Zuclopenthixol decanoate toxicity

IF 0.8 4区 农林科学 Q3 VETERINARY SCIENCES Equine Veterinary Education Pub Date : 2024-09-11 DOI:10.1111/eve.14045
Janny C. de Grauw, Gemma Pearson
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It is a long-acting dopamine D1 and D2 receptor antagonist, with a duration of action of 3–4 days (acetate ester) up to 2–3 weeks (decanoate) in wild ungulates, depending on the pharmaceutical formulation (Swan, <span>1993</span>; Read, <span>2002</span>).</p><p>Our understanding of equine behaviour and in particular learning theory, has deepened over the past few years. We now recognise that most problematic behaviours can quickly be resolved with appropriate training (McLean &amp; Christensen, <span>2017</span>; Pearson, <span>2019</span>) and this knowledge should markedly reduce the need for psychopharmaceutical use during the routine management of horses. Yet, as this knowledge is still not embedded into mainstream equestrianism, and considering we know most people overestimate their understanding of horse behaviour (Warren-Smith &amp; McGreevy, <span>2008</span>; Wentworth-Stanley, <span>2013</span>; Pearson et al., <span>2020</span>), psychopharmaceuticals remain an attractive option to many. Moreover, some problematic behaviours coincide with marked levels of emotions such as fear, which impairs a horse's ability to learn. By directly reducing fear, judicious psychopharmaceutical use may optimise retraining, improve welfare and maximise safety.</p><p>When it comes to pharmacological behavioural modification in horses, there is an intricate ethical balance between safely promoting equine welfare during stressful events versus the inherent risks of abuse. Antipsychotics like zuclopenthixol are also classified as neuroleptics or major tranquilisers, as they superficially appear to reduce agitation and have a resultant calming effect. This is why this class of drug has a high potential for abuse in equine sports. They have been denoted ‘banned substances’ by the Fédération Equestrian Internationale (FEI) as they are considered to have no legitimate use in equine medicine (FEI equine prohibited substance list, https://inside.fei.org/fei/cleansport/ad-h/prohibited-list), and they are likewise prohibited in horseracing (International Federation of Horseracing Authorities, International Agreement on Breeding, Racing and Wagering, <span>2018</span>). A true anxiolytic reduces fear while allowing the animal to otherwise function normally, however, antipsychotics reduce motor activity and blunt all emotional responsiveness (Cromwell-Davies &amp; Landsberg, <span>2018</span>). As a consequence, they are contra-indicated as a stand-alone treatment in companion animal behavioural medicine where fear or anxiety is suspected (Cromwell-Davies &amp; Landsberg, <span>2018</span>; Pereira et al., <span>2024</span>).</p><p>Zuclopenthixol first gained attention as a potential drug of abuse in equestrian sports when the gold medal showjumping horse Waterford Crystal tested positive for the drug after the 2004 Olympics in Rome, with samples sent to the official doping laboratory testing positive for both fluphenazine (a closely related antipsychotic drug) and zuclopenthixol. With antipsychotic use on the rise in humans globally, comprehensive assays based on LC/tandem MS have been developed for forensic and toxicology screening as well as for doping detection in equine samples (Wong et al., <span>2020</span>).</p><p>It is known that through exposure and availability, racetrack workers and equestrian trainers are at increased risk of diversion and toxicity from self-ingestion of drugs (mis)used in equestrian sports (Newton &amp; Rose, <span>1991</span>; Sawalha et al., <span>2021</span>). It is a less common occurrence perhaps for horses to be dosed with drugs acquired for human medical conditions, but the case reported here highlights that we must be vigilant of this possibility whenever a horse presents with unexplained behavioural signs, be it excitatory or aggressive behaviour, or excessive somnolence.</p><p>Zuclopenthixol toxicity in the horse has, to the authors' knowledge, not previously been described, although recent studies were undertaken in Sweden to elucidate dynamics of zuclopenthixol acetate (a shorter acting zuclopenthixol, 1–3 days) in <i>n</i> = 4 healthy warmblood trotters. Two of the four horses in this study showed side effects at doses of 0.25, 0.5 and 1 mg/kg bwt and comprised extrapyramidal symptoms, muscle fasciculations, inappetence, aggressive behaviour, tachycardia, colic and submandibular oedema (Ödmark, <span>2016</span>). These signs are very similar to those described by the authors of the case report in this edition of EVE. The dopaminergic system in horses and other ungulates is prominent and dopamine's involvement as a neuromediator in the basal ganglia is responsible for its complex effects on locomotor function, flight response, impulse control and mood.</p><p>Dopamine plays a key role in motivational salience, with increases signalling pleasure and satisfaction and reductions signalling fear or aversive stimuli (Wenzel et al., <span>2015</span>). It is therefore fundamental in learning; dopamine release is upregulated through either positive reinforcement (increasing a behaviour through reward) or negative reinforcement (increasing behaviour through release of pressure)—in contrast, tonic dopamine release dips in response to punishment (suppressing a behavioural response) (McBride et al., <span>2017</span>). When initially training a new response using negative reinforcement, an aversive stimulus (e.g. pulling on the reins) results in a dip in tonic dopamine release, this motivates the horse to try new behaviours to resolve the aversive stimulus. When the horse trials slowing down, the rider should release the pressure to reinforce the desired behaviour and this results in a dopamine surge. Over time, as learning occurs, the horse slows from light (non-aversive) pressure on the reins and this results in a dopamine spike without an initial reduction. This example demonstrates the importance to the animal of maintaining tonic baseline levels of dopamine activity, since when these dip, the animal is highly motivated to alter its behaviour to restore them. At the same time, they are also motivated to repeat behaviours that result in a dopamine surge, as this makes them feel good. Moreover, chronic dopamine depletion such as occurs with Parkinson's or PPID is associated with low mood states and behavioural depression. The intricate relationship between dopamine and how an animal might feel should be carefully considered when using dopamine antagonists.