In the lung’s alveolar capillaries, E-1173 experienced a transformation. It rolled to a stop, flattened against a thin endothelial wall. On the other side was a puff of inhaled air (partial pressure of O₂ ~100 mmHg). The air’s oxygen molecules, driven by the simple physics of , passed through the alveolar membrane, through the plasma, and into E-1173. There, oxygen bound cooperatively to the four heme groups of its hemoglobin. E-1173 turned from a dull maroon to a brilliant scarlet. It had been oxygenated . In return, it unloaded the waste product carbon dioxide (as bicarbonate, thanks to the enzyme carbonic anhydrase in its cytoplasm) back into the alveolus to be exhaled. The law of mass action was served.
E-1173’s first challenge was to leave the marrow. It squeezed, deforming its flexible membrane (a property called ) through a tiny pore in the sinusoidal wall. It was now adrift in a raging river: the venous bloodstream. The current was driven by the right ventricle of the heart, a four-chambered marvel of hemodynamics . E-1173 was swept through the vena cava, into the right atrium, through the tricuspid valve, and into the right ventricle. With a coordinated electrical impulse from the sinoatrial node—a cardiac action potential —the ventricle contracted. Lub . E-1173 was shot through the pulmonary artery toward the lungs. fundamentals of medical physiology
As E-1173 made its return journey, now a tired, deoxygenated blue, it entered the renal circulation. The kidney was a master of . Blood pressure forced plasma through the glomerulus, but E-1173 was too large to pass. It tumbled through the vasa recta, past the loop of Henle, where countercurrent multiplication was busy concentrating urine. Suddenly, the vessel ruptured. A microscopic tear in the arteriole wall. In the lung’s alveolar capillaries, E-1173 experienced a