid, Gelsedine-type	14-Hydroxygelsenicine		P
H14	9.7	C19H22N2O3	327.1703	0.06	265.1240, 108.0703, 95.0869	Alkaloid, Gelsedine-type	Gelsenicine		P
H15	10.9	C21H24N2O5	385.1758	0	354.1537, 309.1507, 180.0876, 134.0581	Alkaloid, Gelsedine-type	15-Hydroxyhumantenoxenine		B, U
H16	11.6	C19H22N2O4	343.1631	6.24	238.0790, 128.0493, 118.0639	Alkaloid, Gelsedine-type	Hydroxyl of gelsenicine		B, U
H18	11.4	C20H22N2O5	371.1571	8.24	340.1368, 295.1354, 120.0412, 91.0508	Alkaloid, Gelsedine-type	Gelsemolenine B		U
H22	7.6	C19H20N2O2	309.1551	11.53	194.0904, 167.0698, 115.0490	Alkaloid, Sarpagine-type	Oxokoumidine		U
H23	7.9	C19H20N2O	293.1650	−0.55	218.0904, 194.0917, 167.0721, 115.0486, 91.0548	Alkaloid, Sarpagine-type	Dehydrokoumidine		B, U, F, P
H23-M1	6.3	C25H28N2O8	485.1920	−0.33	309.1506, 194.0918, 167.0697, 154.0607, 115.0543			+O + GlcA	U
H23-M2	6.5	C19H20N2O2	309.1586	3.75	291.1457, 234.1227, 194.0946, 193.0890			+O	Only detected in tissue samples
H30	11.5	C20H24N2O4	357.1804	1.36	311.1188, 178.1097, 108.0794, 77.0377	Alkaloid, Humantenine-type	14-Hydroxyrankinidine		B, U, F
H30-M1	7.3	C26H32N2O10	533.2136	−1.18	326.1654, 311.1506, 164.1064, 148.0401,			+GlcA	B, U
H31	13.6	C21H26N2O3	355.2006	2.88	309.1609, 122.0968	Alkaloid, Humantenine-type	Humantennine		Only detected in tissue samples
H32	7.2	C20H22N2O	307.1786	6.17	277.1684, 220.1106, 238.1197, 130.0643, 70.0643	Alkaloid, Koumine-type	Koumine		Only detected in tissue samples
H37	4.7	C16H24O10	377.1422	5.38	165.0797, 119.0854, 105.0678, 93.0710	Iridoids	9-Hydroxysemperoside		U
H39	4.6	C10H16O4	201.1119	1.18	119.0859, 103.0541, 91.0538, 77.0391	Iridoids	Gelsemiol		U
H44	17.5	C30H44O3	453.3410	−10.78	209.1656, 114.0907, 96.0787, 69.0680	Triterpene	3-keto-urs-11-en-13β(28)-olide		B, U, P, F
H45	17.7	C20H24N2O5	373.1758	−2.15	260.0920, 214.0844, 130.1252	Alkaloid, Gelsedine-type	GS-2(11-Methoxy-14-Hydroxygelsenicine)		Only detected in tissue samples
H46	8.3	C19H22N2O	295.1801	1.33	277.1667, 156.0797, 144.0781, 138.0900, 108.0778	Alkaloid, Sarpagine-type	Koumidine		Only detected in tissue samples

Note: “H” means natural products; “M” means metabolites (M1 to M3 means the natural product has three metabolites identified); “U” means urine sample; “P” means plasma sample; “F” means fecal sample; “B” means bile sample; and “()” means low concentration.

. The main structures of the natural products are shown in Figure 1.

2.1. Characterization of Compounds in Plasma

Five natural products from G. elegans were characterized in plasma samples, and the accurate EICs of these compounds are shown in Figure 2. No metabolites of the natural products were found in plasma samples.

