Musculoskeletal Disorders. Sean Gallagher

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Local damage (microcracks) of the osteoid matrix can compromise the osteocyte environment, disrupting the fluid flow, consequently reducing nutrients and oxygen supply to the embedded cells and creating oxidative stress (Al‐Dujaili et al., 2011).

       Osteoclasts—reallocate and remodel bone

      Osteoclasts differentiate after the fusion of bone marrow‐derived mononuclear precursor cells of the monocyte–macrophage lineage in a process termed osteoclastogenesis. Osteoclasts are large multinucleated cells with a ruffled bottom in contact with the bone matrix (Figure 3.17d). They work in concert with osteoblasts in the constant turnover and remodeling of bone. They do this via their ability to secrete hydrochloric acid and other degradative enzymes, which, once activated, dissolve the bone matrix, creating a resorption pit underneath the cell. Osteoclasts are regulated by parathyroid hormone, calcitonin (from the thyroid gland), and pro‐inflammatory cytokines (Boyce & Xing, 2007; Brabnikova Maresova, Pavelka, & Stepan, 2013; Nakashima & Takayanagi, 2011). As mentioned earlier, osteoclast activation is also mediated by the binding of osteoblast or osteocyte produced RANKL (a protein that plays an essential role in the recruitment, differentiation, activation, and survival of osteoclasts) (Burgess et al., 1999). Estrogen has a dual effect: Its presence increases bone formation and reduces bone resorption by enhancing osteoblast proliferation and function (Ernst, Heath, & Rodan, 1989; Majeska, Ryaby, & Einhorn, 1994); it also reduces bone turnover by reducing osteoclast activity (Hofbauer et al., 1999).

      Extracellular matrix

      Organization

      Bone tissue can also be classified by texture, matrix arrangement, maturity, or developmental origin (Yang, 2010). There are two main subtypes of bone: cortical and trabecular bone. Both types are chemically identical, but differ in terms of their structure, arrangement, and cell density. Approximately 80% of bone is cortical bone, with the remainder as trabecular bone (Carter & Hayes, 1977).

      Trabecular bone (also known as cancellous or spongy bone) has numerous cavities (Figure 3.18). It is found mainly at the ends of many long bones and in areas like the ears and nose (Cooper, Milgram, & Robinson, 1966). Individual trabeculae are extensively connected and are oriented along the lines of mechanical stress on the bone in question. Trabecular bone is more metabolically active than cortical bone because of its much larger surface area for remodeling.

      Lamellar bone is mature bone in which collagen fibers are arranged in parallel. It is located in both trabecular bone and cortical bone, the latter concentrically organized around a vascular canal.

Photos depict the organization of long bones. Photos depict osteons in cortical bone.

      Bone Function

      Bones serve numerous functions in the human body. Bones provide strength and structural stability to the body and provide a means by which loads can be transferred from one part of the body to another. Biomechanically, they are critical structures in that they provide levers and points of attachment for tendons (driven by muscle contraction) that are essential in permitting movement of the human body. Bones also play an important structural protective role for important organs of the body (most notably as the skull around the brain and the rib cage around the heart and lungs).

      However, there is much more to bone than its structural and protective roles. Bones themselves are living dynamic

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