Blood oxygenators leukocyte

Bone marrow is the spongy tissue inside the cavities of our bones. Bone marrow stem cells grow and divide into the various types of blood cells white blood cells (leukocytes) that fight infection, red blood cells (erythrocytes) that transport oxygen, and platelets that are the agents for clotting. 

The fluid that circulates in the vascular system of vertebrate animals, carrying nourishment and oxygen to all parts of the body and taking away waste products for excretion. Blood consists of liquid plasma containing dissolved nutrients, waste products, and other substances and Suspended red blood cells, leukocytes, and blood platelets. 

Thus, the mechanism of MT antioxidant activity might be connected with the possible antioxidant effect of zinc. Zinc is a nontransition metal and therefore, its participation in redox processes is not really expected. The simplest mechanism of zinc antioxidant activity is the competition with transition metal ions capable of initiating free radical-mediated processes. For example, it has recently been shown [342] that zinc inhibited copper- and iron-initiated liposomal peroxidation but had no effect on peroxidative processes initiated by free radicals and peroxynitrite. These findings contradict the earlier results obtained by Coassin et al. [343] who found no inhibitory effects of zinc on microsomal lipid peroxidation in contrast to the inhibitory effects of manganese and cobalt. Yeomans et al. [344] showed that the zinc-histidine complex is able to inhibit copper-induced LDL oxidation, but the antioxidant effect of this complex obviously depended on histidine and not zinc because zinc sulfate was ineffective. We proposed another mode of possible antioxidant effect of zinc [345], It has been found that Zn and Mg aspartates inhibited oxygen radical production by xanthine oxidase, NADPH oxidase, and human blood leukocytes. The antioxidant effect of these salts supposedly was a consequence of the acceleration of spontaneous superoxide dismutation due to increasing medium acidity. 

Thus, oxygen radical production by leukocytes can be responsible for cancer development. However, the levels of leukocyte oxygen radical generation depend on the type of cancer. For example, PMNs and monocytes from peripheral blood of patients with lung cancer produced a diminished amount of superoxide [169], Timoshenko et al. [170] observed the reduction of superoxide production in bronchial carcinoma patients after the incubation of neutrophils with concanavalin A or human lectin, while neutrophils from breast cancer patients exhibited no change in their activity. Chemotherapy of lung and colorectal carcinoma patients also reduced neutrophil superoxide production. Human ALL and AML cells produced, as a rule, the diminished amounts of superoxide in response to PMA or FMLP [171], On the other hand total SOD activity was enhanced in AML cells but diminished in ALL cells, while MnSOD in AML cells was very low. It has been proposed that decreased superoxide production may be responsible for susceptibility to infections in cancer patients. 

The formed elements of blood are red blood cells, platelets, and leukocytes. Red blood cells, or erythrocytes (Figure 9.2), are flexible biconcave disk-shaped bodies whose main function is to carry oxygen to tissue bound to the hemoglobin that they contain. They are generated in the marrow of various bones by the action of stem cells. The hormone erythropoietin stimulates erythrocyte production in response to tissue needs for oxygen. Marrow stem cells also produce platelets, tiny cell fragments that contain the biochemicals necessary for blood clotting. The third kind of formed elements consists of leukocytes, which are defensive white blood cells. 

The primary functions of the blood may be considered in a broad sense to be the following (1) metabolic regulation—transport of oxygen, carbon dioxide, metabolites, hormones (2) physical and chemical regulation—temperature, acid-base balance, and osmotic pressure and fluid balance and (3) regulation of body defenses—protection against infection by the action of antibodies, leukocytes, and other mechanisms and prevention of hemorrhage. 

Leukemia begins in the bone marrow and spreads through the lymph and blood system to tissues, organs, and sometimes testicles, brain, and spinal fluid. Leukocytes normally attack, kill, and help to expel invading microbes, but the leukocytes of patients with leukemia are abnormally shaped, increased in number, and immature of development (termed lymphoblasts). As the lymphoblasts multiply and spread, they outnumber and overwhelm the erythrocytes that transport oxygen and carbon dioxide in opposite directions, and hamper the function of platelets (thrombocytes), which help blood to clot. 

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