</p><p>Antipsychotics act as dopaminergic antagonists and, as discussed by Addis and Savage (<span>2024</span>), clearly have beneficial effects when used in wild animals to facilitate stressful events and where the risk of physical harm is high. Nonetheless, the reductions in stress as measured by cortisol may actually be secondary to a reduced flight response through inhibited motor activity rather than by actually promoting calmness. In companion animal behavioural medicine, it is accepted that dopamine antagonists have no anxiolytic properties, and instead block or attenuate motor responses without altering the sensory experience for the individual animal. As such, the animal may still experience fear but be less able to move away from it; as a consequence, they may become more fearful overtime. These drugs are therefore contraindicated for phobic states (Pereira et al., <span>2024</span>). At the same time, they are recommended where the flight response is so intense it is likely to result in harm, and/or when combined with an anxiolytic (Cromwell-Davies &amp; Landsberg, <span>2018</span>). Horses are a domesticated species but have maintained a strong flight response. As a species, they can be considered to sit between wild ungulates and domesticated companion animals—so is there any justification for using antipsychotics in horses?</p><p>While the authors have no experience of zuclopenthixol decanoate or fluphenazine decanoate, all equine veterinarians will be familiar with the antipsychotic acepromazine, which has for a long time been used to manage horses in need of tranquilisation. Its use in equine anaesthesia, as part of premedication for general anaesthesia or to augment standing sedation (both combined with alpha-2 agonists and opioids) is commonplace, and in such protocols, it can help reduce excitability and smoothen recovery. For behavioural management, as a dopamine antagonist, acepromazine alone has no appreciable anxiolytic properties and it likely has a negative (depressive) impact on mood. Be that as it may, the reduction in spontaneous motor activity may provide safety benefits when used in horses that may otherwise injure themselves. Ideally, when horses are excessively fearful or anxious, an anxiolytic should be used in the first instance (e.g. trazodone, alprazolam or fluoxetine for longer-term use), and both authors have seen increased efficacy when acepromazine is combined with an anxiolytic. However, under some circumstances, such as horses competing under FEI rules, these agents are banned so cannot be used, and acepromazine may be the only option to keep a horse (and its handlers) safe.</p><p>The use of behaviour modifying drugs/psychopharmaceuticals can be well justified in individual cases of equine problematic behaviour, and/or horses subjected to highly stressful (medical) interventions, and it would be detrimental to consider any behavioural modifying drug to have no place in equine practice—in fact, many sedatives and anaesthetic agents can impact how an animal feels and are behaviour modifying. While such drugs have no place in competition or performance enhancement, it is the authors' personal experience and opinion that for individual horses showing problematic behaviours, a psychopharmaceutical, ideally alongside a behaviour modification programme, is beneficial and underutilised. As a result, fractious, fearful or frustrated horses needing to undergo veterinary procedures are more likely to be darted or tele immobilised and/or receive high dosages of alpha-2 agonists, (strong) opioids or ketamine, with higher risk of complications following sedation and anaesthesia. Prudent pretreatment with anxiolytics such as alprazolam or trazodone can be justified on an individual case-by-case basis and can greatly enhance welfare and safety of chemical restraint in extremely difficult horses. Be that as it may, it is difficult to justify their use for routine handling, especially as most procedures can be trained with minimal stress to the horse if using learning theory and modifying the training according to current emotional state.</p><p>Racing, and equestrianism generally, is already under pressure to maintain its social licence to operate, and a key component is transparency (Pearson et al., <span>2023</span>). It is difficult to maintain that weaning, handling during sales preparation and the sales themselves are not stressful for horses, when the use of antipsychotic drugs, such as acepromazine, is commonplace. How would the general public feel about this? Equine vets are well positioned to advise on the judicious use of psychopharmaceuticals where indicated for an individual case, and potentially also to support trainers in making changes to their management, increasing their knowledge of equine behaviour or seeking help from a clinical animal behaviourist as required (Doherty et al., <span>2017</span>; Pearson, <span>2019</span>; Wolframm et al., <span>2023</span>). Ultimately, welfare represents how an animal feels, and so we have a responsibility to maximise positive emotional states and minimise negative ones.</p><p><b>Janny C. de Grauw:</b> Conceptualization; data curation; writing – original draft. <b>Gemma Pearson:</b> Conceptualization; data curation; writing – original draft.</p><p>None.</p><p>No conflicts of interest have been declared.</p><p>Not applicable to this clinical commentary.</p>","PeriodicalId":11786,"journal":{"name":"Equine Veterinary Education","volume":"36 12","pages":"625-627"},"PeriodicalIF":0.8000,"publicationDate":"2024-09-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/eve.14045","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Equine Veterinary Education","FirstCategoryId":"97","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/eve.14045","RegionNum":4,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"VETERINARY SCIENCES","Score":null,"Total":0}
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Abstract

