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Pyrrolizidine alkaloid

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Skeletal formula of retronecine, a pyrrolizidine alkaloid found in the common groundsel (Senecio vulgaris) and comfrey (Symphytum spp.)

Pyrrolizidine alkaloids (PAs), sometimes referred to as necine bases, are a group of naturally occurring alkaloids based on the structure of pyrrolizidine. Their use dates back centuries and is intertwined with the discovery, understanding, and eventual recognition of their toxicity on humans and animals.[1]

History

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PAs were first discovered in plants in the 19th century, but their toxic effects were not immediately recognized.[2] Instead, many PA-containing plants were traditionally used for medicinal purposes in various cultures around the world. For example, herbs containing PAs were used in traditional Chinese medicine and by Native American tribes for their purported therapeutic properties.[3] It has been estimated that 3% of the world's flowering plants contain pyrrolizidine alkaloids.[4] Honey can contain pyrrolizidine alkaloids,[5][6] as can grains, milk, offal and eggs.[7] To date (2011), there is no international regulation of PAs in food, unlike those for herbs and medicines.[8]

In the early to mid-20th century, researchers began to observe and document cases of livestock poisoning linked to the consumption of PA-containing plants.[9] These observations led to the recognition of PAs as potent hepatotoxic and genotoxic compounds.[10]

In response to growing concerns about PA exposure, regulatory agencies around the world began to establish guidelines and regulations to limit PA levels in food, herbal products, and animal feed.[11] These regulations aim to protect human and animal health by minimizing PA exposure and mitigating the risk of toxicity.

Despite regulatory efforts, the issue of PA exposure remains relevant today. Ongoing research continues to explore various aspects of PA toxicity, including the identification of new PA-containing plants, the development of sensitive analytical methods, and the assessment of human health risks associated with PA exposure.[12] Additionally, efforts to raise awareness among healthcare professionals, herbal product manufacturers, and the general public about the risks of PA exposure are ongoing.

Natural occurrence

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PAs are a group of naturally occurring compounds found in a wide range of plant species. These alkaloids are secondary metabolites synthesized by plants primarily as a defense mechanism against herbivores, insects, and pathogens.[13]

The biosynthesis of PAs was discovered to occur through the first pathway-specific enzyme homospermidine synthase.[14]

Biosynthesis of PAs[15]

The polyamines putrescine and spermidine are derived from the basic amino acid arginine. Subsequently, homospermidine synthase exchanges the 1,3-diamonopropane by putrescine and forms symmetric homospermidine. Oxidation of homospermidine by copper-dependent diamine oxidases initiates cyclization to pyrrolizidine-1-carbaldehyde, which is reduced, to 1-hydroxymethylpyrrolizidine. Desaturation and hydroxylation ultimately form retronecine, which is acylated with an activated necic acid, for instance with senecyl-CoA2 as in the example shown below.[15]

PAs are preferably found in the plant families Asteraceae (tribes Eupatorieae and Senecioneae), Boraginaceae (many genera), Fabaceae (mainly the genus Crotalaria), and Orchidaceae (nine genera). More than 95% of the PA-containing species investigated thus far belong to these four families.[14]

Structure and reactivity

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Chemical structures of the necine bases[16]

PAs are compounds made up of a necine base, a double five-membered ring with a nitrogen atom in the middle, and one or two carboxylic esters called necic acids.[17] Four major necine bases are described, with retronecine and its enantiomer Heliotridine being the largest group, and highly toxic. Another group is the platynecine, the difference between these groups is its saturated base, which makes it less toxic.[18] Most bases have a 1,2-unsaturated base. Another difference in the groups is with Otonecine, which cannot form N-oxides, due to the methylation of the nitrogen atom.[16]

Chemical structures of various PAs

The alcohol groups on the necine bases can make esters in a wide variety of forms. Among the possibilities are mono-esters, like Floridine and Heliotrine, and di-esters either with an open or closed ring structure, like Usaramine and Lasiocarpine. In total more than 660 PAs and PA N-oxides have been identified in over 6000 plants.[11]

Synthesis

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There are multiple ways to synthesize PAs and their derivatives. A flexible strategy would be to start with a Boc (tert-Butoxycarbonyl) protected pyrrole molecule and use specific reaction for synthesis into the desired compound.[19]

