ABSTRACT
Prolonged imbalance between input and output of any element in a living organism is incompatible with life. The duration of imbalance varies, but eventually balance is achieved. This rule applies to any quantifiable element in a compartment of finite capacity. Transient discrepancies occur regularly, but given sufficient time, balance is always achieved, because permanent imbalance is impossible, and the mechanism for eventual restoration of balance is foolproof. The kidney is a central player for balance restoration of fluid and electrolytes, but the smartness of the kidney is not the reason for perfect balance. The kidney merely accelerates the process. The most crucial element of the control system is that discrepancy between intake and output inevitably leads to a change in total content of the element in the system, and uncorrected balance has a cumulative effect on the overall content of the element. In a living organism, the speed of restoration of balance depends on the permissible duration of imbalance without death or severe disability. The three main factors that influence the speed of balance restoration are: magnitude of flux, basal store, and capacity for additional storage. For most electrolytes, total capacity is such that a substantial discrepancy is not possible for more than a week or two. Most control mechanisms correct abnormality partially. The infinite gain control mechanism is unique in that abnormality is completely corrected upon completion of compensation.
Subject(s)
Acid-Base Equilibrium , Body Composition , Compensation and Redress , Electrolytes , KidneyABSTRACT
Estudaram-se as alterações nos eletrólitos, nos gases sanguíneos, na osmolalidade, no hematócrito, na hemoglobina, nas bases tituláveis e no anion gap no sangue venoso de 11 equinos da raça Puro Sangue Árabe, destreinados, submetidos a exercício máximo e submáximo em esteira rolante. Esses animais passaram por período de três dias de adaptação à esteira rolante e posteriormente realizaram dois exercícios testes, um de curta e outro de longa duração. Foram coletadas amostras de sangue venoso antes, imediatamente após e 30 minutos após o término dos exercícios. Após a realização do exercício máximo, observou-se diminuição significativa no pHv, na PvCO2, no HCO3, na cBase além de elevação no AG. Detectou-se também aumento do K+, do Ht e da Hb. Ao final do exercício submáximo, constatou-se somente aumento significativo no pHv, na cBase, na SatvO2 e na PvO2. Conclui-se que os equinos submetidos a exercício máximo desenvolveram acidose metabólica e alcalose respiratória compensatória, hipercalemia e aumento nos valores de hematócrito e hemoglobina. No exercício submáximo, os animais apresentaram alcalose metabólica hipoclorêmica e não ocorreram alterações no equilíbrio hidroeletrolítico.
Changes in electrolytes, blood gas, osmolality, hematocrit, hemoglobin, base concentration, and anion gap in 11 detrained Arabian horses during exercise on a high-speed treadmill were investigated. After a period of three days of adaptation on the rolling mat, the animals were submitted to two exercises: one of short (maximum) and other of long duration (submaximum). Venous blood samples were obtained right before, and 30 minutes after the exercise. After the maximum exercise, it was observed a significative decrease in pHv, PvCO2, HCO3, and cBase and an increase in AG. It was also observed hypercalemia and increase in Ht and Hb. At the final of the submaximum exercise, it was observed significative increase in pH, cBase, SatvO2, and PvO2. So, maximum exercises can lead equines to present metabolic acidosis with respiratory alkalosis as response, hypercalemia and increase in hematocrit and hemoglobin, values. Submaximum exercises can present hypochloremic metabolic alkalosis but no alterations in the hydroelectrolitic balance.