1. Introduction

Equids grazing on European pasture are at risk of lethal intoxication by ingesting seeds and seedlings from the sycamore maple (Acer pseudoplatanus) [1,2,3,4,5,6]. Botanically, maple trees belong to the Sapindaceae family. Deaths caused by components of these trees have also been described in zoo animals [7,8,9,10]. Intoxications by Sapindaceae toxins are also of concern for human medicine [11,12,13,14]. The proven toxic constituents are hypoglycin A (methylenecyclopropylalanine, HGA) and methylenecyclopropylglycine (MCPrG). Both also occur as dipeptides conjugated with glutamic acid (hypoglycin B and α-glutamyl MCPrG, respectively) [15]. Both HGA and MCPrG are not toxic by themselves. They are rather to be regarded as protoxins that have to be transformed into toxically active compounds.

The metabolism of HGA and MCPrG is known to duplicate the first two steps occurring with branched-chain amino acids [16,17]. The enzymatic activation takes place after the so-called LAT1 transporter, an ubiquitously expressed transport protein from the system L transporter family, has effected the transfer into the intracellular space. The first reaction there consists of the deamination of HGA or MCPrG by a branched-chain aminotransferase (BCAT, EC 2.6.1.42) [18,19]. Thus, MCP-pyruvate is formed from HGA and MCP-glyoxalate from MCPrG.

Unlike other amino acids, the first step of catabolism of the branched molecules does not take place preferentially in the liver but in the skeletal muscles. This gives rise to the assumption that the deamination of HGA and MCPrG can also take place to a large extent in this tissue. One of the aims of our study was to test this theory.

In a second enzymatic step, the α-keto acids formed by transamination are converted by the branched-chain α-keto acid dehydrogenase complex (BCKDHc; EC 1.2.4.4) into the corresponding acyl-CoA derivatives. The activity of the enzymes varies from tissue to tissue, both inter- and intraspecifically, and can also show large differences within an organ [20,21,22]. The products of the toxin activation are the CoA esters of methylenecyclopropylacetate (MCPA) and methylenecyclopropylformate (MCPF), respectively. Regarding the tissue-specific enzyme activities, we wanted to examine to what extent an activation of the protoxins shows a tissue-typical pattern.

The clinical presentation of Sapindaceae intoxication is characterized by acute onset and high lethality. Death usually occurs within 2 days after the onset of the clinical manifestation. An acute rhabdomyolysis syndrome combined with marked hyperglycemia determines the clinical picture in equids [23,24]. In horses, initial knowledge of the pathophysiological process has improved supportive therapy [25] and refined the decision criteria for euthanasia [26].

Necroscopic examination reveals extensive muscle necrosis, predominantly in the postural and respiratory muscles. The extent and severity of the changes vary considerably, not only between individuals but also between the different muscles of each animal. It is worth noting that in some cases, macroscopic lesions are not observed. Within an affected muscle, the degree of myodegeneration may vary greatly. Histology revealed abundant neutral fat, predominantly in type 1 muscle fibers [27,28]. Electron microscopy shows morphological changes in the mitochondria [27,29]. Westermann et al. found deficiencies of short-chain and medium-chain as well as isovaleryl-CoA dehydrogenases in muscle tissue [29]. The plasma/serum acylcarnitines profile showed increased concentrations of short- and medium-chain carnitine esters [29] but also of long-chain acylcarnitines [26]. A further aim of our investigations was therefore to examine whether the expected tissue-specific activation of the protoxins would also lead to a tissue-specific accumulation of products of the energy metabolism.

In some horses, severe macroscopic and histological changes in the myocardium have been found with the presence of pale areas, accumulation of neutral fat, and/or granular degeneration of myocardium cells, while no lesions were found in others [6,23,27,28]. However, elevated troponin I in the blood [26] and both electrocardiographic and echocardiographic changes were seen in most investigated cases [30]. Inhibition of 2-ketoglutarate and pyruvate dehydrogenases in bovine heart mitochondria [31] and reversible inhibition of long-chain acyl-CoA:carnitine acyltransferase were described [32].

