Citation: Flores, J.A.; Rovesti, G.L.;

Rodriguez-Quiros, J. A Bilateral

Acetabular Physeal Fracture Treated

with External Fixation in an Immature

Cat. Animals 2024, 14, 379. https://

doi.org/10.3390/ani14030379

Academic Editor: Lysimachos

G. Papazoglou

Received: 14 November 2023

Revised: 14 January 2024

Accepted: 23 January 2024

Published: 25 January 2024

Copyright: © 2024 by the authors.

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animals

Case Report

A Bilateral Acetabular Physeal Fracture Treated with External
Fixation in an Immature Cat
Jose Antonio Flores 1,*, Gian Luca Rovesti 2 and Jesus Rodriguez-Quiros 3

1 Hospital Veterinario IVC Evidensia Prïvet, Calle Duero 37, Villaviciosa de Odón, 28670 Madrid, Spain
2 Clinica Veterinaria M. E. Miller, Via della Costituzione 10, 42025 Cavriago, Italy; glrovesti@gmail.com
3 Departamento de Medicina y Cirugía Animal, Facultad de Veterinaria, Universidad Complutense de Madrid,

Avda. Puerta de Hierro s/n, 28040 Madrid, Spain; jrquiros@ucm.es
* Correspondence: jose.a.flores@ivcevidensia.es

Simple Summary: This study intended to show the use of external fixation to resolve bilateral
acetabular physeal fractures in an immature cat, obtaining a good outcome with a low rate of
complications. A great part of this success was because external fixation allows fractures to be
stabilised through a minimally invasive procedure. In addition to its relevance as a fixation method,
it was possible to show that external fixation provided comfort and a high level of tolerance for the
patient during the whole healing period.

Abstract: This study aimed to assess the outcome of a bilateral acetabular physeal fracture treated
with external fixation in an immature cat, a surgical technique not usually employed in immature
patients. The fixator took 40 days, and it was removed after radiographic bone healing was achieved.
No significant complications related to the technique were identified, and the outcome was classified
as good based on the functional assessment and pain scales employed. The use of external fixation
for stabilising acetabular fractures in immature cats should be considered a viable technical option,
especially for minimally invasive stabilisation.

Keywords: cat; acetabular; external fixation; fracture; immature cat

1. Introduction

Pelvic fractures in cats account for 22–32% of all skeletal system fractures [1,2]. Among
these, acetabular fractures constitute 14–43% of the total [3,4]. Despite this, there is a lack of
information related to non-traumatic “acetabular physeal fractures” (APFs). The acetabular
physis closes between 20 and 24 weeks of age [1], and it is unknown whether APFs share
an etiological link with “Feline Epiphyseal Dysplasia Syndrome”, where spontaneous
fractures of the femoral head are described [5–8] in male patients, typically early-neutered,
young, obese [8], and/or hypothyroid [9]. There are no data in the literature supporting a
similar theory for the origin of APF.

Conservative treatment of acetabular fractures has traditionally been considered a
therapeutic option in immature patients [10]. Non-surgical options, though, are not the best
choice for the treatment of this type of fracture [1,10], as the most common complication is
the development of osteoarthritis [11]. Piana et al. suggest that displacements of more than
3 mm in fracture reduction are associated with a higher risk of osteoarthritis in the affected
joint [12]. However, other authors argue that this decision is more of a biomechanical
matter, where factors such as the patient’s level of activity and body weight are important
factors for deciding between conservative or surgical treatment [13]. Other complications
observed in displaced, non-reduced acetabular fractures include narrowing of the pelvic
canal with subsequent constipation, neurological deficits, and pain [4].

Different techniques are described for the treatment of acetabular fractures, with
the most commonly used being small fragment plates or locking plates [4,12–17] and the

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Animals 2024, 14, 379 2 of 10

combination of screws with polymethyl methacrylate or cerclage wire [1,4,18–20]. In cases
where surgical repair is not feasible, salvage procedures such as femoral head and neck
ostectomy can provide pain relief and preserve limb function [21]. The use of external
fixation (EF) as the sole stabilisation method in the treatment of APFs in immature cats
has not been described in the literature to our knowledge. While this technique has
been described as a complementary method in a single case in dogs [22], it has been
widely employed in paediatric patients with traumatic acetabular fractures in human
medicine [23,24].

