HOW DO WE DIAGNOSE LAMENESS IN YOUR HORSE ?

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Presentation transcript:

HOW DO WE DIAGNOSE LAMENESS IN YOUR HORSE ? To help horse owners better understand the tools we routinely use at VetweRx to evaluate their horse’s soundness, the following section of this website reviews a series of actual cases we have treated. We first discuss your horse’s anatomy, using diagrams and actual limb dissections. We then demonstrate our ability to visualize these structures using digital radiography and ultrasound. Finally we examine some traumatic injuries and developmental abnormalities that you may encounter with your horse. Please note that all of the images were taken on site with our own equipment, and the pathology represents real cases that we have treated. Treatment modalities that we can provide to help your horse are discussed in a separate section of this website – “Treating Your Horse’s Lameness”.

EQUINE STIFLE FORTUNATELY, TIMES HAVE CHANGED !! Author: Martin Butley DVM One of the most complex joints in the body, the stifle has long been a repository for the diagnosis of any cryptic hind end lameness of the horse. If a veterinarian could not pinpoint the cause of an upper hind limb lameness, the stifle was always a safe bet, as it was difficult for the veterinarian to be proven wrong. The stifle was too massive to be easily radiographed in the field. And even if radiographs were available, they were never definitive. There are too many important soft tissue structures like menisci, collateral ligaments and cartilage defects that cannot be visualized with x-rays, but can often be the source of lameness. FORTUNATELY, TIMES HAVE CHANGED !!

STIFLE ANATOMY - orientation

STIFLE ANATOMY - diagram PATELLA This diagram (lateral or side view of the stifle) shows important soft tissue structures not visible on radiographs. It depicts the medial or inside of the stifle, and shows the medial collateral (femoro-tibial) ligament, the medial meniscus, and two of the patetellar ligaments (the horse has three). There are two main joints, the femoropatellar joint shown in orange, and the femorotibial joint shown in blue. The femorotibial joint has medial and lateral compartments that do not communicate in the horse. FEMUR TIBIA

STIFLE ANATOMY - diagram PATELLA This diagram shows the stifle from the front. The three patellar ligaments are shown attached to the patella (proximal, or top of page), wrapping around the trochlear ridges of the femur, shown in blue (the medial trochlear ridge is larger – on left side of diagram) and attaching distally to the tibia. The collateral ligaments are also shown, with the lateral collateral ligament attaching to the head of the fibula. The medial and lateral menisci are shown in yellow. medial lateral Patellar ligaments Collateral ligamens TIBIA FIBULA

STIFLE ANATOMY – gross dissection Patella ARTICULAR SURFACES OF THE FEMOROPATELLAR JOINT fibrocartilage In this dissection, the patellar ligaments have been removed and the patella flipped upwards to reveal the articular (joint) surfaces covered with cartilage. The patella has a fibro-cartilagenous portion that wraps around the medial (larger) trochlear ridge of the femur and aids in locking the stifle in place when the horse is standing. Trochlear Ridges of Femur

STIFLE ANATOMY – gross dissection FEMOROTIBIAL JOINT The femur sits on the flat top of the tibia – the tibial plateau – supported by the two menisci and tied down by the cranial and caudal cruciate ligaments. Femoral Condyles Cruciate Ligament Meniscus Tibial Plateau

STIFLE ANATOMY – gross dissection The cruciates have been severed to allow the femur and tibia to be separated and the two menisci to be shown. Femoral Condyles Medial and Lateral Meniscus Severed cruciate ligaments Tibial Plateau

STIFLE ANATOMY – gross dissection Femoral Condyles The menisci have been removed, exposing the tibial plateau. Tibial Plateau Menisci

STIFLE ANATOMY - radiograph The Equine Stifle corresponds to the human knee. The radiograph at left (credit VetweRx) is a lateral view of the stifle, showing the knee cap, or patella, and the femur. As the leg moves, the patella rides up and down the trochlear ridges of the femur in the Femoropatellar joint. The head of the horse is to the right. PATELLA FEMUR

STIFLE ANATOMY - radiograph Femur Lateral view of the equine Stifle showing the femorotibial joint. The head of the horse is to the right. Radiograph credit VetweRx. Tibia

STIFLE ANATOMY - radiograph Anterior Posterior (front to back) view of the equine stifle (radiograph credit VetweRx). The medial and lateral condyles of the femur rest on the tibial plateau, separated by the menisci – soft tissue structures not visible on radiographs. The fibula is a small bone on the lateral (outside) aspect of the tibia, and is also present in humans. Femur Medial Lateral Tibia Fibula

STIFLE ANATOMY - ultrasound Fibers of Medial Collateral Ligament Ultrasound image of the medial meniscus and the overlying medial collateral ligament in a normal horse. (credit VetweRx) Tibia Femur Ultrasound probe and beam Medial meniscus in cross section

CASE #1 Torn Medial Meniscus Ultrasound image at left (credit VetweRx). Torn meniscus seen at surgery, below. Collateral Ligament Tibia Femur TORN MEDIAL MENISCUS

CASE #2 OCD OF THE TROCHLEAR RIDGE FEMOROPATELLAR JOINT OCD (osteochondritis dissecans) is an abnormality in bone growth (endochondral ossification) affecting young horses. The cartilage is poorly affixed to the underlying bone and is readily pealed away. At left is a large lesion on the medial trochlear ridge of a weanling quarter horse. The cartilage has been removed, showing the abnormal subchondral bone. This photo was taken at necropsy. An ultrasound of this horse’s stifle is shown on the following slide.

CASE #2 OCD OF THE TROCHLEAR RIDGE FEMOROPATELLAR JOINT Cartilage, invisible on radiographs, can be readily seen on ultrasound. Defects in the cartilage and underlying bone are evident in the ultrasound images below (credit VetweRx). CARTILAGE (yellow arrow) OVERLYING BONE Middle Patellar Ligament BONE SURFACE Defect in subchondral bone and overlying cartilage Defect in subchondral bone and overlying cartilage

CASE #3 OCD OF FEMORAL CONDYLE FEMOROTIBIAL JOINT Radiograph of a horse with OCD of the medial femoral condyle on the left (credit VetweRx). OCD lesion seen at surgery, below. OCD lesion FEMUR TIBIA