Visual examination of other equine tissues such as the central and peripheral nervous systems or the pancreas did not reveal specific lesions; however, forebrain swelling with cellular oedema was reported as well as some little hemorrhage foci on the meninges in the first clinical series. Apart from hyaline, granular, or myoglobin-containing cylinders in the tubules of the kidney, the parenchymatous organs showed no histological abnormalities [27,28]. In rats, ultrastructural electron microscopic examination revealed swelling of the mitochondria of liver cells and a reduction in matrix density 3–5 h after intraperitoneal injection of a high HGA dose (i.e., 100 mg/kg; [33]).

In the case of poisoning, routine laboratory tests show a severe increase in muscle enzyme activity and, most of the time, hyperglycemia, high haptoglobin concentration, hyperlipaemia, high troponin I, and increased liver enzyme activity [23,24,26]. In the urine of horses, myoglobin is excreted in large quantities [24,29]. Such analyses are valuable diagnostic tools in cases of Sapindaceae intoxication. However, they do not provide any information about the affected tissues.

The therapy of maple intoxication has so far only been successful to a very limited extent. If one wishes to improve it decisively, more precise knowledge of the pathobiochemistry is required. This study is intended to make a contribution to this.

2. Materials and Methods

2.1. Horses

Five horses with a tentative diagnosis of atypical myopathy according to a diagnostic algorithm [34] used in the literature [26,35,36] were included in this study (Table 1). Serum samples were obtained from four of them just prior to euthanasia being decided due to the progressively worsening of respiratory difficulties [37]. No blood sample was available for one horse that was found dead in pasture. All five horses were necropsied between 1 and 4 days after spontaneous death or euthanasia.

Samples of the semitendinosus, triceps brachii, gluteus medius, myocardium, and diaphragm muscles were taken, as well as samples of the liver, kidney, and pancreas. The cerebrospinal fluid was collected from three horses during necropsy. In addition, in the four euthanized animals, collection of samples of the semitendinosus muscle took place not only at necropsy but also immediately after death.

Tissues from five slaughtered animals served as controls. The pancreas and cerebrospinal fluid of unaffected horses were not available. An undefined number of days elapsed between slaughtering and the acquisition of the material, during which the samples had been kept refrigerated but not frozen. Serum samples for control were taken from material examined for diseases not related to maple intoxication. Once collected, all samples were stored frozen at −18 °C until analysis.

2.2. Preparation and Use of Tissue Extracts

Quantities of 30 to 130 mg of material were separated from the frozen tissue samples using a scalpel, and 1000 µL of methanol was added. After brief mixing, samples were placed in an ultrasonic bath for 40 min at room temperature. Centrifugation at 14,000× g for 10 min produced a clear supernatant. A dilution factor was calculated from the ratio of the tissue weight to the amount of methanol. Analyses of liquid materials were conducted on 30 µL each.

It is not possible to give a completely accurate indication of the concentrations of protoxins, toxins, their metabolites, or acyl compounds because it is not possible to load animal tissues with these compounds in a reproducible manner. However, repeated extractions can give an indication of the degree of completeness of the initial extraction. It was found that only about 10% of the original concentration is obtained with a second extraction. Therefore, we assume that our analytical values correspond to about 90% of the total tissue contents.

2.3. Quantification of Toxins, Toxin Metabolites, and Several Acyl Metabolites

Ultra-performance liquid chromatography coupled with tandem mass spectrometry using a Xevo TQMS (Waters, Eschborn, Germany) was used for the quantification of HGA and MCPrG plus their metabolites in serum and tissue extracts, as described in detail earlier [38,39,40,41]. In addition, concentrations of C4 to C10 acyl conjugates were determined. This method also allowed for the differentiation of branched and unbranched C4 and C5 metabolites. Further carnitines and glycines were determined comparatively in four tissues of one horse. Statistical data on the normal distribution of concentrations of acyl compounds in the tissues of healthy horses are not available. Therefore, in this study, mean values obtained by examination of tissues from five healthy slaughtered animals were used for comparison.

Analyses were performed after butylation. The butyl esters were detected in electrospray ionization-positive mode by multiple reaction monitoring. For the separation of analytes, 5 µL of the final extracts were injected into an Acquity UPLC BEH C18 1.7 µm, 2.1 × 50 mm column (Waters, Eschborn, Germany). For gradient chromatography, acetonitrile/water eluents modified by 0.1% formic acid and 0.01% trifluoroacetic acid were used.