A general strategy for the production of pyrrolizidine alkaloids is described, starting from intermediate (+)−9. The key features are diastereoselective dihydroxylation, inversion at the ring junction by hydroboration of an enamine, and ring closure to form the bicyclo ring system.[19]

Mechanisms of actions and metabolism

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PAs are commonly introduced into the body via oral ingestion through contaminated food or traditional medicine, notably borage leaf, comfrey and coltsfoot.[20] It can readily form salts with nitrates, chlorides and sulphates, which facilitate the uptake in the gastrointestinal tract. After which they travel to the liver via the portal vein.[21][22]

Proposed hepatic metabolic activation of retronecine-type and otonecine-type PAs to form pyrrolic esters, which further interact with glutathione or proteins to generate pyrrole–GSH conjugates or pyrrole–protein adducts, respectively.[23]

Metabolites form mostly in the liver. Here esterases can hydrolyze the PAs to reduce the compound into its necine acids and bases, both forms are non-toxic for humans and do not damage the body. However, cytochrome P450 (CYP450) also metabolizes PAs, this enzyme can form pyrrolic esters (EPy), these are hepatotoxic due to their high reactivity. The EPy can also be hydrolyzed into alcoholic pyrroles, which are mutagenic and carcinogenic.[24][23]

Since this mostly happens in the liver, this is the most affected organ. Other affected organs are the lungs and kidneys. The EPy can escape the liver, and travel through the Disse space into the bloodstream.

The electrophilic nature of pyrroles makes it an easy target for nucleophilic attack from nucleic acids and protein. If bound by glutathione it can become a non-toxic conjugate and be excreted via the kidneys.[24][25]

A second detoxifying pathway is the formation of the N-oxide[26][27] In the liver and lungs of certain mammal species enzymes called monooxygenase can prevent aromatization of the double 5-ring and in turn prevent the formation of the pyrrole-protein adduct.[20]

Toxicological effects

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The toxicity consequences resulting from the metabolism of PAs in humans primarily revolve around hepatotoxicity and genotoxicity.[1]

Pathogenesis of PA-induced HSOS[16]

PAs are metabolized in the liver through CYP450-mediated pathways. This metabolic process leads to the formation of reactive intermediates, such as pyrrolic metabolites, which can covalently bind to proteins in the liver, forming pyrrole-protein adducts. These adducts impair the function of essential liver proteins, leading to hepatotoxicity. The severity of liver damage correlates with the level of pyrrole-protein adduct formation. Hepatotoxicity induced by PAs can manifest as liver injury, inflammation, necrosis, HSOS (Hepatic Sinusoidal Obstruction Syndrome) and even liver failure in severe cases.[16][28] The pathogenesis of PAs-induces HSOS is shown by Xu.

Genotoxicity is another consequence of PA metabolism. The reactive metabolites formed during PA metabolism can also bind to DNA, leading to the formation of DNA adducts. These adducts can induce mutations and DNA damage, increasing the risk of cancer development and other adverse health effects. Genotoxicity is particularly concerning as it can lead to long-term health consequences, including carcinogenesis.[29]

The toxicity of PA metabolites can vary depending on the specific PA compound and its chemical structure. Different PAs may undergo metabolic activation to varying degrees, resulting in differences in toxicity. For example, retronecine-type PAs like monocrotaline are known to be highly hepatotoxic, while other types may exhibit lower toxicity or different toxicological profiles.[30]

Pharmacological effects

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Next to its toxicological effects, PAs have long been researched for their potential beneficial effects.[18] Traditional medicinal plants have long been known to contain PAs, the exact effect of the PAs regarding beneficial effect of the plants is debated.[31] Among these traditional medicines is the root of Ligularia achyrotricha of Tibet.[32] Several pharmacological effects have been found. Among these effects are antimicrobial activity,[33][34] antiviral activity[35] and antineoplastic activity,[36][37] acetylcholinesterase inhibition,[38][39] and gastric ulcers treatment.[40]

Antimicrobial activity of several PAs have been identified as having mild to strong effect against bacteria: E. coli and P. chrysogenum.[33] In particular Lasiocarpine and 7-angeloyl heliotrine were found to have significant activity against these microbes. Derivatives of PAs have been found to induce cell death in these bacteria by attacking bacterial cell membranes. Retronecine derivatives have been found slow the growth rate of several strains of the fungus Fusarium oxysporum.[34]

Antiviral activity has been found in haliotridine derivates.[35] However, effects are not consistent across PA compounds, derivates significantly differ in activity between different viral pathogens. As a result, it is difficult to determine an exact PA with an effect on a specific virus. Several PAs have been found with significant inhibition of growth in the following viruses: coxsackie, poliomyelitis, measles, and vesicular stomatitis.