These five natural products were gelsedine-type alkaloids (compounds H11, H12, H14), a sarpagine-type alkaloid (compound H23), and a triterpene (compound H44). These five natural products were not found in blank samples. All of them were characterized based on their characteristic accurate MS2 fragment (Table 1). H12 and H14 were unique to plasma and were not detected in bile, urine or fecal samples. Compound H11 in the plasma sample was also detected in bile and urine samples. The MS2 spectrum of H14 exhibited a product ion at m/z 296, formed by the loss of CH3O from m/z 327. The ion at m/z 296 could further lose CH3O to produce an ion at m/z 265. The product ion at m/z 225 was formed by the loss of C₃H₄ from m/z 265; after comparison with the reference data, H14 was characterized as gelsenicine. The MS2 spectrum of H11 generated product ions at m/z 312 and m/z 281, which were 16 Da higher than the m/z values of 296 and 265 of the product ions of gelsenicine, respectively. The product ion at m/z 108 was the same as that in gelsenicine, so H11 is presumably 11-hydroxygelsenicine.

2.2. Characterization of Compounds in Urine

Compared with the blank group, in all the biological samples of the experimental group, the highest number of compounds was detected in the urine samples, which shows that the metabolism of G. elegans is fast. Twelve natural products and five metabolites were characterized, and their EICs are shown in Figure 3.

2.2.1. Gelsemine-Type Alkaloids (H6) and Its Metabolic Products

Gelsemine-type natural products (H6) and two related metabolites (H6-M2 and H6-M3) were detected and identified. H6 was characterized as either gelsemine or 21-oxogelsemine based on comparing the data with the reference compounds. Metabolite H6-M2 was characterized as an oxidation metabolite of H6. Additionally, a phase II metabolite conjugated with glucuronic acid was detected and named H6-M3.

The retention time of H6 is 13.469 min, and the [M + H]⁺ was observed at m/z 337.1565. First, the MS2 spectrum of compound H6 generated a product ion at m/z 236, formed by the loss of C₅H₉O₂ from m/z 337, and the product ion at m/z 204 was due to the loss of C₈H₇NO from m/z 337. Then, the product ion at m/z 77 may have been formed by the loss of C₆H₄ from m/z 236. Therefore, we speculate that compound H6 is 21-oxogelsemine.

Metabolite H6-M2 presented an m/z of 353, which was 16 Da greater than that of natural product H6. The product ion at m/z 222 of H6-M2 was also 16 Da higher than the product ion at m/z 206 of H6, suggesting that H6-M2 is an oxidation metabolite of H6. Glucuronide conjugates could produce the [M + H − 176]⁺ fragment in the MS2 spectrum. The ion produced by the loss of C₆H₈O₆ from metabolite H6-M3 was the same as the m/z of compound H6. Therefore, metabolite H6-M3 was characterized as a phase II glucuronic acid conjugated metabolite of compound H6.

2.2.2. Gelsedine-Type Alkaloids (H10, H11, H15, H16, H18) and Their Metabolic Products

Five gelsedine-type natural products (compounds H10, H11, H15, H16, H18) and one related metabolite (H11-M1) were detected in urine samples. Compounds H10, H11, H15, H16 and H18 were characterized as 11,14-dihydroxygelsenicine, 11-hydroxygelsenicine, 15-hydroxyhumantenoxenine, hydroxygelsenicine and gelsemolenine B, respectively. Metabolite H11-M1 may be a phase II metabolite conjugated with glucuronic acid.

The retention time of compound H15 was 10.9 min, which was used as an example for the characterization of gelsedine-type compounds. The product ion at m/z 354 was formed by the loss of OCH₃ from m/z 385, and further, the product ion at m/z 309 was formed by the loss of CHO₂ from m/z 354. The product ion at m/z 134 may have been formed by loss of CH₄NO from m/z 180. According to this fragmentation information, natural product H15 was suggested to be 15-hydroxyhumantenoxenine.