3. Results

3.1. Toxins and Toxin Metabolites

Neither toxins nor toxin metabolites of Sapindaceae were found in any of the control samples. As shown in Table 2, non-metabolized HGA was detected in all tissues as well as in the cerebrospinal fluid and the serum of the patients. Unmetabolized MCPrG (not listed in Table 2) was detected in trace amounts only. Concentrations of HGA differed based on the type of material analyzed. There were also large individual differences, as can be derived from the wide range of measured values. In skeletal muscles, including the diaphragm, HGA concentrations were generally found to be lower than in the heart, liver, kidney, and serum. The concentrations were particularly high in the pancreas. Concentrations here exceeded those of M. semitendinosus on the same horse by factors up to 23.8.

The distribution of the carnitine and glycine conjugates of MCPA and MCPF showed a pattern very different from that of HGA. MCPA-carinitine, formed from MCPA-CoA by conjugation with carnitine, as well as MCPF-carnitine, formed from MCPF-CoA, were present in very high concentrations in skeletal muscles. In contrast, in the cardiac muscle, the level of MCPA-carnitine was on average only 1.3% of the simultaneously present HGA. In the parenchymal tissues too, the metabolization of HGA was lower than in the skeletal muscles. Accordingly, the concentration of HGA was markedly higher there. The measured values for MCPA-carnitine in these organs, with a few exceptions in liver and kidney samples, were considerably lower than 10% of those of HGA.

MCPA-CoA and MCPF-CoA were conjugated with carnitine or glycine to quite different extents. In skeletal muscles, conjugation with carnitine was by far predominant for both CoA compounds. Again, this was not true for the cardiac muscle. Comparatively strong conjugation with glycine was found in the liver and was particularly pronounced in kidney tissue, which is known to have a high activity of glycine acyltransferase.

Results of a study on the post-mortem stability of HGA and MCPA-carnitine as well as three acylcarnitines in M. semitendinosus are summarized in Table 3. There was only a slight decrease in the concentration of HGA but a significant reduction in the concentration of MCPA-carnitine. For the acylcarnitines examined, there was a decrease in concentration by factors of up to 6.3.

3.2. Acylcarnitines and Acylglycines

As with toxin metabolites, tissue-specific accumulations of acyl compounds have been observed. Again, the skeletal muscles were particularly affected, as shown in Table 4.

In the four serum samples collected from 4 of the 5 horses with atypical myopathy, an increase in all acylcarnitines and hexanoylglycine was observed compared to samples collected from horses not affected by sycamore maple intoxication. In the tissues, however, this was only partly the case. Severely increased values were found for short- to medium-chain compounds in the skeletal muscles, but with large individual differences. The very high values for butyrylcarnitine prove a strong inhibition of the enzyme short-chain acyl-CoA dehydrogenase (EC 1.3.99.2). As an indication of the inhibition of the ß-oxidation of medium-chain fatty acids and the degradation of branched amino acids, the corresponding carnitine conjugates were found in the skeletal muscles of the diseased horses in considerably elevated concentrations. Additionally, the simultaneous accumulation of the monounsaturated decenoylcarnitine (C10:1), which is typical for cases of medium-chain acyl-CoA dehydrogenase (EC 1.3.8.7) deficiency in humans, was also observed here.

In the myocardium, accumulation of straight-chain acylcarnitines was only observed in two patients. In four cases, increased concentrations of the branched compounds isovalerylcarnitine and 2-methylbutyrylcarnitine were detected, but the maximum concentrations were often more than one order of magnitude lower than those in the skeletal muscle of the same animals.

In the liver, kidney, and pancreas, control levels were strongly exceeded only in some cases; in numerous samples, the measured values were in the control range.

Looking at the long-chain acylcarnitines, we found an enrichment of myristoyl-, palmitoyl-, and stearylcarnitine as well as of oleylcarnitine in the serum. Although higher concentrations of long-chain acylcarnitines were found in the skeletal muscles than in other tissues, similar levels were also observed in some controls. Thus, a toxin-dependent accumulation of long-chain acylcarnitines in these tissues was not proven.

The conjugation of the acyl residues in the skeletal muscles was predominantly with carnitine, while binding to glycine occurred to a much lesser extent. It is also evident that the ratios in the heart muscle and in the other tissues diverge strongly from this.