A psychopharmaceutical describes a drug that has an impact on the mental state of the user. These medications are often used preventively to modify the behavioural response to stress in ungulate prey species, for example, to facilitate transportation and/or introduction into a new area, group or herd. Zuclopenthixol is a long-acting neuroleptic (LAN) or antipsychotic agent that has been used to facilitate wildlife translocation in conservation projects. In human medicine, this drug is used to treat psychiatric disorders including schizophrenia and psychosis. It is a long-acting dopamine D1 and D2 receptor antagonist, with a duration of action of 3–4 days (acetate ester) up to 2–3 weeks (decanoate) in wild ungulates, depending on the pharmaceutical formulation (Swan, 1993; Read, 2002).

Our understanding of equine behaviour and in particular learning theory, has deepened over the past few years. We now recognise that most problematic behaviours can quickly be resolved with appropriate training (McLean & Christensen, 2017; Pearson, 2019) and this knowledge should markedly reduce the need for psychopharmaceutical use during the routine management of horses. Yet, as this knowledge is still not embedded into mainstream equestrianism, and considering we know most people overestimate their understanding of horse behaviour (Warren-Smith & McGreevy, 2008; Wentworth-Stanley, 2013; Pearson et al., 2020), psychopharmaceuticals remain an attractive option to many. Moreover, some problematic behaviours coincide with marked levels of emotions such as fear, which impairs a horse's ability to learn. By directly reducing fear, judicious psychopharmaceutical use may optimise retraining, improve welfare and maximise safety.

