A 19-year-old Cob mare with atrial fibrillation (AF) presented for transvenous electric cardioversion (TVEC). Under general anaesthesia, three successive incremental electric shocks were given (total 750 Joules) and sinus rhythm was temporarily restored. After 13 seconds, AF recurred so a fourth shock (300 Joules) was given and intravenous (IV) amiodarone started. Shortly after, capnography revealed an acute drop in the end-tidal carbon dioxide, which was followed by agonal gasping. Echocardiography showed severe cardiac dysfunction. Successful cardiac resuscitation consisted, amongst others, of cessation of amiodarone, and administration of dobutamine and adrenaline. This case report highlights the importance of capnography as a non-invasive means of cardiac output monitoring in equine anaesthesia which definitely contributed to a positive outcome. It also emphasises the critical importance of early recognition and communication of complications within anaesthetic and cardiology teams.

Caudal cervical spine pathologic lesions are a common cause of pain, lameness, ataxia, poor performance, or any mixture of these clinical signs. Combined radiographic and computed tomography myelography imaging of the caudal cervical spine is imperative when spinal cord compression, nerve root compression, and/or intervertebral disc disease is suspected. Surgical arthrodesis (ventral interbody fusion) of the C7-T1 articulation can be performed successfully and it is important for veterinarians to be aware that treatment at this level is possible.

Septicemia can be a tragic illness in neonatal and young foals. Sick foals may manifest a variety of clinical symptoms all related to a common infection and its systemic effects. While the pathogenesis of this disease is the same as for adult equids, the clinical signs seen can be very different. The rapid changes seen in foal are reflective of their low endogenous reserves of glucose and innate immune mediators as well as the poor ability to self-regulate their metabolism. The neonatal immune system is reliant on maternal antibodies at birth and development of the foal's own system takes a significant amount of time. This non-competent immune system changes how the foal responds to infection when compared to the adult. Clinical signs in septic foals include tachycardia, tachypnea, depression, anorexia, colitis, and fever. Less commonly, foals may show petechiation, swollen joints, anterior uveitis, and coma. This article is the first of a two part series on neonatal sepsis and will present a review on the neonatal immune system, the pathophysiology of sepsis, and the range of clinical signs seen in foals.

not-yet-known not-yet-known not-yet-known unknown Our awareness and understanding of neck conditions in the horse is increasing, along with options for treatment. The ability to perform a thorough and considered orthopaedic and neurologic clinical examination is a vital clinical tool that is accessible to all. Clinical presentations of cervical dysfunction may vary widely in severity and can include one or more components of the three functional diagnoses of; neck pain; neurologic signs of spinal cord compression; and/or signs of radiculopathy. Radiography and ultrasonography are valuable imaging modalities and can be performed in the field, however achieving quality diagnostic radiographs can be challenging in this setting and both have their limitations. Computed tomography (CT) has emerged as the current gold standard imaging modality which offers excellent multiplanar anatomical detail of bony structures and reasonable soft tissue detail, with the risks of anaesthesia being low. Myelography is a key adjunct in the ataxic patient but objective measures for interpretation are not clear. Development of new diagnostic techniques are an active area of research and clinically useful functional testing methods are eagerly awaited to help interpret the clinical relevance of imaging findings.

A 3-year-old Arabian mare was referred for evaluation of swelling beneath the tongue, unilateral facial swelling, mandibular abscess drainage, severe oral cavity wounds, anorexia, and depression. Radiographic imaging revealed a metallic foreign body located near the caudal molars, adjacent to the laryngeal region. Due to significant trauma-induced temporomandibular joint (TMJ) ankylosis and severe limitation in mouth opening, surgical access was extremely challenging. After extensive planning, the mare was anesthetized and after 90 minutes of delicate manipulation, the foreign object, identified as a hypodermic needle embedded within the daily forage, was successfully retrieved. Postoperative wound management and medical therapy led to complete recovery over two weeks. This case emphasizes the importance of considering intraoral foreign bodies in horses presenting with unexplained facial swelling and oral trauma.