Table 5 illustrates the strong predominance of conjugation with carnitine versus glycine not only for butyric acid but also for branched fatty acids additionally quantified in the tissues of one horse.

4. Discussion

This paper is the first to show that HGA is distributed unhindered to all organs after intestinal absorption and that the protoxins are activated to a very unequal extent in the different organs to form the toxic products. The tissue-specific, varying accumulation of products of the energy metabolism was also demonstrated here for the first time. For the assessment of the quantitative results presented here, however, certain limitations should be considered.

Some uncertainty results from the fact that control tissues from slaughtered horses had to be used. The blood is always drained when the animal is for human consumption, but this is not the case when the animal is kept for necropsy. Tissue subtypes such as certain muscle fibers or the renal medulla and cortex could not be examined separately. Furthermore, it must be considered that the collection of material at any point in time always generates an instantaneous value at that very point in time. Pre-mortem changes may take place, and post-mortem alterations have been shown in this study. In addition, since horses on pastures ingest sycamore maple materials irregularly, quite different phases of resorption, metabolization, and excretion can be encountered at the time of the pathological-anatomical examination. HGA is known to be rapidly absorbed from the intestine. However, subsequent metabolization then takes place over a longer period [40,41]. There must be an accumulation when the toxin is taken up again in the decay phase.

Despite the uncertainties described, some basic statements can be made: one of the most important observations is that there is an unhindered distribution of HGA to different tissues, corresponding to an unmetabolized passage of the physiologic branched amino acids through the liver. The concentrations of HGA, however, were low in the cerebrospinal fluid. In the three cases examined, levels of only 212 to 356 nmol/L were found. Studies on a specific blood/brain barrier have not yet been published.

The metabolization rates of the protoxins proved to be very different in a tissue-typical manner. The very large differences in the concentrations of MCPA and MCPF derivatives found in the different tissues largely rule out an effective exchange of these metabolites between organs. It is also shown that the accumulation of the metabolites coming from the β-oxidation of fatty acids under the influence of the Sapindaceae toxins obeys a pattern typical of each tissue.

So far, little attention has been paid to the fact that sycamore maple materials contain not only HGA but also MCPrG [15,42], which, however, was not identified in significant concentrations in the serum or in the tissues in our investigation. The reason behind this is unknown. Whether instability in the matrix or rapid metabolization could be responsible requires further investigation. If MCPrG is absorbed in bound form, e.g., as a dipeptide with glutamic acid, it would not be detected with the analytics used in this study. In any case, the high concentrations of MCPF derivatives in skeletal muscle and other tissues suggest that MCPrG is a major contributor to the clinical manifestations of sycamore maple poisoning in equids.

In skeletal muscles, the CoA metabolites of HGA and MCPrG were preferentially conjugated with carnitine (Table 2). The use of carnitine in the treatment of HGA poisoning has occasionally been discussed [25,43]. The very high concentration of carnitine esters in the muscles, even without carnitine application, calls for caution. In contrast, in the liver and especially in the kidney, conjugation of MCPA but not MCPF also occurred to a greater extent with glycine. While MCPA carnitine was only released into the blood to a small extent, the glycine conjugate was detectable in the serum in slightly higher concentrations. The opposite was true for MCPF. An explanation of the tissue- and compound-specific differences would require further investigation.

It should be pointed out that at the time of euthanasia or spontaneous death, HGA was found in considerable quantities in the tissues and blood in an unmetabolized state. Large amounts of not yet metabolized HGA must be expected, especially before the clinical signs are approaching their peak. If one wants to intervene early, it is crucial to prevent further activation of HGA by MCPA-CoA. As HGA activation requires the interaction of several proteins, interruption of the function of one of these might be therapeutically useful. The importance of BCAT for the activation of sycamore maple toxins could be of interest because an inhibitor of the enzyme, gabapentin, is already being used in another veterinary context [44]. Furthermore, previous studies had shown that in the stomach and intestine, HGA can still be found in undigested sycamore maple material and is unabsorbed in the intestinal lumen [8,9]. Gastric/intestinal lavage and the application of activated charcoal could prevent further absorption to a certain extent [45].