The potential benefits of EF are that it is a minimally invasive approach, reducing
the damage to the vascular supply of tissues, avoiding a delay in bone healing [25,26],
and providing less postoperative pain [27]. However, the technique requires a good
understanding of the principles of its application [25] to avoid complications. The most
frequent complications associated with this technique include implant loosening and
delayed bone healing [28,29].

This paper describes the surgical technique and the outcome of a case of a bilateral
non-traumatic APF in a 5-month-old cat.

2. Materials and Methods

This study involves a 20-week-old, 950 grs cat admitted to Prïvet Veterinary Hospital
(Villaviciosa de Odón, Madrid, Spain). The patient presented with difficulty standing and
walking, exhibiting evident signs of pain during the physical examination. The report
includes details about the cause of the fracture, the surgical procedure, the radiographic
images, and the evaluation of lameness both before and after the intervention. Additionally,
information on postoperative (PO) progress, more detailed below, was collected during
follow-up consultations at the hospital as well as through two phone calls conducted 4 and
6 months after the intervention to assess the presence of lameness and ambulatory function.

2.1. Preoperative Management

The preoperative management involved sedating the patient for a radiographic study.
The patient was sedated with an intramuscular injection of medetomidine (Medetor
1 mg/mL, Virbac España SA, Esplugues de Llobregat, Spain) at a dose of 100 mcg/kg,
methadone (Semfortan, Eurovet Animal Health BV, Handelsweg, The Netherlands) at
a dose of 0.4 mg/kg, and midazolam (Midazolam Normon, Laboratorios Normon SA,
Tres Cantos, Spain) at a dose of 0.1 mg/kg. Lateral and ventrodorsal pelvic projections
were taken, revealing a bilateral APF with a displacement of 6 mm between the frag-
ments in both fracture sites. Post-radiography, the patient was treated with meloxicam
(Inflacam 0.5 mg/mL; Virbac España SA, Esplugues de Llobregat, Spain) at a dose of
0.1 mg/kg orally.

After 24 h, the patient was operated on to address both fractures. The premedication
protocol was the same as that used for sedation during the previous radiographic study. The
patient was induced with propofol (Propofol Lipuro 10 mg/mL; B. Braun, Melsungen AG,
Germany) at a dose of 2 mg/kg intravenously and maintained under inhalation anaesthesia
using isoflurane (Isoflo; Zoetis Spain SL, Madrid, Spain).

2.2. Surgical Technique

The surgical site was prepared by shaving and disinfecting the lumbosacral and gluteal
dorsal regions, extending from the midportion of the lumbar spine to below both stifle
joints. The patient was positioned in sternal recumbency with a ventral support that kept
the hind limbs abducted and the pelvis as horizontally aligned as possible on the surgical
table. During the procedure, the main anatomical references of the pelvis were identified:
iliac crests, iliac wings, and ischial tuberosities. Safe corridors for the placement of the
external fixator (EF) transfixing nails were determined as follows.



Animals 2024, 14, 379 3 of 10

• Sacral tuberosity corridor of the ilium, near the origin of the gluteus medius muscle.
The pins were inserted at an angle of 10–15◦ from proximo-medial to disto-lateral to
the vertical.

• Corridor of the body of the ilium, in the caudal aspect, along the origin of the gluteus
profundus muscle, with pins inserted at an angle of 10–15◦ to the vertical of the
iliac crest.

• Ischial tuberosity corridor, with pins inserted at an entry angle of 10–15◦ to the vertical.

In total, eight end-threaded, self-tapping 1.2 mm-diameter pins were inserted after
performing a predrilled hole: one pin in each iliac crest, another pin in each body of the
ilium, and a third and fourth pin in each body of the ischium and ischial tuberosity. Once
properly placed by a fluoroscopy-assisted procedure, the pins were used to reduce both
APFs, and they were interconnected with a 1.5 mm bar and Meynard clamps (Insorvet,
Barcelona, Spain). A pin introduced in the ischium of each hemipelvis was connected
directly with a pin inserted in the ilium due to the lack of room for the connection clamp in
the main bar.

2.3. Postoperative Care

Lateral and ventrodorsal radiographic projections were taken to confirm the fracture
reduction. After 24 h, the patient was discharged with a 7-day prescription for cephalexin
(Cefaseptin 75 mg; Vetoquinol Especialidades Veterinarias S.A., Alcobendas, Spain) at a
dose of 15 mg/kg every 12 h orally and meloxicam (Inflacam 0.5 mg/mL; Virbac España
SA, Esplugues de Llobregat, Spain) at a dose of 0.1 mg/kg every 24 h orally.