When it comes to pharmacological behavioural modification in horses, there is an intricate ethical balance between safely promoting equine welfare during stressful events versus the inherent risks of abuse. Antipsychotics like zuclopenthixol are also classified as neuroleptics or major tranquilisers, as they superficially appear to reduce agitation and have a resultant calming effect. This is why this class of drug has a high potential for abuse in equine sports. They have been denoted ‘banned substances’ by the Fédération Equestrian Internationale (FEI) as they are considered to have no legitimate use in equine medicine (FEI equine prohibited substance list, https://inside.fei.org/fei/cleansport/ad-h/prohibited-list), and they are likewise prohibited in horseracing (International Federation of Horseracing Authorities, International Agreement on Breeding, Racing and Wagering, 2018). A true anxiolytic reduces fear while allowing the animal to otherwise function normally, however, antipsychotics reduce motor activity and blunt all emotional responsiveness (Cromwell-Davies & Landsberg, 2018). As a consequence, they are contra-indicated as a stand-alone treatment in companion animal behavioural medicine where fear or anxiety is suspected (Cromwell-Davies & Landsberg, 2018; Pereira et al., 2024).

Zuclopenthixol first gained attention as a potential drug of abuse in equestrian sports when the gold medal showjumping horse Waterford Crystal tested positive for the drug after the 2004 Olympics in Rome, with samples sent to the official doping laboratory testing positive for both fluphenazine (a closely related antipsychotic drug) and zuclopenthixol. With antipsychotic use on the rise in humans globally, comprehensive assays based on LC/tandem MS have been developed for forensic and toxicology screening as well as for doping detection in equine samples (Wong et al., 2020).

It is known that through exposure and availability, racetrack workers and equestrian trainers are at increased risk of diversion and toxicity from self-ingestion of drugs (mis)used in equestrian sports (Newton & Rose, 1991; Sawalha et al., 2021). It is a less common occurrence perhaps for horses to be dosed with drugs acquired for human medical conditions, but the case reported here highlights that we must be vigilant of this possibility whenever a horse presents with unexplained behavioural signs, be it excitatory or aggressive behaviour, or excessive somnolence.

Zuclopenthixol toxicity in the horse has, to the authors' knowledge, not previously been described, although recent studies were undertaken in Sweden to elucidate dynamics of zuclopenthixol acetate (a shorter acting zuclopenthixol, 1–3 days) in n = 4 healthy warmblood trotters. Two of the four horses in this study showed side effects at doses of 0.25, 0.5 and 1 mg/kg bwt and comprised extrapyramidal symptoms, muscle fasciculations, inappetence, aggressive behaviour, tachycardia, colic and submandibular oedema (Ödmark, 2016). These signs are very similar to those described by the authors of the case report in this edition of EVE. The dopaminergic system in horses and other ungulates is prominent and dopamine's involvement as a neuromediator in the basal ganglia is responsible for its complex effects on locomotor function, flight response, impulse control and mood.

Dopamine plays a key role in motivational salience, with increases signalling pleasure and satisfaction and reductions signalling fear or aversive stimuli (Wenzel et al., 2015). It is therefore fundamental in learning; dopamine release is upregulated through either positive reinforcement (increasing a behaviour through reward) or negative reinforcement (increasing behaviour through release of pressure)—in contrast, tonic dopamine release dips in response to punishment (suppressing a behavioural response) (McBride et al., 2017). When initially training a new response using negative reinforcement, an aversive stimulus (e.g. pulling on the reins) results in a dip in tonic dopamine release, this motivates the horse to try new behaviours to resolve the aversive stimulus. When the horse trials slowing down, the rider should release the pressure to reinforce the desired behaviour and this results in a dopamine surge. Over time, as learning occurs, the horse slows from light (non-aversive) pressure on the reins and this results in a dopamine spike without an initial reduction. This example demonstrates the importance to the animal of maintaining tonic baseline levels of dopamine activity, since when these dip, the animal is highly motivated to alter its behaviour to restore them. At the same time, they are also motivated to repeat behaviours that result in a dopamine surge, as this makes them feel good. Moreover, chronic dopamine depletion such as occurs with Parkinson's or PPID is associated with low mood states and behavioural depression. The intricate relationship between dopamine and how an animal might feel should be carefully considered when using dopamine antagonists.