5. Conclusions

In addition to HGA testing, a profound diagnosis of atypical myopathy additionally requires the quantitative determination of toxin metabolites as well as evidence of the interrupted ß-oxidation of fatty acids and of the disturbed energetic utilization of the branched amino acids. The subsequent severe skeletal muscle damage results in a sharp increase in serum creatine kinase activity, which confirms the rhabdomyolysis syndrome.

In light of the findings of this study, new therapeutic approaches could be considered, in particular the inhibition of the enzymes and transport systems that allow protoxins to become effective toxins. These possibilities could be used both for prevention (the toxins being ubiquitous in certain regions) and for emergency treatment, as the protoxins are still present in the blood and tissues of poisoned animals.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

References

1. Baise, E.; Habyarimana, J.A.; Amory, H.; Boemer, F.; Douny, C.; Gustin, P.; Marcillaud-Pitel, C.; Patarin, F.; Weber, M.; Votion, D.M. Samaras and seedlings of Acer pseudoplatanus are potential sources of hypoglycin A intoxication in atypical myopathy without necessarily inducing clinical signs. Equine Vet. J.; 2016; 48, pp. 414-417. [DOI: https://dx.doi.org/10.1111/evj.12499]

2. Unger, L.; Nicholson, A.; Jewitt, E.M.; Gerber, V.; Hegeman, A.; Sweetman, L.; Valberg, S. Hypoglycin a concentrations in seeds of acer pseudoplatanus trees growing on atypical myopathy-affected and control pastures. J. Vet. Intern. Med.; 2014; 28, pp. 1289-1293. [DOI: https://dx.doi.org/10.1111/jvim.12367]

3. Votion, D.M.; Habyarimana, J.A.; Scippo, M.L.; Richard, E.A.; Marcillaud-Pitel, C.; Erpicum, M.; Gustin, P. Potential new sources of hypoglycin A poisoning for equids kept at pasture in spring: A field pilot study. Vet. Rec.; 2019; 184, 740. [DOI: https://dx.doi.org/10.1136/vr.104424]

4. Votion, D.M.; Francois, A.C.; Kruse, C.; Renaud, B.; Farinelle, A.; Bouquieaux, M.C.; Marcillaud-Pitel, C.; Gustin, P. Answers to the Frequently Asked Questions Regarding Horse Feeding and Management Practices to Reduce the Risk of Atypical Myopathy. Animals; 2020; 10, 365. [DOI: https://dx.doi.org/10.3390/ani10020365]

5. Westermann, C.M.; van Leeuwen, R.; van Raamsdonk, L.W.; Mol, H.G. Hypoglycin A Concentrations in Maple Tree Species in the Netherlands and the Occurrence of Atypical Myopathy in Horses. J. Vet. Intern. Med.; 2016; 30, pp. 880-884. [DOI: https://dx.doi.org/10.1111/jvim.13927]

6. Zuraw, A.; Dietert, K.; Kuhnel, S.; Sander, J.; Klopfleisch, R. Equine atypical myopathy caused by hypoglycin A intoxication associated with ingestion of sycamore maple tree seeds. Equine Vet. J.; 2016; 48, pp. 418-421. [DOI: https://dx.doi.org/10.1111/evj.12460]

7. Renaud, B.; Kruse, C.J.; François, A.C.; Grund, L.; Bunert, C.; Brisson, L.; Boemer, F.; Gault, G.; Ghislain, B.; Petitjean, T. et al. Acer pseudoplatanus: A Potential Risk of Poisoning for Several Herbivore Species. Toxins; 2022; 14, 512. [DOI: https://dx.doi.org/10.3390/toxins14080512]

8. Bochnia, M.; Ziemssen, E.; Sander, J.; Stief, B.; Zeyner, A. Methylenecyclopropylglycine and hypoglycin A intoxication in three Pere David’s Deers (Elaphurus davidianus) with atypical myopathy. Vet. Med. Sci.; 2021; 7, pp. 998-1005. [DOI: https://dx.doi.org/10.1002/vms3.406]

9. Hirz, M.; Gregersen, H.A.; Sander, J.; Votion, D.M.; Schanzer, A.; Kohler, K.; Herden, C. Atypical myopathy in 2 Bactrian camels. J. Vet. Diagn. Investig.; 2021; 33, pp. 961-965. [DOI: https://dx.doi.org/10.1177/10406387211020721]