A three-year-old Warmblood filly presented with left forelimb lameness of two weeks duration with a discharging sinus over the lateral aspect of the mid-metacarpal region. The filly was diagnosed with a proximal, open, comminuted fracture of metacarpal IV (MCIV). Initial treatment with local debridement and systemic antimicrobial administration was unsuccessful, with the development of osteomyelitis which cultured a methicillin resistant Staphylococcus pseudointermedius. A subsequent segmental ostectomy was performed resulting in avulsion of proximal MCIV from metacarpal III post-operatively. Reduction and internal fixation of the displaced MCIV with cortical lag screws was performed, with immediate bone failure during recovery from general anaesthesia. The proximal MCIV was then removed under standing sedation and local anaesthesia. Subsequent development of osteoarthritis in the carpometacarpal and middle carpal joints was likely secondary to joint instability, but the horse was sound 12 months post-operatively. Despite the surgical complications in this case being previously described, there are no reports on the removal of metacarpal splint bones in the horse to the author’s knowledge. As the prognosis for this case is considered good for future athletic performance, proximal or complete MCIV resection could be considered as a possible treatment option in select cases.

Background: No safety study has been conducted regarding PRP usage in cervical facet joints Objectives: To determine whether intra- and/or peri-articular injections of PRP in cervical facet joints in the horse is safe. Study design: Prospective, multi-centre, safety study Methods: PRP was injected via ultrasound guidance into the cervical and/or cervicothoracic facet joints in horses with diagnosed cervical complaints. Data recorded for each case included: breed, sex, age, primary reason for treatment, list of which facet joints were injected, the volume of PRP injected, whether the PRP was injected intra-articular or peri-articular, gauge of needle used. Data was collected at three time points: prior to treatment, 48 hours after treatment and a minimum of 30 days after treatment. At each time point, owners/trainers were asked to assess the level of pain the horse was suffering on a 0-10 (no pain to worst) scale. At the final evaluation the owners/trainers were also asked if the treatment met their expectations on a 0-5 scale. Results: No adverse events were reported. The average pain scores prior to treatment, at 48 hours, and at 30 days were 3.8, 3.4 and 1.1 respectively (see Figure 2). At no point did any horse have an increase in their reported pain level. Main limitations: Since PRP is not classified as a drug it does not come with a label indicating items such as dosage or route of administration. Thus, methodologies will vary amongst veterinarians. Conclusions: PRP appears to be safe for cervical and/or cervicothoracic facet joint injections in the horse. Evidence for efficacy was also recorded by means of owner/trainer reporting that the injections overwhelmingly met their expectations.

