The human body is a system that involves the interplay of different organs to ensure optimal functioning. In the case of complications, an individual experiences discomfort and develop an illness based on the immune’s attempt to fight the infection and pathogen. Therefore, it is crucial to assess the dynamic parts to determine the integral value for effective treatment and recovery (Grässel & Muschter, 2017). One of the prominent factors to consider in the case study is the measure of particular biological procedures causing the dysfunction. It is crucial to indicate the key value of neurologic system due to the its influence on the coordination of muscles.
Over the decades, human activities have exposed individuals towards a significant percentage of heavy lifting, rendering health index risk. The engagements extremely affect the body’s nervous system due to its role as an anchor. Stewart (2017) articulates that the major difference between biomechanical and pathophysiological encompasses the causative agent. Mechanical effect to a person emerges in a situation that one lifts a heavier object than the body’s weight hence causing an imbalance in the distribution system. As a result, the counterpart suffers from the biomechanical condition in the musculoskeletal structure and requires engaging in exercise to enhance effective therapeutic relief.
The physiologic response is a system that enshrines the exposure of a human body to an external and internal force. The divulgence encapsulates three elements, that is, duration, frequency, and magnitude. The outbound energy involves carrying an object, while the inbound potency enshrines the relation between capacity and dosage in phases during the lifting. The interaction between the two facets leads to either adaptation, injury, or healthy outcomes (Everts et al., 2019). Nevertheless, the incorporation of pathogenic infection leads to a distinct outcome among the patients. In the view of the case study, the victim suffers from a pathophysiological process of neurological and musculoskeletal aspects.
The individual suffers from muscular tensions while enjoying dinner time with the wife hence ruling out biomechanical as the causative agent for the sudden illness. However, the patient is a smoker and suffers from hypertension, thus cumulatively causing the insight regarding the pathophysiologic process on neurologic and muscles (Puntilo et al., 2021). In this case, it is vital to establish the essential element that attributes to infection and its effect on the body.
Apart from the smoking habit, the diagnosis indicates that the old man has high blood pressure at a record of 178/94 which is risky at his age. Therefore, it is essential to consider an optimal impact from the increased blood flow pressure within the veins, causing a rupture, thus leading to organ damage and failure (de Sire et al., 2021). The body’s fuel is blood, and a shortage or a rupture of the vessels leads to the deficiency in the supply of oxygen to the organs that fosters the eventual fallout of the highly affected side. Therefore, the 74-year-old male faces a profound challenge during the treatment that involves regulating blood flow and observation for any infectious elements intensifying the condition.
Consequently, the human body is a system whose organs rely on the supply of blood and oxygen. As a result, any disruption in the operation leads to complications and illness. An excellent example is the old man’s case, whose condition emerges from smoking and high blood pressure. Therefore, it is crucial to consider different causative agents to the abrupt sickness despite the indicators approving pathophysiologic processes within the neurological and musculoskeletal elements.
References
de Sire, A., Agostini, F., Lippi, L., Mangone, M., Marchese, S., Cisari, C., Bernetti, A., & Invernizzi, M. (2021). Oxygen–ozone therapy in the rehabilitation field: State of the art on mechanisms of action, safety, and effectiveness in patients with musculoskeletal disorders.Biomolecules, 11(3), 356.
Everts, P. A., Malanga, G. A., Paul, R. V., Rothenberg, J. B., Stephens, N., & Mautner, K. R. (2019). Assessing clinical implications and perspectives of the pathophysiological effects of erythrocytes and plasma free hemoglobin in autologous biologics for use in musculoskeletal regenerative medicine therapies. A review. Regenerative Therapy, 11, 56-64.
Grässel, S., & Muschter, D. (2017). Peripheral nerve fibers and their neurotransmitters in osteoarthritis pathology. International Journal of Molecular Sciences, 18(5), 931.
Puntillo, F., Giglio, M., Paladini, A., Perchiazzi, G., Viswanath, O., Urits, I., Sabba, C., Varrassi, G., & Brienza, N. (2021). Pathophysiology of musculoskeletal pain: a narrative review. Therapeutic Advances in Musculoskeletal Disease, 13, 1759720X21995067.
Stewart, J. (2017). Anatomical chart company atlas of pathophysiology. Lippincott Williams & Wilkins.