10. Bunert, C.; Langer, S.; Votion, D.M.; Boemer, F.; Muller, A.; Ternes, K.; Liesegang, A. Atypical myopathy in Pere David’s deer (Elaphurus davidianus) associated with ingestion of hypoglycin A. J. Anim. Sci.; 2018; 96, pp. 3537-3547. [DOI: https://dx.doi.org/10.1093/jas/sky200]

11. John, T.; Das, M. Acute encephalitis syndrome in children in Muzaffarpur: Hypothesis of toxic origin. Curr. Sci.; 2014; 106, pp. 1184-1185.

12. Joskow, R.; Belson, M.; Vesper, H.; Backer, L.; Rubin, C. Ackee fruit poisoning: An outbreak investigation in Haiti 2000–2001, and review of the literature. Clin. Toxicol.; 2006; 44, pp. 267-273. [DOI: https://dx.doi.org/10.1080/15563650600584410]

13. Shah, A.B.; John, T.J. Recurrent Outbreaks of Hypoglycaemic Encephalopathy in Muzaffarpur, Bihar. Curr. Sci.; 2014; 107, pp. 570-571.

14. Shrivastava, A.; Kumar, A.; Thomas, J.D.; Laserson, K.F.; Bhushan, G.; Carter, M.D.; Chhabra, M.; Mittal, V.; Khare, S.; Sejvar, J.J. et al. Association of acute toxic encephalopathy with litchi consumption in an outbreak in Muzaffarpur, India, 2014: A case-control study. Lancet Glob. Health; 2017; 5, pp. e458-e466. [DOI: https://dx.doi.org/10.1016/S2214-109X(17)30035-9]

15. Fowden, L.; Pratt, H.M. Cyclopropylamino acids of the genus Acer: Distribution and biosynthesis. Phytochemistry; 1973; 12, pp. 1677-1681. [DOI: https://dx.doi.org/10.1016/0031-9422(73)80387-5]

16. Melde, K.; Buettner, H.; Boschert, W.; Wolf, H.P.; Ghisla, S. Mechanism of hypoglycaemic action of methylenecyclopropylglycine. Biochem. J.; 1989; 259, pp. 921-924. [DOI: https://dx.doi.org/10.1042/bj2590921]

17. Melde, K.; Jackson, S.; Bartlett, K.; Sherratt, H.S.; Ghisla, S. Metabolic consequences of methylenecyclopropylglycine poisoning in rats. Biochem. J.; 1991; 274, Pt 2, pp. 395-400. [DOI: https://dx.doi.org/10.1042/bj2740395]

18. Ghisla, S.; Melde, K.; Zeller, H.D.; Boschert, W. Mechanisms of enzyme inhibition by hypoglycin, methylenecyclopropylglycine and their metabolites. Prog. Clin. Biol. Res.; 1990; 321, pp. 185-192.

19. Osmundsen, H.; Sherratt, H.S. A novel mechanism for inhibition of beta-oxidation by methylenecyclopropylacetyl-CoA, a metabolite of hypoglycin. FEBS Lett.; 1975; 55, pp. 38-41. [DOI: https://dx.doi.org/10.1016/0014-5793(75)80951-3]

20. Adeva-Andany, M.M.; López-Maside, L.; Donapetry-García, C.; Fernández-Fernández, C.; Sixto-Leal, C. Enzymes involved in branched-chain amino acid metabolism in humans. Amino Acids; 2017; 49, pp. 1005-1028. [DOI: https://dx.doi.org/10.1007/s00726-017-2412-7]

21. Holeček, M. Branched-chain amino acids in health and disease: Metabolism, alterations in blood plasma, and as supplements. Nutr. Metab.; 2018; 15, 33. [DOI: https://dx.doi.org/10.1186/s12986-018-0271-1]

22. Mann, G.; Mora, S.; Madu, G.; Adegoke, O.A.J. Branched-chain Amino Acids: Catabolism in Skeletal Muscle and Implications for Muscle and Whole-body Metabolism. Front. Physiol.; 2021; 12, 702826. [DOI: https://dx.doi.org/10.3389/fphys.2021.702826]