CLINICAL COMMENTARYManagement of parotid gland trauma in horsesJ. F. HawkinsDepartment of Clinical Sciences, College of Veterinary Medicine, North Carolina State University, Raleigh, NC.Correspondence: J.F. HawkinsEmail: jfhawkin@ncsu.eduKEYWORDSHorse, parotid gland, surgery, trauma, fluid accumulation, botulinum toxinThe parotid gland is the largest salivary gland in the horse and is located subcutaneously ventrally from the base of the ear and the wing of the atlas and extending dorsal and ventral to the jugular vein, maxillary vein and linguofacial vein. Rostrally the parotid gland is adjacent to the vertical ramus of the mandible. The parotid gland consists of multiple lobules of yellow to white, glandular tissue. The parotid gland secretes fluid into the oral cavity through the parotid salivary duct. The parotid salivary duct empties into the oral cavity at the level of teeth 308 and 309 or 408 and 409 (Dyce et al, 1987). Because of its subcutaneous location and limited fascial coverage the parotid gland is prone to external trauma. Lacerations in this area can involve the gland and manifest by saliva drainage from the wound. The drainage of saliva increases when the horse eats. In addition, lacerations involving the parotid duct from the angle of the mandible and adjacent to the facial artery and vein can result in fistula formation between the skin and the lacerated duct (Newton et al, 1997).One cause of parotid gland fistulation/drainage is iatrogenic surgical trauma. For example, during surgical removal of melanomas embedded in the parotid gland and during surgical approaches to the guttural pouch or mandible. A previously unreported complication of prosthetic laryngoplasty was detailed in the case report by Sanclemente et al (Sanclemente et al, 2025). Although anatomically close to the linguofacial vein it would be unusual to iatrogenically damage the parotid gland during prosthetic laryngoplasty (Rossignol and Ducharme, 2021). However, it should be straightforward to determine that lobes of the parotid gland were disrupted during the surgical approach to the larynx. The lobes of the parotid gland are characteristically dull white to yellow in appearance and are soft and friable (Dyce et al, 1987). Based on the author’s experience disruption of the parotid gland will lead to wound drainage or accumulation of fluid postoperatively (sialocele). When known surgical trauma to the parotid gland is recognized the author has left a portion of the incision open for drainage or placed a passive drain (Penrose) to encourage fluid drainage. Cases managed in this fashion have all been resolved without additional treatment.For the case reported here inadvertent disruption of the parotid gland during the laryngoplasty procedure resulted in severe, postoperative fluid accumulation. The sialocele formation contributed to a follow-up surgical procedure to explore the previous incision and to assess abduction of the arytenoid cartilage. Unfortunately, the laryngoplasty had failed necessitating a repeat laryngoplasty. Following repeat laryngoplasty the surgeons were faced with three treatment options including primary wound closure, leaving a portion of the incision open for drainage or placement of an active or passive drain. To minimize the risk for surgical site infection following repeat laryngoplasty the authors elected to perform a primary wound closure without establishing any form of drainage. Even without saliva leakage from the parotid gland the risk for a surgical site infection or seroma formation following a repeat laryngoplasty is high in the author’s experience. This case was complicated by an already high risk for postoperative seroma formation because of the repeat laryngoplasty and the iatrogenic damage to the parotid gland.A better option would have been open incisional drainage or placement of a Penrose drain. The primary reason being the high risk for ongoing drainage associated with the parotid gland and surgical trauma associated with repeat laryngoplasty. Another option would have been to place an indwelling suction drain. This decision is solely surgeon preference (Bischofberger, 2019). Both types of drainage solutions have their pros and cons and the advantages of preventing ongoing saliva accumulation outweigh the risk for a surgical site infection. Traumatic and iatrogenic parotid gland disruption can be managed successfully with open drainage and secondary wound healing and has been reported in humans and horses. In horses’ persistent drainage of saliva post parotid gland or duct injury has been managed with chemical involution of the parotid gland (Schmotzer et al, 