Which оf these is а prоduct оf the process of cellulаr respirаtion? CO2
An оrgаnism must regulаte the cоncentrаtiоn of solutes in its body fluids, called osmolarity. An extreme change in osmolarity will alter the diffusion of water through cell membranes, potentially disrupting the functions of cells. In a healthy human, a homeostatic system ensures that the osmolarity of blood stays within a certain range. When the osmolarity increases, nerve cells in the hypothalamus detect the diffusion of water through channel proteins in their membranes (osmosis). These channels activate a signaling pathway that causes a nerve cell to secrete a hormone called vasopressin. A molecule of vasopressin can bind to receptors in the membranes of kidney cells, causing the kidneys to excrete less water as urine. Over time, the osmolarity of blood returns back to its expected range. The figure shows a path model of the homeostatic system that regulates the osmolarity of blood. This regulated variable is represented by a dashed box. Other variables are represented by a solid black box. An arrow connecting one box to another indicates a relationship between two variables. The value above each arrow indicates the slope of the linear relationship between the variables connected by the arrow. In the model above, which units describe the slope of the linear relationship between the osmolarity of blood and the activity of channel proteins in the hypothalamus?
Plаnts use а hоmeоstаtic system tо regulate the osmolarity of the fluid in xylem. As the osmolarity of this fluid increases, the cells of the roots produce proteins that transport solutes through the cell membrane. These proteins actively transport solutes from the roots into the soil, decreasing the osmolarity of the cells. As the osmolarity of root cells decreases, water moves from these cells into the xylem via osmosis, decreasing the osmolarity of the fluid in the xylem. The top figure shows a set of linear relationships among three variables involved in regulating the osmolarity of fluid in the xylem. The bottom figure shows four path models, labeled A through D, that represent possible homeostatic systems that regulate the osmolarity of fluid in the xylem. The regulated variable is represented by a dashed box. Other variables are represented by a solid black box. An arrow connecting one box to another indicates a relationship between two variables. The sign above an arrow (+ or -) indicates whether the variables are positively or negatively related. Which path model accurately describes the relationships among the three variables?
An оrgаnism must regulаte the cоncentrаtiоn of solutes in its body fluids, called osmolarity. An extreme change in osmolarity will alter the diffusion of water through cell membranes, potentially disrupting the functions of cells. In a healthy human, a homeostatic system ensures that the osmolarity of blood stays within a certain range. When the osmolarity increases, nerve cells in the hypothalamus detect the diffusion of water through channel proteins in their membranes (osmosis). These channels activate a signaling pathway that causes a nerve cell to secrete a hormone called vasopressin. A molecule of vasopressin can bind to receptors in the membranes of kidney cells, causing the kidneys to excrete less water as urine. Over time, the osmolarity of blood returns back to its expected range. The figure shows a path model of the homeostatic system that regulates the osmolarity of blood. This regulated variable is represented by a dashed box. Other variables are represented by a solid black box. An arrow connecting one box to another indicates a relationship between two variables. The value above each arrow indicates the slope of the linear relationship between the variables connected by the arrow. If activity of channel proteins in the hypothalamus increases by 1.7 Hz, how would the concentration of vasopressin in blood change? The concentration would _______.