Antineoplastic activity, specifically against leukemia, has been found in retronecine derivatives such as indicine.[36] A 1984 study by L. Letendre treated 22 leukaemia patients with indicine, this resulted in a significant observed antineoplastic response with four complete remissions and five partial remissions. An observed adverse side effect of the treatment was observed in 5 patients who died of hepatic toxicity likely caused by the medication. Two different dose levels were tested on children: 2 g/m2/ day for 5 consecutive days (14 patients) and 2,5 g/m2/ day for 5 consecutive days (17 patients).[37] Therapeutic effect was determined based on these doses and deemed to have a limited antileukemic effect below a dose of 3 g/m2/ day. However, this study also found severe hepatotoxic responses to be common at these doses.

Four known PAs, 7-O-angeloyllycopsamine N-oxide, echimidine N-oxide, echimidine, and 7-O-angeloylretronecine have been clinically shown to inhibit acetylcholinesterase (AChE) .[38] AChE inhibitors have been used as one of the treatments for Alzheimer's disease.[39] The effect of these compounds was significant in the reduction of AChE production and thus a potential alternative in the fight against Alzheimer's.

PAs like senecionine, integerrimine, retrorsine, usaramine and seneciphylline have been shown to cause an increase in both the levels of gastrin and the expression of epidermal growth factor (EGF).[40] These two compounds aid in the repair of the stomach after gastric ulcers. A high concentration of said compounds can reduce lesions in the stomach. This may aid in treatment after operation to the stomach.

Effects on animals

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The toxicological effects of PAs have been studied on animals. Retronecine derivatives are known to cause a toxic response in the livers of livestock like cows.[41] Symptoms tend to start with a change in rough hair coat and depression. When Pregnant livestock is exposed to PAs an effect can be seen on the foetus, mainly stillbirth and accumulation in the foetus. The main lethal responses in adult livestock exhibit necrosis, HSOS and megalacytosis. Additional to the short-term effect PAs have been found to lead to carcinogenic growths on the long term. The carcinogenic effect is caused by formation of DNA adducts,[20] because of metabolic reactions. No minimum dosage for the carcinogenic effect is currently known. However, there have been studies to determine the lowest dose for an adverse effect, also known as LOAEL.[42] LOAEL and LD50 (oral) for 40 PAs have been experimentally found out. These values can be seen in the Table below. The found low LD50 values clearly show the relatively high toxicity of PAs, however no significant relation was found between the LD50 and LOAEL.

Recorded LD50 and LOAEL values[42]
Type Compound LD50 (g/kg) LOAEL (g/kg)
Retronecine types Retrorsine∗ 0.320 0.001
Clivorine 0.386 0.002
Riddelliine 0.616 0.015
Senecionine 0.127 0.001
Usaramine 0.264 0.002
Jacobine 0.461 0.003
Monocrotaline∗ 0.731 0.002
Seneciphylline 0.264 0.002
Integerrimine 0.254 0.002
Senecivernine 0.592 0.004
Jacoline 0.230 0.001
Trichodesmine 0.324 0.004
Fulvine 0.369 0.002
Angularine 0.559 0.009
Crotananine 0.592 0.004
7-Acetylintermedine 0.559 0.009
7-Acetyllycopsamine 0.356 0.003
Echimidine 0.616 0.015
Echiumine 0.122 0.001
Lycopsamine 0.239 0.001
Intermedine 0.264 0.002
Indicine 0.264 0.002
Retronecine∗ 0.242 0.001
Lasiocarpine 0.555 0.001
Heliosupine 0.708 0.002
Heleurine 0.616 0.015
Supinine 0.215 0.001
Callimorphine 0.559 0.009
Heliotrine 0.056 0.001
Echinatine 0.250 0.003
Rinderine 0.486 0.001
Platynecine types Platyphylline∗ 0.443 0.002
Trachelanthamine 0.391 0.001
Heliocoromandaline 0.246 0.004
Heliocurassavicine 0.404 0.001
Otonicine types Acetylanonamine 0.230 0.001
Senkirkine 0.275 0.001
Otosenine 0.106 0.001
Petasitenine 0.264 0.002
Otonecine 0.467 0.001

