Finally, no veterinarian would be able to do what we do without our patients and their owners. Recognizing the bond that animals bring to our lives helps inspire all veterinary professionals to do our best. Animals bring out the best in all of us and we certainly don't deserve them, so being able to help them in a time of need is one of the most humbling and wonderful experiences.
David L. Dycus
Disclosures
Matthew D. Barnhart is a paid lecturer for Securos and Everost (Steris) and receives royalties from the sales of some of their products.
Matt Corse is a paid consultant for Arthrex Vet Systems.
David L. Dycus is a paid lecturer for Veterinary Orthopedic Implants.
Ian G. Holsworth is a paid consultant and receives royalties from IMEX Veterinary Inc., Veterinary Instrumentation~Covetrus, Sontec Instruments, VetSurg Surgical instrumentation, and Arthrex Vet Systems.
1 Pathology, Diagnosis, and Treatment Goals of Cranial Cruciate Ligament Rupture and Defining Complications
David L. Dycus, Jeffery Biskup, Michael G. Conzemius and Ron Ben‐Amotz
1.1 Introduction
The cranial cruciate ligament (CCL) is a robust intraarticular, yet extrasynovial structure responsible for preventing stifle hyperextension, excessive internal rotation, and cranial subluxation of the tibia in relation to the femur. It originates from the caudomedial aspect of the lateral femoral condyle, and travels in a craniomedial direction to insert on the cranial intercondyloid region of the tibia [1]. It is composed of two distinct bands: the craniomedial and caudolateral portions. During stifle extension, both the craniomedial and caudolateral bands are taut, while during flexion the craniomedial band remains taut while the caudolateral band becomes lax [2].
Cranial cruciate ligament disease is considered to be the most common cause of pelvic limb lameness in the canine, affecting approximately 2.55% of the population [3, 4]. It is a broad term that encompasses a variety of different pathological disorders that may affect the ligament. For example, in skeletally immature canines, avulsion of the CCL may occur secondary to a traumatic event. In the skeletally mature canine, traumatic rupture occurs less commonly, although it may still be induced by forced hyperextension with internal tibial rotation [5]. The most likely etiology for rupture of the CCL in mature dogs is progressive degeneration of the ligament. This degenerative process likely explains the high incidence of bilateral and contralateral CCL pathology. Contralateral CCL pathology has been documented in over 50% of canines [6]. Complicating the matter is the fact that the exact cause of degeneration is poorly understood. Various factors have been investigated in the etiology and pathogenesis of CCL degeneration. Tibial plateau angle [7], genetics, age, bony confirmation, body weight, gait, and vascularity of the ligament [8–10] have all been identified as risk factors for CCL rupture. To date, none of these factors has proved definitive and as such, the degeneration of the CCL is considered multifactorial.
Regardless of the cause of CCL damage, rupture results in a cascade of events that causes altered kinetics and kinematics of the stifle. It is these altered dynamics that likely lead to progressive osteoarthritis (OA) and increased likelihood of meniscal pathology. Kinematic analysis of the CCL‐deficient stifle has shown that the joint remains in a more flexed position throughout the gait cycle. As a result of the increased stifle flexion, the hip and tarsocrural joints compensate by maintaining a greater degree of extension during the stance phase [11]. Kinetic analysis has revealed decreases in peak vertical force (PVF), vertical impulse, braking, and propulsion impulses in dogs with CCL pathology [12]. For example, the PVF in the normal canine pelvic limb was 70% of static body weight; however, when the CCL was transected, the PVF decreased to 25% of static body weight. This was only improved to 32% and 37% at 6 and 12 weeks post transection respectively [13]. Therefore, this demonstrates continued loss of PVF even after periarticular fibrosis has developed. It could be argued that because of this lack of improvement in kinetic function, surgical stabilization of the cruciate‐deficient stifle should be considered.
Along with altered weight bearing and joint flexion/extension, there is also evidence to suggest that the CCL‐deficient stifle exhibits increased cranial subluxation of the tibia in relation to the femur. Up to 8–12 mm of subluxation has been noted during the stance phase of the gait [14].
Long‐term changes have been evaluated in the canine following CCL transection. Following initial transection of the CCL, there was 10 mm more tibial subluxation compared to patients with an intact CCL. Two months following transection, tibial subluxation was noted only during the stance phase and not during the late swing/early stance phase (paw strike). Two years following transection, 5 mm of tibial thrust was noted at the end of the swing phase. It was suggested that the reason for these changes was the presence of an intact medial meniscus. It was theorized that in the CCL‐deficient stifle, the meniscus minimizes tibial subluxation by elastically deforming during tibial subluxation and aiding in reduction of the subluxation once the swing phase begins (alternatively, as the load from the stance phase is removed) [15]. Interestingly, tibial subluxation as the result of instability has been called into question as it demonstrated that instability following CCL rupture is actually a caudal slippage of the femur at the beginning of the stance phase. As such, documented continuation of instability in some stifles exists following common osteotomy procedures such as the tibial plateau leveling osteotomy (TPLO) and tibial tuberosity advancement (TTA) [16].
In addition to controlling sagittal joint motion of the stifle, the CCL also aids in limiting internal rotation. To date, no osteotomy modifying procedures effectively eliminate excessive internal rotation. Initially, this was thought to play a minimal role in the CCL‐deficient stifle. While significant changes in internal rotation were not noted immediately following transection of the CCL, 2 months following transection the range of abduction and adduction in the stifle was increased. These rotary changes remained increased 2 years following tran section [15]. Recognition of the importance of preventing excessive internal rotation has led to the idea and development of augmentation to prevent excessive internal rotation following certain osteotomy procedures such as the TPLO (Figure 1.1).
Interestingly, a population of CCL‐deficient canines will exhibit persistent internal rotation following surgical stabilization. This persistent internal rotation likely falls under the umbrella term of “pivot shift.” Unfortunately, to date, it is not possible to predict which population of patients will exhibit persistent internal rotation following surgical stabilization. In the authors' opinion, patients with acute CCL rupture, large medial meniscal bucket handle tears, and lack of periarticular fibrosis tend to have persistent internal rotation following