Metabolite H11-M1 may be a phase II glucuronic acid conjugated metabolite because the [M + H]⁺ of H11-M1 was observed at m/z 519, 176 Da higher than the m/z of H11.

2.2.3. Sarpagine-Type Alkaloids (H23)

There was only one compound (compound H23) belonging to the sarpagine type in bile samples, and no metabolites were found. In our previous study, the compound koumidine was found in the crude extract of G. elegans. The MS2 spectrum of H23 was compared with the MS2 spectrum of koumidine, and the product ion at m/z 154 from H23 was 2 Da lower than that of the product ion at m/z 156 of koumidine. Combined with the other product ions, H23 was characterized as dehydrokoumidine.

2.2.4. Humantenine-Type Alkaloids (H30) and Its Metabolic Products

Compound (H30) was classified as a humantenine-type alkaloid. The phase II metabolite of H30 was characterized and named H30-M1.

The fragment ions of compound H30 showed that the product ion at m/z 326 was formed by the loss of OCH₃ from m/z 357. The product ion at m/z 311 was formed by the loss of CH₃ from m/z 326, and the further loss of CH₂ from the ion at m/z 311 followed to generate the m/z of 297. Compound H30 was tentatively characterized as 14-hydroxyrankinidine.

Metabolite H30-M1 displayed an [M + H]⁺ ion at m/z 533, which is consistent with the molecular formula of C₂₆H₃₂N₂O₁₀. The MS2 spectrum revealed that the [M + H]⁺ ion could further lose a glucuronic acid moiety (176 Da) to produce the fragment ion at m/z 357. The fragment ion at m/z 357 then fragmented into an ion at m/z 311, which was consistent with the fragmentation of H30. Therefore, we deduced that metabolite H30-M1 was a glucuronidated metabolite of 14-hydroxyrankinidine.

2.2.5. Non-Alkaloids (H37, H39, H44)

Two iridoid compounds (H37 and H39) and one triterpene compound (H44) were found in urine samples. H37 and H39 were characterized as 9-hydroxysemperoside and gelsemiol. H44 was characterized by triterpene 3-keto-urs-11-en-13β(28)-olidevia database matching.

2.3. Characterization of Compounds in Bile

A total of ten natural products and four metabolites were detected in bile samples. These ten natural products and four metabolites were not found in the blank samples. Accurate EICs of the natural products and metabolites in bile samples are shown in Figure 4.

Three of these natural products were determined to be gelsemine-type alkaloids (compounds H1, H2, H6), four were determined as gelsedine-type alkaloids (compounds H10, H11, H15, H16), and the other three were a sarpagine-type alkaloid (compound H23), a humantenine-type alkaloid (compound H30) and a triterpene (compound H44). Based on the MS2 data and accurate mass analysis, the structures of these compounds were characterized. The protonated molecular ion ([M + H]⁺) of H2 was observed at m/z 323.1750 (C₂₀H₂₃N₂O₃⁺, 1.26 ppm). As observed from the MS2 spectrum, the more abundant product ion at m/z 236.1076 was formed by the neutral losses of CH₂O (30 Da) and C3H7N (57 Da). H2 was characterized as gelsemine by comparison with the reference standard.

A total of four metabolites (H6-M1, H6-M3, H11-M1, H30-M1) were detected in the bile samples. H6-M3, H11-M1 and H30-M1 may be phase II glucuronic acid conjugated metabolites of compounds because their [M + H]⁺ values were observed at m/z 519, 513 and 533, which were all 176 Da greater than H6, H11 and H30, respectively. When the natural products (H6, H11, H30) were combined with glucuronic acid, the water solubility increased, followed by entry into the bile and participation in enterohepatic circulation.

2.4. Compounds Identification in Feces

Three compounds were tentatively identified via comparisons of the retention times and observed masses in feces samples, including one sarpagine-type alkaloids (H23), one humantanine-type alkaloids (H30), and a triterpene (H44). Only three natural products were detected in the feces of the experimental group, and no metabolites were detected. Many compounds were detected in bile but not in feces, suggesting that these compounds may have been reabsorbed. The accurate EICs of those compounds are shown in Figure 5.