Antipsychotics act as dopaminergic antagonists and, as discussed by Addis and Savage (2024), clearly have beneficial effects when used in wild animals to facilitate stressful events and where the risk of physical harm is high. Nonetheless, the reductions in stress as measured by cortisol may actually be secondary to a reduced flight response through inhibited motor activity rather than by actually promoting calmness. In companion animal behavioural medicine, it is accepted that dopamine antagonists have no anxiolytic properties, and instead block or attenuate motor responses without altering the sensory experience for the individual animal. As such, the animal may still experience fear but be less able to move away from it; as a consequence, they may become more fearful overtime. These drugs are therefore contraindicated for phobic states (Pereira et al., 2024). At the same time, they are recommended where the flight response is so intense it is likely to result in harm, and/or when combined with an anxiolytic (Cromwell-Davies & Landsberg, 2018). Horses are a domesticated species but have maintained a strong flight response. As a species, they can be considered to sit between wild ungulates and domesticated companion animals—so is there any justification for using antipsychotics in horses?

While the authors have no experience of zuclopenthixol decanoate or fluphenazine decanoate, all equine veterinarians will be familiar with the antipsychotic acepromazine, which has for a long time been used to manage horses in need of tranquilisation. Its use in equine anaesthesia, as part of premedication for general anaesthesia or to augment standing sedation (both combined with alpha-2 agonists and opioids) is commonplace, and in such protocols, it can help reduce excitability and smoothen recovery. For behavioural management, as a dopamine antagonist, acepromazine alone has no appreciable anxiolytic properties and it likely has a negative (depressive) impact on mood. Be that as it may, the reduction in spontaneous motor activity may provide safety benefits when used in horses that may otherwise injure themselves. Ideally, when horses are excessively fearful or anxious, an anxiolytic should be used in the first instance (e.g. trazodone, alprazolam or fluoxetine for longer-term use), and both authors have seen increased efficacy when acepromazine is combined with an anxiolytic. However, under some circumstances, such as horses competing under FEI rules, these agents are banned so cannot be used, and acepromazine may be the only option to keep a horse (and its handlers) safe.

The use of behaviour modifying drugs/psychopharmaceuticals can be well justified in individual cases of equine problematic behaviour, and/or horses subjected to highly stressful (medical) interventions, and it would be detrimental to consider any behavioural modifying drug to have no place in equine practice—in fact, many sedatives and anaesthetic agents can impact how an animal feels and are behaviour modifying. While such drugs have no place in competition or performance enhancement, it is the authors' personal experience and opinion that for individual horses showing problematic behaviours, a psychopharmaceutical, ideally alongside a behaviour modification programme, is beneficial and underutilised. As a result, fractious, fearful or frustrated horses needing to undergo veterinary procedures are more likely to be darted or tele immobilised and/or receive high dosages of alpha-2 agonists, (strong) opioids or ketamine, with higher risk of complications following sedation and anaesthesia. Prudent pretreatment with anxiolytics such as alprazolam or trazodone can be justified on an individual case-by-case basis and can greatly enhance welfare and safety of chemical restraint in extremely difficult horses. Be that as it may, it is difficult to justify their use for routine handling, especially as most procedures can be trained with minimal stress to the horse if using learning theory and modifying the training according to current emotional state.

Racing, and equestrianism generally, is already under pressure to maintain its social licence to operate, and a key component is transparency (Pearson et al., 2023). It is difficult to maintain that weaning, handling during sales preparation and the sales themselves are not stressful for horses, when the use of antipsychotic drugs, such as acepromazine, is commonplace. How would the general public feel about this? Equine vets are well positioned to advise on the judicious use of psychopharmaceuticals where indicated for an individual case, and potentially also to support trainers in making changes to their management, increasing their knowledge of equine behaviour or seeking help from a clinical animal behaviourist as required (Doherty et al., 2017; Pearson, 2019; Wolframm et al., 2023). Ultimately, welfare represents how an animal feels, and so we have a responsibility to maximise positive emotional states and minimise negative ones.