PAs are also used as a defense mechanism by some organisms such as Utetheisa ornatrix. Utetheisa ornatrix caterpillars obtain these toxins from their food plants and use them as a deterrent for predators. PAs protect them from most of their natural enemies. The toxins stay in these organisms even when they metamorphose into adult moths, continuing to protect them throughout their adult stage.[43]

Plants species containing pyrrolizidine alkaloids

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This is a dynamic list and may never be able to satisfy particular standards for completeness. You can help by adding missing items with reliable sources

References

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  1. ^ a b Moreira, Rute; Pereira, David M.; Valentão, Patrícia; Andrade, Paula B. (June 2018). "Pyrrolizidine Alkaloids: Chemistry, Pharmacology, Toxicology and Food Safety". International Journal of Molecular Sciences. 19 (6): 1668. doi:10.3390/ijms19061668. ISSN 1422-0067. PMC 6032134. PMID 29874826.
  2. ^ Gilruth, J (1903). Hepatic cirrhosis Affecting Horses and Cattle (So-Called "Winton Disease"). OCLC 418874883.
  3. ^ Wiedenfeld, Helmut; Edgar, John (2011-03-01). "Toxicity of pyrrolizidine alkaloids to humans and ruminants". Phytochemistry Reviews. 10 (1): 137–151. Bibcode:2011PChRv..10..137W. doi:10.1007/s11101-010-9174-0. ISSN 1572-980X.
  4. ^ Smith, L. W.; Culvenor, C. C. J. (April 1981). "Plant Sources of Hepatotoxic Pyrrolizidine Alkaloids". Journal of Natural Products. 44 (2): 129–152. doi:10.1021/np50014a001. ISSN 0163-3864. PMID 7017073.
  5. ^ Kempf, Michael; Reinhard, Annika; Beuerle, Till (January 2010). "Pyrrolizidine alkaloids (PAs) in honey and pollen-legal regulation of PA levels in food and animal feed required". Molecular Nutrition & Food Research. 54 (1): 158–168. doi:10.1002/mnfr.200900529. ISSN 1613-4125. PMID 20013889.
  6. ^ Edgar, John A.; Roeder, Erhard; Molyneux, Russell J. (2002-05-08). "Honey from Plants Containing Pyrrolizidine Alkaloids: A Potential Threat to Health". Journal of Agricultural and Food Chemistry. 50 (10): 2719–2730. doi:10.1021/jf0114482. ISSN 0021-8561. PMID 11982390.
  7. ^ https://web.archive.org/web/20091014232504/http://www.foodstandards.gov.au/_srcfiles/TR2.pdf. Archived from the original (PDF) on 2009-10-14. Retrieved 2024-03-15. {{cite web}}: Missing or empty |title= (help)
  8. ^ Coulombe, Roger A. Jr (2003). "Pyrrolizidine alkaloids in foods". Advances in Food and Nutrition Research Volume 45. Vol. 45. pp. 61–99. Elsevier Science. ISBN 978-0-12-016445-5.
  9. ^ Gilruth, J. A. (1905-07-01). "Hepatic Cirrhosis in Sheep Due to Ragwort (Senecio Jacobœa)". The Veterinary Journal. 61 (7): 30–33. doi:10.1016/S0372-5545(17)70348-3. ISSN 0372-5545.
  10. ^ Bull, L. B.; Dick, A. T. (October 1959). "The chronic pathological effects on the liver of the rat of the pyrrolizidine alkaloids heliotrine, lasiocarpine, and their N -oxides". The Journal of Pathology and Bacteriology. 78 (2): 483–502. doi:10.1002/path.1700780215. ISSN 0368-3494. PMID 13805866.
  11. ^ a b "Invited Speakers". Drug Metabolism Reviews. 42 (sup1): 1–323. August 2010. doi:10.3109/03602532.2010.506057. ISSN 0360-2532.