2.5. Characterization of Compounds in Tissue

As a result, nine natural products were detected in the brain, which suggested that G. elegans could cross the blood-brain barrier. All compounds were a gelsemine-type alkaloid (H2), gelsedine-type alkaloids (H11, H45), sarpagine-type alkaloids (H23, H46), humantenine-type alkaloids (H30, H31), a koumine-type alkaloid (H32) and a triterpene (H44). H46 and H32 were selected as examples to characterize the fragmentation patterns for the other compounds. H46 was characterized as koumidine, the major fragment ion at m/z 277 was due to the loss of H₂O from the ion at m/z 295, and compared with the reference data, the structure was determined. Compound H32 was characterized as koumine because the fragment ion at m/z 277 was formed by loss of CH₂ from the ion at m/z 307 and the further loss of C₃H₇N to form an m/z of 220. Moreover, the ion at m/z 307 was formed by m/z 238 + m/z 70. Only three compounds were detected in the spinal cord, including gelsemine-type alkaloids (H2, H45) and a sarpagine-type alkaloid (H23), which were also detected in the brain. All compounds detected in the tissues are shown in

Table 2. The peak heights of compounds in different tissue samples.

Tissues	Gelsemine (H2)	11-Hydroxygelsenicine (H11)	Gelsenicine (H14)	Dehydrokoumidine (H23)	14-Hydroxyrankinidine (H30)	Humantennine (H31)	Koumine (H32)	3-keto-urs-11-en-13β (28)-olide (H44)	GS-2(11-Methoxy-14-Hydroxygelsenicine) (H45)	Koumidine (H46)	H23-M2	H30-M1
Brain	8 × 106	2.9 × 105	-	0.9 × 106	2.1 × 105	2 × 105	4 × 105	2.9 × 107	2.2 × 105	3.1 × 105	-	-
Spinal cord	3 ×105	-	-	1 × 106	-	-	-	-	2.1 × 105	-	-	-
Heart	8.2 × 105	8 × 105	2.9 × 105	2.9 × 106	6.1 × 105	1.1 × 105	2.6 × 105	3.9 × 107	-	-	-	-
Liver	-	-	-	2.9 × 105	-	-	-	-	-	-	-	-
Lung	2.0 × 106	-	1.9 × 105	3 × 107	2.9 × 107	-	-	-	-	5.9 × 106	3.1 × 105	-
Spleen	2.5 × 106	5.8 × 105	4.9 ×105	6 × 106	1.5 × 106	-	3.2 × 105	-	-	1 × 105	7 × 104	-
Adrenal gland	-	-	-	0.7 × 106	-	-	-	-	-	-	-	-
Testis	6.1 × 105	1.3 × 106	2 × 105	2 × 106	4.2 × 105	1.0 × 105	3.9 × 105	3 × 107	-	-	5.6 × 104	3.7 × 105
Thigh muscle	2.0 × 106	1.4 × 106	3 × 105	4.4 × 106	0.75 × 106	0.9 × 105	0.5 × 105	-	-	-	-	-
Abdominal muscle	1.25 × 106	1 × 106	4 × 105	2.1 × 106	3.9 × 105	-	6 × 105	-	-	-	-	-
Back muscle	7.9 × 105	5 × 105	1.8 × 105	1.9 × 106	3.1 × 105	8 × 104	2.5 × 105	4.1 × 107	-	-	-	-

“-” means that it was not detected in the tissue sample.

.