Janny C. de Grauw: Conceptualization; data curation; writing – original draft. Gemma Pearson: Conceptualization; data curation; writing – original draft.

None.

No conflicts of interest have been declared.

Not applicable to this clinical commentary.

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癸酸祖氯倍他索的毒性
精神药物是指对使用者的精神状态有影响的药物。这些药物通常用于预防性地改变麋鹿猎物对压力的行为反应,例如,便于运输和/或引入新的地区、群体或兽群。左旋倍他索(Zuclopenthixol)是一种长效神经安定剂(LAN)或抗精神病药,已被用于促进保护项目中的野生动物迁移。在人类医学中,这种药物用于治疗精神疾病,包括精神分裂症和精神病。它是一种长效多巴胺 D1 和 D2 受体拮抗剂,对野生蹄类动物的作用时间为 3-4 天(醋酸酯)至 2-3 周(癸酸酯),具体取决于药物配方(Swan,1993 年;Read,2002 年)。我们现在认识到,大多数有问题的行为都可以通过适当的训练迅速解决(McLean &amp; Christensen, 2017; Pearson, 2019),这些知识应能显著减少马匹日常管理中对精神药物的使用需求。然而,由于这些知识仍未融入主流马术运动,考虑到我们知道大多数人都高估了自己对马匹行为的理解(Warren-Smith &amp; McGreevy, 2008; Wentworth-Stanley, 2013; Pearson et al.此外,一些有问题的行为与明显的情绪水平相吻合,如恐惧,这会损害马匹的学习能力。通过直接减少恐惧,明智地使用精神药物可以优化再训练、改善马匹福利并最大限度地提高安全性。在对马匹进行药物行为矫正时,在应激事件中安全地促进马匹福利与滥用药物的固有风险之间存在着错综复杂的伦理平衡。抗精神病药物如左旋倍他索也被归类为神经安定剂或主要镇静剂,因为它们表面上看起来能减少马匹的躁动,从而起到镇静作用。因此,这类药物在马术运动中被滥用的可能性很大。它们被国际马术联合会(FEI)列为 "禁用物质",因为它们被认为在马术医学中没有合法用途(FEI 马术禁用物质清单,https://inside.fei.org/fei/cleansport/ad-h/prohibited-list),在赛马中也同样被禁止使用(国际赛马管理机构联合会,《国际育种、赛马和博彩协议》,2018 年)。真正的抗焦虑药能减轻动物的恐惧感,同时让动物在其他方面发挥正常功能,然而,抗精神病药会减少运动活动,并削弱所有情绪反应能力(Cromwell-Davies &amp; Landsberg, 2018)。因此,在怀疑存在恐惧或焦虑的伴侣动物行为医学中,抗精神病药物不宜作为单独的治疗手段(Cromwell-Davies &amp; Landsberg, 2018; Pereira et al、2004年罗马奥运会后,马术障碍赛金牌马沃特福德-水晶(Waterford Crystal)的药物检测呈阳性,送往官方兴奋剂实验室的样本检测结果显示氟奋乃静(一种密切相关的抗精神病药物)和左旋倍他索(zuclopenthixol)均呈阳性,因此左旋倍他索作为马术运动中的一种潜在滥用药物首次引起了人们的注意。随着抗精神病药物在人类中的使用在全球范围内不断增加,基于液相色谱/串联质谱的综合检测方法已被开发出来,用于法医和毒理学筛查以及马匹样本中的兴奋剂检测(Wong 等人,2020 年)。众所周知,通过接触和供应,赛马场工作人员和马术驯马师因自我摄入马术运动中(误)使用的药物而被转移和中毒的风险增加(Newton &amp; Rose, 1991; Sawalha 等人,2021 年)。马匹服用为治疗人类疾病而获得的药物的情况可能不太常见,但此处报告的病例突出表明,每当马匹出现无法解释的行为症状时,无论是兴奋或攻击行为,还是过度嗜睡,我们都必须警惕这种可能性。据作者所知,尽管瑞典最近开展了一项研究,以阐明醋酸唑仑苯噻醇(一种作用时间较短的唑仑苯噻醇,1-3 天)在 n = 4 匹健康的温血马中的动态变化,但此前从未描述过马的唑仑苯噻醇毒性。在这项研究中,四匹马中有两匹在剂量为 0.25、0.5 和 1 毫克/千克体重时出现了副作用,包括锥体外系症状、肌肉痉挛、食欲不振、攻击行为、心动过速、腹绞痛和颌下水肿(Ödmark,2016 年)。