23. Brandt, K.; Hinrichs, U.; Glitz, F.; Landes, E.; Schulze, C.; Deegen, E.; Pohlenz, J.; Coenen, M. Atypische Myoglobinurie der Weidepferde. Pferdeheilkunde; 1997; 13, pp. 27-34. [DOI: https://dx.doi.org/10.21836/PEM19970104]

24. Votion, D.-M.; Linden, A.; Saegerman, C.; Engels, P.; Erpicum, M.; Thiry, E.; Delguste, C.; Rouxhet, S.; Demoulin, V.; Navet, R. et al. History and clinical features of atypical myopathy in horses in Belgium (2000–2005). J. Vet. Intern. Med.; 2007; 21, pp. 1380-1391. [DOI: https://dx.doi.org/10.1892/07-053.1]

25. Fabius, L.S.; Westermann, C.M. Evidence-based therapy for atypical myopathy in horses. Equine Vet. Educ.; 2018; 30, pp. 616-622. [DOI: https://dx.doi.org/10.1111/eve.12734]

26. Boemer, F.; Detilleux, J.; Cello, C.; Amory, H.; Marcillaud-Pitel, C.; Richard, E.; van Galen, G.; van Loon, G.; Lefere, L.; Votion, D.M. Acylcarnitines profile best predicts survival in horses with atypical myopathy. PLoS ONE; 2017; 12, e0182761. [DOI: https://dx.doi.org/10.1371/journal.pone.0182761]

27. Cassart, D.; Baise, E.; Cherel, Y.; Delguste, C.; Antoine, N.; Votion, D.; Amory, H.; Rollin, F.; Linden, A.; Coignoul, F. et al. Morphological alterations in oxidative muscles and mitochondrial structure associated with equine atypical myopathy. Equine Vet. J.; 2007; 39, pp. 26-32. [DOI: https://dx.doi.org/10.2746/042516407X157765]

28. Palencia, P.; Rivero, J.L. Atypical myopathy in two grazing horses in northern Spain. Vet. Rec.; 2007; 161, pp. 346-348. [DOI: https://dx.doi.org/10.1136/vr.161.10.346]

29. Westermann, C.M.; de Sain-van der Velden, M.G.; van der Kolk, J.H.; Berger, R.; Wijnberg, I.D.; Koeman, J.P.; Wanders, R.J.; Lenstra, J.A.; Testerink, N.; Vaandrager, A.B. et al. Equine biochemical multiple acyl-CoA dehydrogenase deficiency (MADD) as a cause of rhabdomyolysis. Mol. Genet. Metab.; 2007; 91, pp. 362-369. [DOI: https://dx.doi.org/10.1016/j.ymgme.2007.04.010]

30. Verheyen, T.; Decloedt, A.; De Clercq, D.; van Loon, G. Cardiac changes in horses with atypical myopathy. J. Vet. Intern. Med.; 2012; 26, pp. 1019-1026. [DOI: https://dx.doi.org/10.1111/j.1939-1676.2012.00945.x]

31. Jackson, R.H.; Singer, T.P. Inactivation of the 2-ketoglutarate and pyruvate dehydrogenase complexes of beef heart by branched chain keto acids. J. Biol. Chem.; 1983; 258, pp. 1857-1865. [DOI: https://dx.doi.org/10.1016/S0021-9258(18)33067-9]

32. Entman, M.; Bressler, R. The mechanism of action of hypoglycin on long-chain fatty acid oxidation. Mol. Pharmacol.; 1967; 3, pp. 333-340.

33. Brooks, S.E.; Audretsch, J.J. Studies on hypoglycin toxicity in rats. I. Changes in hepatic ultrastructure. Am. J. Pathol.; 1970; 59, pp. 161-180.