  12. ^ Mulder, Patrick P.J.; Sánchez, Patricia López; These, Anja; Preiss-Weigert, Angelika; Castellari, Massimo (August 2015). "Occurrence of Pyrrolizidine Alkaloids in food". EFSA Supporting Publications. 12 (8). doi:10.2903/sp.efsa.2015.EN-859.
  13. ^ Macel, Mirka (2011-03-01). "Attract and deter: a dual role for pyrrolizidine alkaloids in plant–insect interactions". Phytochemistry Reviews. 10 (1): 75–82. Bibcode:2011PChRv..10...75M. doi:10.1007/s11101-010-9181-1. ISSN 1572-980X. PMC 3047672. PMID 21475391.
  14. ^ a b Ober, Dietrich; Hartmann, Thomas (1999-12-21). "Homospermidine synthase, the first pathway-specific enzyme of pyrrolizidine alkaloid biosynthesis, evolved from deoxyhypusine synthase". Proceedings of the National Academy of Sciences. 96 (26): 14777–14782. Bibcode:1999PNAS...9614777O. doi:10.1073/pnas.96.26.14777. ISSN 0027-8424. PMC 24724. PMID 10611289.
  15. ^ a b Schramm, Sebastian; Köhler, Nikolai; Rozhon, Wilfried (January 2019). "Pyrrolizidine Alkaloids: Biosynthesis, Biological Activities and Occurrence in Crop Plants". Molecules. 24 (3): 498. doi:10.3390/molecules24030498. ISSN 1420-3049. PMC 6385001. PMID 30704105.
  16. ^ a b c d Xu, Jie; Wang, Weiqian; Yang, Xiao; Xiong, Aizhen; Yang, Li; Wang, Zhengtao (December 2019). "Pyrrolizidine alkaloids: An update on their metabolism and hepatotoxicity mechanism". Liver Research. 3 (3–4): 176–184. doi:10.1016/j.livres.2019.11.004. ISSN 2542-5684.
  17. ^ Aniszewski, T. (2015). Alkaloids: Chemistry, Biology, Ecology, and Applications. Elsevier. ISBN 978-0-444-59462-4.
  18. ^ a b Wei, Xianqin; Ruan, Weibin; Vrieling, Klaas (January 2021). "Current Knowledge and Perspectives of Pyrrolizidine Alkaloids in Pharmacological Applications: A Mini-Review". Molecules. 26 (7): 1970. doi:10.3390/molecules26071970. ISSN 1420-3049. PMC 8037423. PMID 33807368.
  19. ^ a b Donohoe, Timothy J.; Thomas, Rhian E.; Cheeseman, Matthew D.; Rigby, Caroline L.; Bhalay, Gurdip; Linney, Ian D. (2008-08-21). "Flexible Strategy for the Synthesis of Pyrrolizidine Alkaloids". Organic Letters. 10 (16): 3615–3618. doi:10.1021/ol801415d. ISSN 1523-7060. PMID 18636741.
  20. ^ a b c Fu, P.P.; Yang, Y.-C.; Xia, Q.; Chou, M. W.; Cui, Y. Y.; Lin, G. (2020-07-14). "Pyrrolizidine alkaloids - Tumorigenic components in Chinese herbal medicines and dietary supplements". Journal of Food and Drug Analysis. 10 (4). doi:10.38212/2224-6614.2743. ISSN 2224-6614.
  21. ^ Luckert, Claudia; Hessel, Stefanie; Lenze, Dido; Lampen, Alfonso (2015-10-01). "Disturbance of gene expression in primary human hepatocytes by hepatotoxic pyrrolizidine alkaloids: A whole genome transcriptome analysis". Toxicology in Vitro. 29 (7): 1669–1682. Bibcode:2015ToxVi..29.1669L. doi:10.1016/j.tiv.2015.06.021. ISSN 0887-2333. PMID 26100227.
  22. ^ Stewart, Michael J.; Steenkamp, Vanessa (December 2001). "Pyrrolizidine Poisoning: A Neglected Area in Human Toxicology". Therapeutic Drug Monitoring. 23 (6): 698–708. doi:10.1097/00007691-200112000-00018. ISSN 0163-4356. PMID 11802107.