这些症状与本期《EVE》中病例报告的作者所描述的症状非常相似。 马和其他有蹄类动物的多巴胺能系统非常突出,多巴胺作为神经介质参与基底神经节,对运动功能、飞行反应、冲动控制和情绪产生了复杂的影响。多巴胺在动机显著性方面起着关键作用,其增加表示快乐和满足,减少表示恐惧或厌恶刺激(Wenzel等人,2015年)。因此,多巴胺是学习的基础;多巴胺的释放会通过正强化(通过奖励增加行为)或负强化(通过释放压力增加行为)而得到提升,相反,强直性多巴胺的释放会因惩罚(抑制行为反应)而下降(McBride 等人,2017 年)。在最初使用负强化训练新反应时,厌恶性刺激(如拉缰绳)会导致强直性多巴胺释放下降,从而促使马匹尝试新的行为来解决厌恶性刺激。当马匹尝试放慢速度时,骑手应释放压力以强化所需的行为,这将导致多巴胺激增。随着时间的推移,随着学习的发生,马匹会从缰绳上轻微(非厌恶性)的压力中减速,这将导致多巴胺激增,而不会出现最初的减少。这个例子说明,维持多巴胺活动的强直性基线水平对动物来说非常重要,因为当多巴胺活动水平下降时,动物就会有很大的动力去改变自己的行为,以恢复多巴胺活动水平。与此同时,它们也有动力重复那些会导致多巴胺激增的行为,因为这会让它们感觉良好。此外,慢性多巴胺耗竭(如帕金森病或 PPID)与情绪低落和行为抑郁有关。抗精神病药物作为多巴胺能拮抗剂,正如 Addis 和 Savage(2024 年)所讨论的,当用于野生动物以促进应激事件和身体伤害风险较高的情况时,显然会产生有益的影响。不过,通过皮质醇测量的应激反应减少实际上可能是通过抑制运动活动而减少的逃逸反应,而不是真正促进平静。在伴侣动物行为医学中,多巴胺拮抗剂不具有抗焦虑特性,而是在不改变动物个体感官体验的情况下阻断或减弱运动反应,这一点已被接受。因此,动物可能仍会感到恐惧,但摆脱恐惧的能力较弱;结果,它们可能会随着时间的推移而变得更加恐惧。因此,这些药物禁用于恐惧症状态(Pereira et al.)与此同时,如果马匹的逃避反应非常强烈,可能会造成伤害,和/或与抗焦虑药合用时,则建议使用此类药物(Cromwell-Davies &amp; Landsberg, 2018)。马是被驯化的物种,但一直保持着强烈的飞行反应。作为一个物种,它们可以被认为是介于野生有蹄类动物和驯化的伴侣动物之间的动物,因此是否有理由在马匹身上使用抗精神病药物?虽然作者没有使用癸酸祖氯倍他索或癸酸氟奋乃静的经验,但所有马科兽医都会熟悉抗精神病药物乙丙嗪,长期以来,乙丙嗪一直被用于管理需要镇静的马匹。在马匹麻醉中,阿司丙嗪作为全身麻醉前用药的一部分或加强站立镇静(两者均与α-2受体激动剂和阿片类药物结合使用)的作用已司空见惯,在此类方案中,阿司丙嗪可帮助降低兴奋性并促进恢复。在行为管理方面,作为一种多巴胺拮抗剂,乙酰丙嗪本身没有明显的抗焦虑作用,而且很可能会对情绪产生负面(抑郁)影响。尽管如此,减少马匹的自发运动活动可能会给马匹带来安全方面的好处,否则马匹可能会自残。理想情况下,当马匹过度恐惧或焦虑时,应首先使用抗焦虑药(如曲唑酮、阿普唑仑或长期使用的氟西汀)。不过,在某些情况下,例如按照国际马联规则参赛的马匹,这些药物是禁用的,因此不能使用,乙酰丙嗪可能是保证马匹(及其饲养者)安全的唯一选择。在马匹出现问题行为和/或马匹受到高度压力(医疗)干预的个别情况下,使用行为矫正药物/精神药物是非常合理的,如果认为任何行为矫正药物在马术实践中都没有用武之地,那将是有害的--事实上,许多镇静剂和麻醉剂都会影响动物的感觉,并具有行为矫正作用。 虽然这类药物在比赛或提高成绩方面没有用武之地,但作者个人的经验和观点是,对于表现出问题行为的马匹,精神药物最好与行为矫正计划一起使用,这对马匹是有益的,但未得到充分利用。因此,需要接受兽医手术的性格暴躁、恐惧或沮丧的马匹更有可能被注射飞镖或远程固定和/或接受大剂量的α-2受体激动剂、(强效)阿片类药物或氯胺酮,镇静和麻醉后出现并发症的风险也更高。谨慎地使用抗焦虑药(如阿普唑仑或曲唑酮)进行预处理是有道理的,可根据具体情况而定,可大大提高极度困难马匹的福利和化学约束的安全性。尽管如此,很难证明在常规处理中使用这些药物是合理的,特别是如果使用学习理论并根据当前的情绪状态修改训练方法,大多数程序都可以在对马匹造成最小压力的情况下完成。赛马和马术运动已经面临着维持其社会经营许可的压力,其中一个关键因素就是透明度(Pearson 等人,2023 年)。当使用抗精神病药物(如醋丙咪嗪)司空见惯时,很难说断奶、销售准备期间的处理以及销售本身不会对马造成压力。公众对此会作何感想?马匹兽医完全有能力在个别情况下就精神药物的合理使用提供建议,并有可能支持驯马师改变管理方式,增加他们对马匹行为的了解,或在必要时寻求临床动物行为学家的帮助(Doherty 等人,2017 年;Pearson,2019 年;Wolframm 等人,2023 年)。归根结底,福利代表了动物的感受,因此我们有责任最大限度地改善动物的积极情绪状态,最大限度地减少动物的消极情绪状态:构思;数据整理;写作--原稿。杰玛-皮尔森无利益冲突,不适用于本临床评论。