1991).Sanclemente et al reported a novel method to decrease postoperative sialocele formation. Following repeat laryngoplasty, saliva drainage from the damaged parotid salivary gland was eliminated following intraglandular injection of botulinum toxin A. They reported that saliva accumulation ceased 5 days after the injection. The horse recovered successfully and was able to return to exercise without recurrence of exercise intolerance.The injection of botulinum toxin A and B in horses has been performed clinically and experimentally (Adam-Castrillo et al, 2004; DePuy et al., 2007; Gutierrez-Nibeyro et al., 2014; Jimenez et al., 2024). The reported dosages of botulinum toxin type A have ranged from 50 to 200 units and for type B have ranged from 50 to 2500 Units. In one study evaluating the injection of botulinum toxin type B into the external anal sphincter of horses no systemic effects were observed with dosages of 500, 1000, and 1500 units but a dosage of 2500 units resulted in lethargy, weakness and dysphagia for 14 days. This indicates an increased risk for clinical botulism following high dose administration of botulinum toxin B (Adam-Castrillo et al., 2004). To the authors’ knowledge no ideal dosage of botulinum toxin has been determined for the horse.In humans with parotid fistulas, drainage secondary to surgical procedures or trauma, the primary means of treatment has been establishment of drainage, second intention healing, bandaging, packing of the wound with gauze and intraglandular parotid injection of botulinum toxin (Chettyvattum et al., 2025; Hao et al., 2023; Jeong et al., 2024; Marks et al., 2024; O’Keefe et al., 2022; Santos et al., 2025; Send et al., 2018; Tighe et al., 2015). Type A botulinum toxin is the preferred agent to stop secretion of saliva from the parotid gland. The primary mechanism of action for botulinum toxin is the blocking of acetylcholine release and other neurotransmitters. The blockage of acetylcholine release decreases or eliminates saliva secretion and production from the parotid salivary gland. The botulinum toxin is injected percutaneously under ultrasonographic guidance (Marks et al., 2024). Dosages of botulinum toxin used in humans range from 5 to 100 units. Currently, in humans intraglandular injection of botulinum toxin A is the preferred method of resolving saliva fistulation secondary to an injured parotid gland.The authors of this case report used an empirical dose of 100 units of botulinum toxin A to manage persistent drainage from the surgically damaged lobe of the parotid gland. The author is not familiar with any experimental evidence of the effect of botulinum toxin A on secretion of saliva from the equine parotid gland. However, there has been an additional report of two horses with parotid trauma successfully managed with the intraglandular injection of 200 units of botulinum toxin A (Jimenez et al., 2024). Therefore, based on these three cases dosages of 100 to 200 units of botulinum toxin A could be used to manage persistent parotid salivary gland drainage of saliva (Jimenez et al., 2024; Sanclemente et al., 2025) without complications.Fortunately, parotid gland disruption secondary to a surgical approach to the equine larynx for laryngoplasty is rare. If lobes of the parotid gland are identified during a surgical approach to the larynx damage to the gland could be minimized by using blunt dissection to separate the gland from the linguofacial vein. In addition, the use of the LigasureTM device has been recommended to cauterize damaged portions of the parotid gland and minimize the risk for postoperative secretion of saliva in humans (Prokopakis et al., 2005). In general, the implantation of drains associated with equine laryngoplasty has been discouraged because of the presumptive risk of increased incidence of a surgical site infection. However, if this complication is encountered in additional cases leaving a portion of the incision open to allow drainage rather than completely close the surgical incision should be considered. The author has managed laryngoplasty seroma formation with targeted incisional suture removal to allow passive drainage of seroma from the surgical site and has not experienced an increased risk for a surgical site infection (Rossignol and Ducharme, 2021).In conclusion, damage to the parotid salivary gland can lead to fistulation, chronic drainage of saliva or sialocele formation and these complications can be managed with a variety of options. Based on the collective experience in humans, the intraglandular injection of botulinum toxin A should be considered to resolve this unusual complication in horses.