A total of eight compounds were tentatively characterized in the heart, including H2, H11, H14, H23, H30, H31, H32 and H44. Only compound H23 was detected in the liver and adrenal gland, and their content was very low. Five natural products were characterized in the lung, including H2, H14, H23, H46, H30, and H23-M2 were also detected. Compounds H2, H11, H14, H23, H30, H32 and H23-M2 were detected in the spleen and testis, compound H46 was only found in the spleen, and H31, H44 and H30-M1 were only detected in the genitals.

Finally, compounds H2, H11, H14, H23, H30 and H32 were detected in the thigh, abdominal, and back muscle samples. However, H31 was only found in abdominal and back muscles, and H44 was only detected in back muscles.

Dehydrokoumidine (H23) was detected in all tissues, and its content in the lung was the highest. Gelsemine (H2) was also detected in most tissues except the lungs and adrenal gland and was highest in the brain. Two metabolites (H23-M1, H30-M1) were detected only in the lungs, spleen, and testis, indicating that most metabolites are highly polar and excreted through the kidneys and bile.

3. Discussion

Previously, there have been studies on the pharmacokinetics of koumine, gelsemine, and gelsenicine in rats or mice [10]. These three single alkaloids have rapid absorption and are widely distributed and rapidly eliminated. Subsequently, our study explored the multicomponent pharmacokinetics of G. elegans in pigs [15,16]. The results showed that G. elegans alkaloids were rapidly absorbed in pigs but eliminated more slowly (the value of T1/2 was 8 to 12 h) than in rats and mice. However, multiple components’ metabolism and tissue distribution have not yet been studied. This study is the first to study the metabolism and tissue distribution of multiple components of G. elegans in pigs. This study detected ten natural products and four metabolites in bile, but only three natural products were detected in feces. Therefore, it is speculated that the slow elimination of G. elegans in pigs may be because G. elegans is involved in enterohepatic circulation. In addition, this study did not detect as many compounds because the pharmacokinetics study used the HPLC/QqQ-MS method. Because the detected concentration was low in the pig biological samples, many compounds were not detected by HPLC/QqTOF-MS. Although it is not possible to detect all compounds, metabolism and distribution studies can be performed on the compounds with a high content, which are active substances with G. elegans effects.

We used rat and pig liver S9 to investigate the in vitro metabolism of koumine and gelsemin [17,18]. The results show that the main metabolic pathways of koumine and gelsemine were dehydrogenation, hydrogenation, demethylation and oxidation, which was consistent with previous research results. However, these studies have not found phase II metabolites of these two alkaloids. Our previous study on goats used a single oral administration [14], but this study used long-term feeding. The method of administration was different, so the compounds detected in the biological samples of pigs were less than those observed in goats. In previous in vivo experiments in sheep, only plasma, urine and fecal samples were analyzed and determined, and a total of 44 absorbed natural products and 27 related metabolites were preliminarily characterized. Including gelsdine type, sarpagine type and gelsmeine type alkaloids are the compounds with the highest amount of metabolites. Most natural products are metabolized by glucuronidation and oxidation. In addition, hydrogenation, dehydrogenation and demethylation reactions also occur. However, this study analyzed and characterized the metabolites in plasma, urine, feces, bile and various tissues. This study first investigated the metabolic profile of multiple components of G. elegans in pigs. The metabolic pathways of 21-oxogelsemine (H6), 11-hydroxygelsenicine (H11), dehydrokoumidine (H23) and 14-hydroxyrankinidine (H30) in pigs are mainly reduced by hydrogenation, oxidation and glucuronidation. Many compounds were detected in bile in this study, especially phase II metabolites, indicating the existence of enterohepatic circulation in pigs, which may be the reason for the slow elimination of G. elegans. In addition, glucuronidation was the major metabolic pathway in pigs, accounting for 42.9%, as diagrammed in Figure 6D.