2.4. Follow-Up

Owners were instructed on the daily care of the pin entry sites. Strict confinement
of the cat was advised for the first 2 weeks. From the third week until the removal of
the fixator, it was recommended to gradually increase the available space for movement,
avoiding access to areas where the patient could run or jump. Follow-up radiographs were
taken at 21 and 40 days post-surgery. At the 21-day recheck, only a lateral projection was
taken in order to review the components of the system. In the last check-up at 40 days,
dorsoventral and lateral projections were made. For the dorsoventral projection, the hips
were flexed to facilitate better positioning of the patient with the EF. After radiological
checking and bone consolidation„ the implants were removed. Subsequently, ventrodorsal
and lateral radiographic projections of both hemipelvis were obtained.

In addition to monitoring bone healing, weekly physical examinations were conducted
to assess functional and pain assessments and to check the adjustment of the Meynard
clamps and pin stability. Two additional rechecks for functionality and pain were performed
at 16 and 24 weeks PO.

For the functional assessment, a 6-level scale was established to help determine
progress and the final outcome.

• Level 0: no functional or locomotor alterations. The patient walks normally.
• Level 1: mild locomotor alterations, with occasional mild lameness.
• Level 2: mild-to-moderate locomotor alterations, with mild and consistent lameness.
• Level 3: moderate locomotor alterations, with moderate and partially constant lameness.
• Level 4: severe locomotor alterations, with pronounced lameness involving intermit-

tent non-use of the limb.
• Level 5: very severe functional alterations with complete limb disuse.

The pain experienced by the patient during the healing period was assessed using a
modified Visual Assessment Scale (VAS) based on the scale described by Flores et al. [29].
This modified scale ranged from A to C, with A indicating very good comfort and C
indicating poor comfort for the patient.

• Level A: No apparent signs of pain. The animal exhibits no complaints upon manipu-
lation. Considered normal behaviour.



Animals 2024, 14, 379 4 of 10

• Level B: Mild -to-moderate signs of pain. The animal shows some discomfort with
occasional spontaneous moans. There may be moderate difficulties in urination and
defecation. No other significant behavioural alterations.

• Level C: Severe signs of pain. Inability to handle the patient without accompanying
vocalisations. Severe difficulties in urination and defecation. Apathy and depression.

Once radiographic confirmation of the bone consolidation of the fractures was achieved,
the removal of the EF was performed. This removal procedure involved sedation and the
same protocol described for preoperative management.

3. Results

The exact cause of the fracture remained undetermined, as the owners did not observe
any preceding trauma. No other traumatic injuries were identified upon examination of
the patient. The radiographic images revealed the presence of APFs in both hips (Figure 1).

Animals 2024, 14, x FOR PEER REVIEW 4 of 11 
 

This modified scale ranged from A to C, with A indicating very good comfort and C indi-
cating poor comfort for the patient. 
• Level A: No apparent signs of pain. The animal exhibits no complaints upon manip-

ulation. Considered normal behaviour. 
• Level B: Mild -to-moderate signs of pain. The animal shows some discomfort with 

occasional spontaneous moans. There may be moderate difficulties in urination and 
defecation. No other significant behavioural alterations. 

• Level C: Severe signs of pain. Inability to handle the patient without accompanying 
vocalisations. Severe difficulties in urination and defecation. Apathy and depression. 
Once radiographic confirmation of the bone consolidation of the fractures was 

achieved, the removal of the EF was performed. This removal procedure involved seda-
tion and the same protocol described for preoperative management. 

3. Results 
The exact cause of the fracture remained undetermined, as the owners did not ob-

serve any preceding trauma. No other traumatic injuries were identified upon examina-
tion of the patient. The radiographic images revealed the presence of APFs in both hips 
(Figure 1). 

 

 

Figure 1. (Left): Lateral radiographic projection of the pelvis showing the bilateral APF. (Right): 
Ventrodorsal radiographic projection of the same patient. 

To stabilise the fractures, an eight-pin fixator with 1.2 mm positive-threaded pins and 
a connecting 1.5 mm-diameter bar was used (Figures 2 and 3). 