backend=biber, style=alphabetic, sorting=ynt ]biblatex Subepiglottic cysts form within the aryepiglottic tissue of the equine upper airway and are thought to arise from remnants of the embryonic thyroglossal duct, craniopharyngeal duct or Ranke’s pouch. The clinical presentation of affected horses can vary, with larger cysts usually associated with symptoms such as dysphasia, exercise intolerance, and epiglottic entrapment. Incidental recognition of asymptomatic cases can occur during routine endoscopic examination. Various surgical approaches and techniques for cyst excision have been described and are most commonly performed under general anaesthesia. This case report describes an alternative surgical technique in two horses where cyst excision was performed under standing sedation using a transoral approach with endoscopic guidance. A four-wire electrocautery polypectomy snare was used to encircle and excise the cyst(s) in toto. The technique offers advantages including improved visualisation of the surgical field and reduced complications usually associated with general anaesthesia. In both cases, the surgery was well tolerated, and the cysts were successfully removed without complication and recoveries were uneventful.

A 14-year-old warmblood gelding was managed for waxing and waning cranial nuchal bursitis for two years. Intensive medical and surgical management was not curative, and the patient was subjected to euthanasia after becoming acutely recumbent. Ante-mortem and post-mortem next generation sequencing of bursal tissue, and post-mortem conventional PCR detected sequence within the Actinobacterial phylum. Post-mortem examination, computed tomography (CT) and magnetic resonance imaging (MRI) findings confirmed spinal cord compression, an undescribed sequela of nuchal bursitis in modern equine medicine.

Background: Volvulus nodosus is a strangulating lesion of the small intestine described only in foals and in just one case in older horses. Huskamp et al (1982, 1998) described the pathophysiology of volvulus nodosus in foals, but to date there is no description of the pathophysiology of volvulus nodosus in adults. Objectives: to describe the different features of volvulus nodosus in adult horses and in foals. Study design: Clinical case series. Methods: Analysis of the clinical and anatomical features of 2 foals and 3 adults presenting with volvulus nodosus. Results: Clinical presentation between foals and adults differed mainly for the mild or absent pain showed by older horses. Clinical and ultrasonography findings were similar. At surgery or necropsy we found anatomical differences between adults and foals. In adults the volvulus didn’t involve the mesentery that instead forms a hernia sac in foals. Further, in adults, there wasn’t involvement of the ileum, but two loops of jejunum resulted one wrapped around another in all 3 cases. After accurate analysis of one case at necropsy, we found that in adults one loop act as a “post” around which another loop turns around. The weight of this loop causes then the formation of a half-hitch formed by the two loops and their mesentery. This cause strangulation and necrosis of two separate tract of jejunum. Main limitations: Small number of cases included. Conclusions: Volvulus nodosus may occur in adult horses with significant differences compared to foals. Knowing the presentation and pathophysiology of volvulus nodosus may help equine surgeons to resolve selected cases of small intestinal strangulation in adult horses.

Manufacturer´s address:Titanium plug: Pferd Dental, 65329 Hohenstein, Germany, (info@pferdefit.de)

Temporohyoid osteoarthropathy: The challenge of modifying physiologic forcesSebastian Larriva MVZ, MS. Anne Brien DVM. Nicholas P. Hall DVM, MS, DACVS-LA.

Abstract Background Horses are used in various countries for multiple purposes and often play a crucial role in the livelihood of many communities. However, parasitic infections represent a significant threat to their health and productivity. Objectives:  This study aimed to identify gastrointestinal parasite species affecting horses using coprological methods and to assess the influence of certain factors (age, sex, and bioclimatic zone) on these infections. Study design: These samples were analyzed using flotation techniques to detect fecal parasitic forms (eggs, oocysts) and larvae. Methods: Between January and May 2024, fresh fecal samples were collected from 121 horses in Setif region (Northeastern Algeria). Prevalences were calculated for each gastrointestinal parasite and the influence of certain intrinsic (age, sex) and extrinsic (region) parameters on these prevalences was analyzed. We have found, namely Strongylus vulgaris (38.84%), Oxyrus equi (7. 44%), Parascaris equorum (24.62%), Anoplocephala spp. 6.61% and 5.79 were carriers of Eimeria leuckarti and 4.96% had Giardia duodenalis cysts Conclusions This study demonstrates that horses in the Setif region are commonly affected by gastrointestinal parasites, with a predominance of mixed infestations. Both helminths and protozoa were identified, with Strongylus vulgaris and Parascaris equorum being the most prevalent species. The variations in infestation rates across age groups, sex, and geographical zones highlight the influence of environmental and management factors.   Keywords : Horse, parasite, gastrointestinal, Algeria