  23. ^ a b Ruan, Jianqing; Yang, Mengbi; Fu, Peter; Ye, Yang; Lin, Ge (2014-06-16). "Metabolic Activation of Pyrrolizidine Alkaloids: Insights into the Structural and Enzymatic Basis". Chemical Research in Toxicology. 27 (6): 1030–1039. doi:10.1021/tx500071q. ISSN 0893-228X. PMID 24836403.
  24. ^ a b Prakash, Arungundrum S; Pereira, Tamara N; Reilly, Paul E. B; Seawright, Alan A (1999-07-15). "Pyrrolizidine alkaloids in human diet". Mutation Research/Genetic Toxicology and Environmental Mutagenesis. 443 (1): 53–67. Bibcode:1999MRGTE.443...53P. doi:10.1016/S1383-5742(99)00010-1. ISSN 1383-5718. PMID 10415431.
  25. ^ Geburek, Ina; Preiss-Weigert, Angelika; Lahrssen-Wiederholt, Monika; Schrenk, Dieter; These, Anja (2020-01-01). "In vitro metabolism of pyrrolizidine alkaloids – Metabolic degradation and GSH conjugate formation of different structure types". Food and Chemical Toxicology. 135: 110868. doi:10.1016/j.fct.2019.110868. ISSN 0278-6915. PMID 31586656.
  26. ^ Williams, D. E.; Reed, R. L.; Kedzierski, B.; Ziegler, D. M.; Buhler, D. R. (1989). "The role of flavin-containing monooxygenase in the N-oxidation of the pyrrolizidine alkaloid senecionine". Drug Metabolism and Disposition: The Biological Fate of Chemicals. 17 (4): 380–386. ISSN 0090-9556. PMID 2571476.
  27. ^ Miranda, Cristobal L.; Chung, Woongye; Reed, Ralph E.; Zhao, Xine; Henderson, Marilyn C.; Wang, Jun-Lan; Williams, David E.; Buhler, Donald R. (1991-07-31). "Flavin-containing monooxygenase: A major detoxifying enzyme for the pyrrolizidine alkaloid senecionine in guinea pig tissues". Biochemical and Biophysical Research Communications. 178 (2): 546–552. doi:10.1016/0006-291X(91)90142-T. ISSN 0006-291X. PMID 1907134.
  28. ^ Zhang, Y. (2019). "Sinusoidal obstruction syndrome: A systematic review of etiologies, clinical symptoms, and magnetic resonance imaging features". World Journal of Clinical Cases. 7 (18): 2746–2759. doi:10.12998/wjcc.v7.i18.2746. PMC 6789402. PMID 31616690.
  29. ^ Chen, Tao; Mei, Nan; Fu, Peter P. (April 2010). "Genotoxicity of pyrrolizidine alkaloids". Journal of Applied Toxicology. 30 (3): 183–196. doi:10.1002/jat.1504. ISSN 0260-437X. PMC 6376482. PMID 20112250.
  30. ^ Wang, Ziqi; Han, Haolei; Wang, Chen; Zheng, Qinqin; Chen, Hongping; Zhang, Xiangchun; Hou, Ruyan (December 2021). "Hepatotoxicity of Pyrrolizidine Alkaloid Compound Intermedine: Comparison with Other Pyrrolizidine Alkaloids and Its Toxicological Mechanism". Toxins. 13 (12): 849. doi:10.3390/toxins13120849. ISSN 2072-6651. PMC 8709407. PMID 34941687.
  31. ^ Kopp, Thomas; Abdel-Tawab, Mona; Mizaikoff, Boris (May 2020). "Extracting and Analyzing Pyrrolizidine Alkaloids in Medicinal Plants: A Review". Toxins. 12 (5): 320. doi:10.3390/toxins12050320. ISSN 2072-6651. PMC 7290370. PMID 32413969.
  32. ^ Hua, L.; Chen, J.; Gao, K. (2012). "A new pyrrolizidine alkaloid and other constituents from the roots of Ligularia achyrotricha". Phytochemistry Letters. 5 (3): 541–544. doi:10.1016/j.phytol.2012.05.009.
  33. ^ a b Singh, B.; Sahu, P.M.; Singh, S. (April 2002). "Antimicrobial activity of pyrrolizidine alkaloids from Heliotropium subulatum". Fitoterapia. 73 (2): 153–155. doi:10.1016/S0367-326X(02)00016-3. PMID 11978430.