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来源期刊
Equine Veterinary Education
Equine Veterinary Education 农林科学-兽医学
CiteScore
2.40
自引率
22.20%
发文量
132
审稿时长
18-36 weeks
期刊介绍: Equine Veterinary Education (EVE) is the official journal of post-graduate education of both the British Equine Veterinary Association (BEVA) and the American Association of Equine Practitioners (AAEP). Equine Veterinary Education is a monthly, peer-reviewed, subscription-based journal, integrating clinical research papers, review articles and case reports from international sources, covering all aspects of medicine and surgery relating to equids. These papers facilitate the dissemination and implementation of new ideas and techniques relating to clinical veterinary practice, with the ultimate aim of promoting best practice. New developments are placed in perspective, encompassing new concepts and peer commentary. The target audience is veterinarians primarily engaged in the practise of equine medicine and surgery. The educational value of a submitted article is one of the most important criteria that are assessed when deciding whether to accept it for publication. Articles do not necessarily need to contain original or novel information but we welcome submission of this material. The educational value of an article may relate to articles published with it (e.g. a Case Report may not have direct educational value but an associated Clinical Commentary or Review Article published alongside it will enhance the educational value).
期刊最新文献
Issue Information Peer reviewers in 2024 Highlights of recent clinically relevant papers Issue Information Highlights of recent clinically relevant papers
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