“Carpal Sheath Hernia in a Cob: Unusual Case, Unorthodox Fix”The case report presented by Neild et al. (2025) describes a rare and unusually complex case of carpal sheath synovial herniation in a cob-cross mare following tenoscopic treatment of a radial physeal exostosis and intra-thecal deep digital flexor tendon (DDFT) tear - an injury more commonly seen in racehorses due to carpal hyperextension (Southwood et al., 1998). The use of a synthetic polypropylene mesh to support the compromised carpal sheath wall represents a novel adaptation of herniorrhaphy techniques to equine synovial pathology and adds a valuable perspective to the growing body of surgical solutions for complex synovial outpouchings. Beyond its technical innovation, the case report also invites thoughtful discussion on several broader clinical themes, including the underlying aetiopathogenesis in an atypical breed, the localisation and assessment of pain in such cases, the interpretation of intrathecal tissue recovery, and the contextualisation of this case within the existing literature.Unusual presentation in a Cob-Cross: Synovial herniation of the carpal sheath is rarely seen in cob-type horses, whose upright limb conformation limits carpal hyperextension. While there is no published evidence specifically linking this condition to Thoroughbreds or other high-motion sport horses, it is thought to be more likely in these types due to the greater frequency of carpal overextension in such populations (Nixon et al., 2004; Southwood et al., 1998). In this case, however, the mare was diagnosed with a radial physeal exostosis where a concurrent deep dorsolaterally located DDFT tear would suggest significant bony pathology given that it matched the location of the exostosis. However, it is also possible that the tear could have been created or exacerbated by dynamic carpal over-extension although, notably, the report does not document this. An injury to the accessory ligament of the DDFT (ALDDFT) injury has also been associated with carpal over-extension and could have been responsible for chronic effusion, requiring repeat sheath injections, but was not reported by the authors.Definition of synovial herniation: ”Synovial Hernia” vs. ”Synoviocoele”: The terminology used to describe fluid-filled swellings associated with synovial structures, particularly the digital flexor tendon sheath (DFTS) and tarsal sheath, has long been inconsistent in the veterinary literature (Hawkins et al., 2021; Minshall et al., 2015; Crawford et al., 2011; Laverty 2009). Terms such as synovial hernia, synoviocoele, synovial ganglion cyst, and adventitious bursa have been applied somewhat interchangeably, though each has specific pathological and anatomical implications. In this case report, Neild et al. (2025) have elected to use the term “synovial hernia”, which traditionally refers to a protrusion of the synovial membrane through a defect in the joint capsule or tendon sheath, often still maintaining continuity with the synovial cavity. This implies that the stratum synoviale has remained intact but has extended abnormally through a fascial or capsular defect. However, given that histopathology was not performed in this case, there is no definitive evidence as to whether the herniated sac retained its synovial lining or was instead the result of rupture and subsequent extra-synovial fluid accumulation. As shown in Crawford et al. (2011), similar fluid-filled structures in the DFTS often lack a synovial lining when examined histologically and instead demonstrate myxomatous inflammation consistent with a synovial ganglion cyst. Minshall & Wright (2012) initially proposed the termsynoviocoele as the most neutral and anatomically descriptive term, simply denoting a cavity of synovial origin without implying a specific pathogenesis or histological profile. Thus, in the absence of histological confirmation in this case, ”synoviocoele” would have been the more conservative and technically accurate descriptor. It acknowledges the synovial origin of the lesion while avoiding assumptions about the integrity or composition of the synovial membrane. In future publications regarding these structures, it would be helpful for authors to clarify the rationale behind terminology choice, particularly when the underlying lesion’s nature - whether herniation, rupture, or cystic degeneration remains speculative in the absence of a biopsy (table 1).Pathogenesis of Synovial Herniation Post-Tenoscopy; The authors attribute the formation of the synovial hernia primarily to post-operative effusion and increased intrasynovial pressure, which may have forced synovial fluid and potentially the synovial membrane through a fascial defect at the site of tenoscopic portal creation. They propose that repeated intra-thecal corticosteroid injections may have further compromised local tissue integrity by suppressing fibroblast activity, contributing to fascial weakening (Stankler & Ewen 1972). Additionally, they acknowledge that multiple instrument passages during the initial tenoscopy could have enlarged the fascial rent, particularly between the ulnaris lateralis and lateral digital extensor muscles, an area that naturally experiences dynamic loading.While these are plausible contributors, the authors do not explore several other likely mechanisms. The cumulative biomechanical strain from exercise during the post-operative period may have exacerbated tension at the weakened portal site. Moreover, the potential for incomplete fascial healing, especially in a site of high motion and pressure fluctuation, could have predisposed the area to delayed herniation. The role of local ischaemia or microvascular disruption during surgery, particularly if compounded by corticosteroid use, was also not discussed but could have further impaired normal healing processes.Taken together, it is likely that the hernia developed as a multifactorial sequela of focal surgical trauma, prolonged synovial effusion, pharmacological tissue suppression, and mechanical stress over time. This case serves as a valuable reminder of the importance of portal site management, controlled rehabilitation, and consideration of long-term tissue resilience following tenoscopy, particularly in horses with conformational or workload factors that may place additional strain on surgical sites.Potential Sources of Pain in Synovial Herniation; Minshall and Wright (2012) proposed a “one-way valve” hypothesis for the pain caused by synoviocoeles, where pressure-related pain is central to their significance. In the discussion of the case report, the