Fractures in the Horse. Группа авторов

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Fractures in the Horse - Группа авторов


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       C.E. Kawcak

       Veterinary Teaching Hospital, Colorado State University, Fort Collings, CO, USA

      Bone has a well‐organized architecture of mineral, organic matrix and cells that has developed and adapted for mechanical efficiency and dynamic response to change in loading. The aim of ‘scarless healing’ is to restore this organizational paradigm in order to optimize use: fortunately, bone has the capacity to fulfil this goal. Nonetheless, optimizing fracture healing in the horse presents many challenges, including the size and behavioural nature of the animal, the location and configuration of the fracture, the amount of soft tissue damage and the ultimate stability of the fracture and/or its repair. These features, in turn, affect the mechanical and physiological environments of the injury, which are the two factors with the greatest influence on healing. This chapter discusses the interactions of physiological and mechanical factors in bone healing together with the influence of stability on cellular function and pain and the influence of pain on cellular events. It describes molecular, cellular, tissue‐ and organ‐based factors significant to fracture healing in order to identify those processes that can optimize repair and those that can lead to derangements in healing. Finally, current evidence for the use of exogenous physical, pharmacological and biological techniques is reviewed.

      Fracture healing is principally influenced by its nature, i.e. location, configuration, etc., and by its stability. The classic fracture types are characterized in Chapter 3. From a perspective of stability, the fracture classification has significance. Fractures occur either in normal bone that fails due to a catastrophic force (monotonic fractures) or in pathologic bone that fails from sub‐catastrophic forces (fatigue fractures). Monotonic fractures are acute in nature and caused by a force that overloads the material properties of the bone. These fractures are often in multiple pieces (comminuted) and accompanied by significant soft tissue and vascular damage. The fracture configuration is usually unpredictable. Instability can be significant, often requiring invasive repair techniques to restore mechanical support. Fatigue (stress) fractures are consistent in location and configuration and result at the end of a cumulative pathologic process in which coalescence of osteoclastic resorption of bone remodelling and/or microdamage produce a clinical fracture [1]. These can be minor or catastrophic, depending on the amount of energy accumulated at the time of bone failure, and resulting fracture configurations can be consistent or variable respectively. Incomplete fractures are usually stable since the fracture does not break out from a secondary site [1]. However, they can become complete without immediate coaptation and attention. Complete fracture can be displaced or non‐displaced; the latter being more stable [1]. Comminuted fractures are complex and can be composed of multiple pieces often with significant soft tissue and vascular damage, compromising both mechanical and physiological factors that favour healing [1]. Fracture configuration greatly influences the mechanical and physiological environments, which is reflected by the variable prognosis given for each type of configuration. The quality of fracture healing depends on a sensitive balance of physiological and mechanical factors that function in parallel through the healing phases to regenerate tissue. The mechanical environment can have a significant effect on physiologic response and vice versa.


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