34. van Galen, G.; Marcillaud Pitel, C.; Saegerman, C.; Patarin, F.; Amory, H.; Baily, J.D.; Cassart, D.; Gerber, V.; Hahn, C.; Harris, P. et al. European outbreaks of atypical myopathy in grazing equids (2006–2009): Spatiotemporal distribution, history and clinical features. Equine Vet. J.; 2012; 44, pp. 614-620. [DOI: https://dx.doi.org/10.1111/j.2042-3306.2012.00556.x]

35. Gonzalez-Medina, S.; Ireland, J.L.; Piercy, R.J.; Newton, J.R.; Votion, D.M. Equine Atypical Myopathy in the UK: Epidemiological characteristics of cases reported from 2011 to 2015 and factors associated with survival. Equine Vet. J.; 2017; 49, pp. 746-752. [DOI: https://dx.doi.org/10.1111/evj.12694]

36. Wimmer-Scherr, C.; Taminiau, B.; Renaud, B.; van Loon, G.; Palmers, K.; Votion, D.; Amory, H.; Daube, G.; Cesarini, C. Comparison of Fecal Microbiota of Horses Suffering from Atypical Myopathy and Healthy Co-Grazers. Animals; 2021; 11, 506. [DOI: https://dx.doi.org/10.3390/ani11020506]

37. van Galen, G.; Saegerman, C.; Marcillaud Pitel, C.; Patarin, F.; Amory, H.; Baily, J.D.; Cassart, D.; Gerber, V.; Hahn, C.; Harris, P. et al. European outbreaks of atypical myopathy in grazing horses (2006-2009): Determination of indicators for risk and prognostic factors. Equine Vet. J.; 2012; 44, pp. 621-625. [DOI: https://dx.doi.org/10.1111/j.2042-3306.2012.00555.x]

38. Sander, J.; Cavalleri, J.M.; Terhardt, M.; Bochnia, M.; Zeyner, A.; Zuraw, A.; Sander, S.; Peter, M.; Janzen, N. Rapid diagnosis of hypoglycin A intoxication in atypical myopathy of horses. J. Vet. Diagn. Investig.; 2016; 28, pp. 98-104. [DOI: https://dx.doi.org/10.1177/1040638715624736]

39. Sander, J.; Terhardt, M.; Sander, S.; Aboling, S.; Janzen, N. A new method for quantifying causative and diagnostic markers of methylenecyclopropylglycine poisoning. Toxicol. Rep.; 2019; 6, pp. 803-808. [DOI: https://dx.doi.org/10.1016/j.toxrep.2019.08.002]

40. Sander, J.; Terhardt, M.; Sander, S.; Janzen, N. Quantification of Methylenecyclopropyl Compounds and Acyl Conjugates by UPLC-MS/MS in the Study of the Biochemical Effects of the Ingestion of Canned Ackee (Blighia sapida) and Lychee (Litchi chinensis). J. Agric. Food Chem.; 2017; 65, pp. 2603-2608. [DOI: https://dx.doi.org/10.1021/acs.jafc.7b00224]

41. Sander, J.; Terhardt, M.; Janzen, N. Study on the Metabolic Effects of Repeated Consumption of Canned Ackee. J. Agric. Food Chem.; 2020; 68, pp. 14603-14609. [DOI: https://dx.doi.org/10.1021/acs.jafc.0c06235]

42. El-Khatib, A.H.; Engel, A.M.; Weigel, S. Co-Occurrence of Hypoglycin A and Hypoglycin B in Sycamore and Box Elder Maple Proved by LC-MS/MS and LC-HR-MS. Toxins; 2022; 14, 608. [DOI: https://dx.doi.org/10.3390/toxins14090608]

43. Lieu, Y.K.; Hsu, B.Y.; Price, W.A.; Corkey, B.E.; Stanley, C.A. Carnitine effects on coenzyme A profiles in rat liver with hypoglycin inhibition of multiple dehydrogenases. Am. J. Physiol.; 1997; 272, pp. E359-E366. [DOI: https://dx.doi.org/10.1152/ajpendo.1997.272.3.E359]

44. Gold, J.R.; Grubb, T.L.; Cox, S.; Malavasi, L.; Villarino, N.L. Pharmacokinetics and pharmacodynamics of repeat dosing of gabapentin in adult horses. J. Vet. Intern. Med.; 2022; 36, pp. 792-797. [DOI: https://dx.doi.org/10.1111/jvim.16386]

45. Krageloh, T.; Cavalleri, J.M.V.; Ziegler, J.; Sander, J.; Terhardt, M.; Breves, G.; Cehak, A. Identification of hypoglycin A binding adsorbents as potential preventive measures in co-grazers of atypical myopathy affected horses. Equine Vet. J.; 2018; 50, pp. 220-227. [DOI: https://dx.doi.org/10.1111/evj.12723]