authors suggest that the clinical significance was likely a consequence of increased intrasynovial pressure secondary to post-operative effusion, with synovial fluid and possibly synovial membrane, being forced through a fascial defect at the tenoscopic portal site. While these are reasonable explanations, they are not explicitly linked to the clinical signs of pain observed in this case. The authors stop short of discussing how these structural changes might have resulted in significant lameness - up to grade 4/5 (AAEP scale) at walk, which is unusual for many synovial outpouchings unless they are large, tense, or associated with deeper pathology. The presence of visibly thinned, compromised skin overlying the hernia was well described in the report but not directly discussed as a pain source. In clinical practice, excessive tension on thinning dermis, particularly in a mobile region like the proximolateral antebrachium, is highly likely to cause nociceptive discomfort and may have been a significant contributor to the horse’s lameness (Muir 2010). Furthermore, the anatomical location of the hernia - situated between the ulnaris lateralis (UL) and lateral digital extensor fasciae places it within a region of considerable muscular activity. The anatomical location of the hernia - between the ulnaris lateralis and lateral digital extensor fasciae places it in an area of substantial muscular activity. This is reminiscent of the biomechanical interplay proposed in accessory carpal bone fracture pathogenesis, where asynchronous contraction of ulnaris lateralis and flexor carpi ulnaris occurs due to their differing embryological origins from dorsal versus ventral limb musculature (Diogo & Abdala 2010; Radue 1981). Despite UL’s developmental classification as an extensor, its functional role as a flexor, combined with flexor carpi ulnaris’s distinct insertion on the accessory carpal bone, creates opposing mechanical forces on the bone.Repetitive mechanical irritation, friction, or stretching of tissues during movement may have further sensitised the area. Although the authors do mention persistent effusion and synovitis, they do not explore whether this inflammatory environment might have sustained or amplified the horse’s pain. Furthermore, given the proximity of superficial nerves in this area, nerve stretch or entrapment cannot be ruled out, especially in a large, space-occupying lesion (Hawkins et al., 2021). In these authors’ opinion, the pain observed in this case is most likely to have arisen from a combination of dermal tension, mechanical irritation, persistent low-grade synovitis, and possibly neuropathic mechanisms. A more comprehensive assessment of pain pathways in similar cases, including diagnostic blocks and dynamic palpation would enhance our understanding of when such hernias are clinically significant and warrant surgical correction.Diagnostic Challenges : While the pathology is self-evident, synovial herniation is not always associated with pain and lameness, which creates a diagnostic challenge to the clinician. A lack of pain on palpation along with ability to deflate the hernia on non-weight bearing examination, has been proposed previously to be useful clinical indicators of significance (Hawkins et al., 2021), but the authors provide no mention of any pain on digital palpation or compression; and would argue against the hernia as the cause of the lameness. The authors acknowledge that diagnostic anaesthesia of the carpal sheath was not performed during the recurrent lameness episodes. This omission leaves uncertainty regarding the actual source of pain and whether the hernia was causative or coincidental.In this report, the authors note diffuse sheath inflammation at repeat tenoscopy of the carpal sheath, but without correlating that finding directly with lameness. Furthermore, the authors state that the tendon injury demonstrated good healing at the repeat tenoscopy therefore unlikely to be contributing to the ongoing lameness. Tendon pain can exist in the absence of surface defects and during healing. Unfortunately, however, intra-synovial diagnostic analgesia is not always able to differentiate these sites of pain.Surgical Insight and Considerations; The pressure-related pain is central to the previously proposed surgical indication of tenoscopic decompression (Minshall & Wright (2012); Hawkins et al. (2021). In this case, it would appear that the communicating defect was large and therefore could not be associated with a ‘one-way valve’ phenomenon. Thus, an alternative approach was necessary and their choice to use a synthetic mesh was an important innovation. The authors describe clear surgical rationale: the fascial defect was too large for simple closure, and resection of the hernial sac would have created a large defect in the synovial membrane with attendant risks of synovial sepsis (Hawthorn et al., 2016). The mesh provided tensile support and allowed for imbrication of synovium without excess tension - a sound approach, especially given the persistent effusion that may have otherwise predisposed to recurrence. However, the post-operative superficial necrosis, likely due to horizontal mattress sutures, suggests the need for alternative skin-closure techniques in future applications. Importantly, the mesh-induced fibrosis likely played a role in preventing re-herniation, as seen in other species (Fitzgerald & Kumar 2014), but long-term consequences of mesh use in equine synovial structures remain unknown and warrant further study. It should be noted, however, that these authors have observed a large synovial herniation resolving in time although the mechanism why this can occur in some cases but not others is unknown (figure 1).Conclusion: This case report offers a creative and successful solution for treating a carpal sheath synovial hernia in a cob-cross horse following tenoscopy - an infrequent but frustrating complication. The authors are commended for introducing mesh herniorrhaphy into equine orthopaedic practice in a synovial context. That said, clarification of the origin of the pain would help limit this approach to those herniations which can be linked definitively with pain and help differentiate the need for a conservative approach or other surgical approaches, such as tenoscopic decompression (Minshall and Wright 2012; Hawkins et al. 2021). Future directions could include better defining the origin and antalgic effects of synovial herniation, the indications for mesh repair, and exploring long-term effects of mesh-induced fibrosis in the synovial environment.