Compounds from G. elegans can be detected in all tissues, indicating that G. elegans is widely distributed in pigs. Figure 6A,B shows that most natural products were detected in the brain from all tissues, including koumine (H32) and gelsemine (H2). Some studies have shown that koumine and gelsemine have antianxiety and analgesic effects. These two alkaloids have low toxicity and potential for development, indicating that the overall administration of G. elegans was a multicomponent multitargeted mechanism. Moreover, it is shown in Figure 6C that the highly toxic alkaloids, the gelsedine type, were present in the highest concentrations in all biological samples, which may be the main reason for human poisoning after eating G. elegans. G. elegans was not toxic to pigs [19], possibly because of different pharmacokinetics and pharmacodynamics between the receptors and gelsedine-type alkaloids within the different species, but this needs further study. Additionally, gelsedine-type alkaloids have been characterized and detected in the lung, heart, and other tissues, indicating that G. elegans poisoning, respiratory failure, and rapid heartbeat may be caused by nerves’ direct and indirect effects. The study also found that compounds from G. elegans were distributed in the muscles and liver, which may threaten the safety of consumers of these animal products. Therefore, the withdrawal time required for G. elegans alkaloids to be eliminated from edible tissues needs further residue depletion studies.

In conclusion, high-performance liquid chromatography coupled to quadrupole time-of-flight mass spectrometry was used in this study to characterize multiple components of G. elegans in pig plasma, urine, feces, bile and different tissues. This is the first study to provide comprehensive information on the absorption, excretion, metabolism and tissue distribution of multiple components of G. elegans in pigs. These findings may help determine gelsedine-type alkaloids from G. elegans for further toxicity and residue studies, laying the foundation for further safety evaluations of products of animals fed G. elegans and promoting the development and utilization of G. elegans in livestock farming.

4. Materials and Methods

4.1. Chemicals and Reagents

Gelsemine (CAS#: 509-15-9, purity: 99.28%), koumine (CAS#: 1358-76-5, purity: 99.53%) and humantenmine (CAS#: 354-38-9, purity: 99.84%) were purchased from Shanghai Kang Biao Chemicals Co., Ltd. (Minhang District, Shanghai, China). Methanol, acetonitrile and formic acid were obtained from Merck Chemicals Co. (Darmstadt, Germany). Water was purified using a Milli-Q water purification system (Millipore, Bedford, MA, USA).

4.2. Plants Material

The raw material of G. elegans plants was cultivated in Longyan City, Fujian Province, China (N 24°43′12″, E 116°43′48″). Vegetative whole plants of G. elegans were collected in the area in 2016. Crude samples of G. elegans were dried in the sunlight for 2–3 days and milled into a powder. Then, the powder was passed through a 100-mesh sieve to obtain the G. elegans powder. Associate Professor Qi Tang at Hunan Agricultural University authenticated the samples. The samples were stored in our laboratory, and the voucher number is 1537201809.

4.3. Animal Experiments

Nine male ternary hybrid pigs approximately 60 days old (20 ± 2 kg) were obtained from Hunan New Wellful Co., Ltd. (Changsha, China). Four were fed a complete diet as the control group, and the other five were fed G. elegans (a complete diet supplemented with 2% G. elegans powder) as the experimental group. After 45 days of continuous feeding, administration of G. elegans was stopped, and all pigs were fasted for 12 h [15]. The experimental protocol was performed in accordance with Animal Care and Use of China. Then, all the pigs were slaughtered (before slaughter, blood was collected from the common artery using vacuum blood collection vessels) 6 h after the last feeding. Bile and 11 tissue samples were obtained from each pig, including the heart, liver, lung, spleen, brain, spinal cord, adrenal gland, genitals, thigh muscle, abdominal muscle and back muscle. Instantly, anticoagulated blood was collected and centrifuged at 1200 rpm for 15 min. Since the defecation time of pigs is uncontrollable, all urine and feces excreted within six hours after stopping feeding were collected and stored at −80 °C.