Figure 1. (Left): Lateral radiographic projection of the pelvis showing the bilateral APF. (Right):
Ventrodorsal radiographic projection of the same patient.

To stabilise the fractures, an eight-pin fixator with 1.2 mm positive-threaded pins and
a connecting 1.5 mm-diameter bar was used (Figures 2 and 3).

The treatment time with the EF had a total duration of 40 days, with an intermediate
radiological check after 21 days (Figure 4) showing initial signs of healing. In the second
and final radiological examination at 40 days (Figure 5), complete bone healing was con-
firmed, allowing for the removal of the system under patient sedation. This procedure was
carried out following the aforementioned anaesthetic protocols, and after removal, a new
radiological control was performed (Figure 6).

In the initial clinical assessment, the patient had difficulty walking and supporting
its own weight with the pelvic limbs, rated at levels 5 and C on both scales. At this point,
a neurological examination did not reveal any abnormalities of this nature, although the
patient experienced difficulties in urination and defecation, with stranguria and constipa-
tion, respectively.

After the surgical intervention, the patient still exhibited a level 5 in functionality and
a level C on the pain scale. The use of both pelvic limbs was appropriate, with levels 3
and B during the first 2 weeks of treatment. Some difficulty in extending the spine was
observed due to the forward position of the connecting bar between both half-fixators,
although this did not prevent the patient from leading a completely normal life with the
system. For this reason, it was decided to cut the cranial part of the connecting bar after
21 days of postoperative radiographic control. At the 3- and 4-week controls, the patient
showed levels 2 and B on the assessment scales. In weeks 5 and 6, the patient was evaluated



Animals 2024, 14, 379 5 of 10

at levels 1 and A. After the removal of the system, the patient remained at levels 2 and A
for 24 h. Subsequently, the patient returned to complete normality, showing no pain or
any alteration in gait and maintaining levels 0 and A in the scheduled follow-ups after 16
and 24 weeks. Information regarding functional and pain evolution during the treatment
period is summarised in the following table (Table 1).

Animals 2024, 14, x FOR PEER REVIEW 5 of 11 
 

 

  

Figure 2. (Top): Close-up of the external appearance of the EF. (Bottom left): Dorsal view of the EF 
covered by a protective bandage. (Bottom right): Lateral view of the EF. 

  

Figure 3. (Left): PO lateral radiographic projection. Note the evident reduction in the gap at the 
fracture site. (Right): PO dorsoventral radiographic projection. In the dorsoventral follow-up radi-
ographs, the hips are flexed for better and more comfortable patient positioning. 

The treatment time with the EF had a total duration of 40 days, with an intermediate 
radiological check after 21 days (Figure 4) showing initial signs of healing. In the second 
and final radiological examination at 40 days (Figure 5), complete bone healing was con-
firmed, allowing for the removal of the system under patient sedation. This procedure 
was carried out following the aforementioned anaesthetic protocols, and after removal, a 
new radiological control was performed (Figure 6). 

Figure 2. (Top): Close-up of the external appearance of the EF. (Bottom left): Dorsal view of the EF
covered by a protective bandage. (Bottom right): Lateral view of the EF.

Animals 2024, 14, x FOR PEER REVIEW 5 of 11 
 

 

  

Figure 2. (Top): Close-up of the external appearance of the EF. (Bottom left): Dorsal view of the EF 
covered by a protective bandage. (Bottom right): Lateral view of the EF. 

  

Figure 3. (Left): PO lateral radiographic projection. Note the evident reduction in the gap at the 
fracture site. (Right): PO dorsoventral radiographic projection. In the dorsoventral follow-up radi-
ographs, the hips are flexed for better and more comfortable patient positioning. 

The treatment time with the EF had a total duration of 40 days, with an intermediate 
radiological check after 21 days (Figure 4) showing initial signs of healing. In the second 
and final radiological examination at 40 days (Figure 5), complete bone healing was con-
firmed, allowing for the removal of the system under patient sedation. This procedure 
was carried out following the aforementioned anaesthetic protocols, and after removal, a 
new radiological control was performed (Figure 6). 

Figure 3. (Left): PO lateral radiographic projection. Note the evident reduction in the gap at the
fracture site. (Right): PO dorsoventral radiographic projection. In the dorsoventral follow-up
radiographs, the hips are flexed for better and more comfortable patient positioning.