Due to the length of the reserve crown and roots of equine cheek teeth, especially in younger horses, their extraction (exodontia) can be a challenging procedure with the potential for many types of post-extraction complications to develop. The prevalence of post-extraction complications is greatly influenced by the exodontia technique used, with unacceptably high levels of complications with the traditional repulsion technique and conversely, low levels of complications with oral extraction performed by skilled operators. Recent objective studies on post-exodontia problems in horses have also highlighted some risk factors for the development of post-extraction problems including exodontia of rostral mandibular teeth in young horses, and exodontia of teeth with apical infections The recent recognition that some non-healing post-extraction equine alveoli suffer from a disorder very similar to dry socket in humans, may help clinicians to recognise, treat and possibly help prevent this disorder.

A document by Callum Haseler. Click on the document to view its contents.

This report describes the evisceration of the jejunum following acute dehiscence of the abdominal wall in an 18 year old gelding which had undergone treatment for suspected sarcoids on the ventral abdomen with a topical caustic/chemotherapy agent 6 weeks previously. The sarcoid lesions appeared to be responding appropriately to the topical therapy until the day of presentation. The jejunum was safely contained in an abdominal bandage and the horse underwent emergency referral before immediate anaesthesia and further assessment. The horse was euthanased at the owners’ request following a guarded prognosis.