  34. ^ a b Hol, W. H. G.; Van Veen, J. A. (2002-09-01). "Pyrrolizidine Alkaloids from Senecio jacobaea Affect Fungal Growth". Journal of Chemical Ecology. 28 (9): 1763–1772. doi:10.1023/A:1020557000707. ISSN 1573-1561. PMID 12449504.
  35. ^ a b Singh, B.; Sahu, P.M.; Jain, S.C.; Singh, S. (January 2002). "Antineoplastic and Antiviral Screening of Pyrrolizidine Alkaloids from Heliotropium subulatum". Pharmaceutical Biology. 40 (8): 581–586. doi:10.1076/phbi.40.8.581.14659. ISSN 1388-0209.
  36. ^ a b Letendre, L.; Ludwig, J.; Perrault, J.; Smithson, W. A.; Kovach, J. S. (1984-10-01). "Hepatocellular toxicity during the treatment of refractory acute leukemia with indicine N-oxide". Cancer. 54 (7): 1256–1259. doi:10.1002/1097-0142(19841001)54:7<1256::aid-cncr2820540704>3.0.co;2-s. ISSN 0008-543X. PMID 6590115.
  37. ^ a b Miser, J. S.; Smithson, W. A.; Krivit, W.; Hughes, C. H.; Davis, D.; Krailo, M. D.; Hammond, G. D. (April 1992). "Phase II trial of indicine N-oxide in relapsed acute leukemia of childhood. A report from the Childrens Cancer Study Group". American Journal of Clinical Oncology. 15 (2): 135–140. doi:10.1097/00000421-199204000-00008. ISSN 0277-3732. PMID 1553901.
  38. ^ a b Benamar, Houari; Tomassini, Lamberto; Venditti, Alessandro; Marouf, Abderrazak; Bennaceur, Malika; Nicoletti, Marcello (2016-11-16). "Pyrrolizidine alkaloids from Solenanthus lanatus DC. with acetylcholinesterase inhibitory activity". Natural Product Research. 30 (22): 2567–2574. doi:10.1080/14786419.2015.1131984. ISSN 1478-6419. PMID 26735939.
  39. ^ a b Akıncıoğlu, Hulya; Gülçin, İlhami (2020). "Potent Acetylcholinesterase Inhibitors: Potential Drugs for Alzheimer's Disease". Mini-Reviews in Medicinal Chemistry. 20 (8): 703–715. doi:10.2174/1389557520666200103100521. PMID 31902355.
  40. ^ a b Toma, Walber; Trigo, José Roberto; Bensuaski de Paula, Ana Cláudia; Monteiro Souza Brito, Alba Regina (2004-05-01). "Modulation of gastrin and epidermal growth factor by pyrrolizidine alkaloids obtained from Senecio brasiliensis in acute and chronic induced gastric ulcers". Canadian Journal of Physiology and Pharmacology. 82 (5): 319–325. doi:10.1139/y04-023. ISSN 0008-4212. PMID 15213731.
  41. ^ Molyneux, R. J.; Gardner, D. L.; Colegate, S. M.; Edgar, J. A. (March 2011). "Pyrrolizidine alkaloid toxicity in livestock: a paradigm for human poisoning?". Food Additives & Contaminants. Part A, Chemistry, Analysis, Control, Exposure & Risk Assessment. 28 (3): 293–307. doi:10.1080/19440049.2010.547519. ISSN 1944-0057. PMID 21360375.
  42. ^ a b Zheng, Pimiao; Xu, Yuliang; Ren, Zhenhui; Wang, Zile; Wang, Sihan; Xiong, Jincheng; Zhang, Huixia; Jiang, Haiyang (2021-01-04). "Toxic Prediction of Pyrrolizidine Alkaloids and Structure-Dependent Induction of Apoptosis in HepaRG Cells". Oxidative Medicine and Cellular Longevity. 2021: e8822304. doi:10.1155/2021/8822304. ISSN 1942-0900. PMC 7801077. PMID 33488944.
  43. ^ Conner, William E., ed. (2009). Tiger moths and woolly bears: behavior, ecology, and evolution of the Arctiidae. Oxford ; New York: Oxford University Press. ISBN 978-0-19-532737-3. OCLC 212908684.