Animals 2024, 14, 379 6 of 10Animals 2024, 14, x FOR PEER REVIEW 6 of 11 
 

 
Figure 4. Lateral radiographic projection of the pelvis obtained 21 days after the surgical interven-
tion. Initial radiological signs of healing are observed. 

  

Figure 5. (Left): Lateral radiographic projection at 40 days PO. (Right): Dorsoventral radiographic 
projection. 

  

Figure 4. Lateral radiographic projection of the pelvis obtained 21 days after the surgical intervention.
Initial radiological signs of healing are observed.

Animals 2024, 14, x FOR PEER REVIEW 6 of 11 
 

 
Figure 4. Lateral radiographic projection of the pelvis obtained 21 days after the surgical interven-
tion. Initial radiological signs of healing are observed. 

  

Figure 5. (Left): Lateral radiographic projection at 40 days PO. (Right): Dorsoventral radiographic 
projection. 

  

Figure 5. (Left): Lateral radiographic projection at 40 days PO. (Right): Dorsoventral radiographic projection.

Animals 2024, 14, x FOR PEER REVIEW 6 of 11 
 

 
Figure 4. Lateral radiographic projection of the pelvis obtained 21 days after the surgical interven-
tion. Initial radiological signs of healing are observed. 

  

Figure 5. (Left): Lateral radiographic projection at 40 days PO. (Right): Dorsoventral radiographic 
projection. 

  

Figure 6. (Left): Lateral radiographic projection after the removal of the external fixator. Acceptable
healing and proper congruence of both fragments are observed. (Right): Dorsoventral radiographic
projection. No stenosis of the pelvic canal is evident.



Animals 2024, 14, 379 7 of 10

Table 1. Data obtained in different follow-up controls assessing the patient’s functional status and
pain according to the described assessment scales. PrO: preoperative; PO: postoperative; W: week;
EXP: implant removal.

PrO PO W1 W2 W3 W4 W5 W6 EXP W16 W24

Functional Scale 5 5 3 3 2 2 1 1 2 0 0

Pain Scale C C B B B B A A A A A

Regarding the resistance of the employed system, no loosening of the pins and/or
the clamps was recorded due to fatigue in the 40 days of fixation. Throughout the entire
healing period, no major complications were experienced, except for the modification of
the system at 21 postoperative days and mild, intermittent, and episodic serosanguinous
discharge from the pin entry holes observed during the first two weeks of treatment.

4. Discussion

In the literature, there are no references to the treatment of spontaneous APFs in cats.
Clinical signs compatible with ‘Patellar Fracture and Dental Anomaly Syndrome (PADS)’
were not detected in the patient, as this syndrome is characterised by dental abnormalities,
patellar fractures, and other non-traumatic fractures [17,30]. Typically, internal fixation
methods dominate the resolution of acetabular fractures [4,12–15,17]. In human medicine,
the use of EF in pelvic fractures at certain stages of treatment has been described [31–36] due
to its structural advantages [32–40], including for acetabular fractures in particular [34–36].
EF allows for minimal invasive approaches, resulting in minimal damage to surrounding
tissues, with a consequent lower risk of infection, a shorter healing time, and a good level
of patient tolerance [25–28].

In the case presented here, conservative treatment was ruled out due to possible
neurological consequences and sustained pain during the healing period [1–5,10]. Addi-
tionally, the possibility of osteoarthritis resulting from incomplete fracture site reductions
was considered [11,12]. Internal osteosynthesis techniques were excluded due to the small
size of the patient, requiring an extensive approach involving small anatomical structures.
The possibility of performing a double femoral head and neck excision was considered,
but this option was discarded after considering its possible drawbacks like limb shorten-
ing, reduced range of motion, muscle atrophy, patellar luxation, and persistent pain and
lameness [41].

In this patient, EF was used to reduce both fractures without the need for an open
approach, using fluoroscopy for precise manipulation of the bone fragments and achieving
good anatomical alignment of the reduction. The use of EF to treat acetabular fractures
in cats is uncommon. Only Graville et al. (2018) and Flores et al. (2023) have described
this system being successfully applied to acetabular fractures in canines for this type of
fracture [23,31]. In other types of pelvic injuries, like sacroiliac luxations, closed reduction
has been shown to be effective and provide good results [42], allowing for a faster recovery
in the postoperative period. The patient’s size also influenced the choice of the EF system
over internal osteosynthesis, as finding suitable implants for a bilateral fracture in a very
small cat would have been a challenge [1]. These various factors collectively influenced the
decision to employ EF for treating the APFs.