4.3.1. Plasma Samples

Before analysis, pig plasma was warmed to room temperature, and 200 μL of each plasma sample was mixed with 1 mL of 1% formic acid-acetonitrile to precipitate the proteins, followed by centrifugation at 10,000 rpm for 10 min. The supernatant was filtered through a 0.22-μm microbore cellulose membrane for HPLC/QqTOF-MS analysis. Treatment of the plasma samples was based on our previous study [16].

4.3.2. Urine Samples

Urine (200 μL) was added to 1 mL of 1% formic acid-acetonitrile, vortexed 2–3 times for 1–2 min each time and centrifuged at 10,000 rpm for 10 min. The supernatant was filtered through a 0.22-μm microbore cellulose membrane for HPLC/QqTOF-MS analysis. Treatment of the urine samples was similar to the treatment of the plasma samples.

4.3.3. Feces Samples

Two grams of feces were accurately weighed and mixed with 4 mL of 1% formic acid-acetonitrile and then centrifuged at 10,000 rpm for 10 min. One milliliter of supernatant was collected and filtered through a 0.22-μm microbore cellulose membrane for HPLC/QqTOF-MS analysis. Treatment of the fecal samples was similar to the treatment of the plasma samples.

4.3.4. Bile Samples

A 200 μL aliquot of bile was mixed with 1 mL of 1% formic acid-acetonitrile to precipitate the proteins and then centrifuged at 10,000 rpm for 10 min. The supernatant was filtered through a 0.22-μm microbore cellulose membrane for HPLC/QqTOF-MS analysis. The treatment of bile samples was similar to the treatment of the plasma samples. Treatment of the bile samples was based on our previous study.

4.3.5. Tissue Samples

Tissue sample samples (2 g) were accurately weighed and mixed with 4 mL of 1% formic acid-acetonitrile. The samples were vortexed 2–3 times for 1–2 min each time and centrifuged at 10,000 rpm for 10 min. The supernatant was poured into a clean 10.0-mL centrifuge tube, the liquid was dried completely with nitrogen, and then the samples were dissolved in acetonitrile (200 μL) and 0.1% formic acid (800 μL). After all the solids had dissolved, 1 mL of the supernatant was filtered through a 0.22-μm microbore cellulose membrane for HPLC/QqTOF-MS analysis.

4.3.6. HPLC/QqTOF-MS Analysis Conditions

An Agilent 6530 Q-TOF mass spectrometer coupled with an Agilent 1290 HPLC system was used (Agilent Technologies, Palo Alto, CA, USA). The HPLC chromatographic system was equipped with an autosampler, a rapid-resolution binary pump, a vacuum degasser, a thermostatic column compartment and a UV detector. A Thermo-C18 column (2.1 mm × 150 mm i.d.; particle size, 3.5 μm) was used for the separation. The mobile phase consisted of 0.1% formic acid in water (A) and acetonitrile (B). The gradient was as follows: 0–5 min, 10% B; 5–20 min, 10–90% B; 20–25 min, 90% B; and 25–30 min, 10% B. The injection volume was 5 μL, and the flow rate was 0.3 mL/min. The column temperature was maintained at 30 °C.

The mass spectrometer was equipped with an electrospray ionization source and was operated in positive mode. Mass spectrometric analyses were carried out in full-scan MS mode with a mass range of m/z 50–1000 and auto MS/MS acquisition. The operating parameters were as follows: gas temperature, 300 °C; capillary voltage, 4.0 kV; nebulizer pressure, 35 psi; sheath gas temperature, 350 °C; sheath gas flow rate, 11 L/min; skimmer voltage, 65 V; and fragmentor voltage, 175 V. Nitrogen was used as the nebulizing gas at a flow rate of 9 L/min. Accurate mass measurements of each peak from the total ion chromatograms (TIC) were obtained using an automated calibrant delivery system to provide the mass corrections. The calibration solution contained internal reference masses at m/z 121.0508 and 922.0098 in positive ion mode. All data acquisition was controlled by Agilent Mass Hunter software (version B.01.03, build 1.3.157.0 2).