This patient showed moderate to good locomotor function from the early weeks,
walking with mild restrictions during the initial two weeks and experiencing minimal
limitations throughout the treatment. Severe signs of pain were only detected at the time
of presentation and during the first 24 h after surgery. Once the fractures were stabilised
with the external fixation and the inflammation decreased, the pain gradually diminished,
consequently eliminating the signs of stranguria and constipation induced by it. From the
first postoperative week, the patient showed significant improvements, transitioning from
levels 5 and C in the assessment scales to levels 3 and B, which is considered a relatively
short time for this type of joint fracture. Anti-inflammatory drug treatment was only



Animals 2024, 14, 379 8 of 10

administered during the first postoperative week, indicating the patient’s good tolerance
to the fixation system. The only incident worth noting was related to the positioning of
the connecting bar between both sides of the fixator, which was removed after 21 days
of treatment. The bar was positioned too far cranially, preventing proper extension of
the lumbosacral spine. In the chosen configuration, this bar consisted of a single piece
connecting the two parts of the system. Once it was cut, when 50% of bone healing
was achieved, both parts of the connecting bar behaved as independent fixators. The
patient showed a very good degree of tolerance compared to that observed with open
approaches, especially the one described for the acetabular region, which often involves
greater trochanter osteotomy or gluteal tenotomy [1,42,43].

Bone healing was recorded after 40 days, and this timeframe is considered acceptable
compared to figures obtained in similar cases treated with internal fixation, which often
requires up to 60 days [1]. The closed approach employed in this case contributed to a
faster recovery, as described in the literature [44]. The use of an EF allowed for easy, quick,
and non-invasive implant removal, which is crucial for growing patients. This contrasts
with cases where internal fixation is used, which often require a reintervention with an
open approach to remove implants, as mentioned in a study by Langley-Hobbs et al. [1].
Additionally, it is highlighted that the diameter of the pelvic canal did not experience any
collapse after treatment, which is a common complication and sometimes unavoidable
when treating acetabular fractures [1,3–5].

During the healing period, no significant complications related to the implant were
identified. Only, as mentioned earlier, a modification in the system design had to be made
after two weeks of treatment. The system remained intact until the end of the treatment,
unaffected by the usual complications of such systems, such as serous discharge from the
entry points of the transfixing pins, loosening of the system components, or compromised
bone healing [45].

5. Conclusions

This work highlights the advantages of EF, demonstrating that its minimally invasive
approach and specific characteristics allowed for the successful resolution of a challenging
double fracture in a very small and immature patient. The encountered complications were
minimal, and the patient showed a good quality of life from the early stages of treatment.
Additionally, this type of implant is very cheap, which is useful for its acceptance by
the owners.

In summary, pending further research to support these findings, this study suggests
that EF should be considered a viable technique for stabilising acetabular fractures in
immature cats.

Author Contributions: Conceptualisation, J.A.F., G.L.R. and J.R.-Q.; methodology, G.L.R. and J.R.-Q.;
software, J.A.F.; validation, J.A.F., G.L.R. and J.R.-Q.; formal analysis, J.R.-Q. and G.L.R.; investigation,
J.A.F. and G.L.R.; resources, J.A.F., G.L.R. and J.R.-Q.; data curation, J.A.F. and G.L.R.; writing—
original draft preparation, J.A.F.; writing—review and editing, J.A.F., G.L.R. and J.R.-Q.; visualisation,
J.A.F., G.L.R. and J.R.-Q.; supervision, G.L.R. and J.R.-Q.; project administration, J.R.-Q.; funding
acquisition, J.A.F. All authors have read and agreed to the published version of the manuscript.

Funding: This research was funded by IVC EVIDENSIA.

Institutional Review Board Statement: No applicable.

Informed Consent Statement: Not applicable.

Data Availability Statement: Data are contained within the article.

Conflicts of Interest: The authors declare no conflicts of interest.



Animals 2024, 14, 379 9 of 10

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	Introduction 
	Materials and Methods 
	Preoperative Management 
	Surgical Technique 
	Postoperative Care 
	Follow-Up 

	Results 
	Discussion 
	Conclusions 
	References