hypotonic to both fresh water and the salt solution

hypertonic to both fresh water and the salt solution

hypertonic to fresh water but hypotonic to the salt solution

hypotonic to fresh water but hypertonic to the salt solution

isotonic with fresh water but hypotonic to the salt solution

Water will leave the cells, causing them to shrivel and collapse.

NaCl will be exported from the red blood cells by facilitated diffusion.

The blood cells will take up water, swell, and eventually burst.

NaCl will passively diffuse into the red blood cells.

The blood cells will expend ATP for active transport of NaCl into the cytoplasm.

side A is hypertonic to side B.

side A is hypotonic to side B.

side A is isotonic to side B.

side A is hypertonic to side B with respect to glucose.

side A is hypotonic to side B with respect to sodium chloride.

a decrease in the concentration of NaCl and glucose and an increase in the water level.

a decrease in the concentration of NaCl, an increase in water level, and no change in the concentration of glucose.

no net change in the system.

a decrease in the concentration of NaCl and a decrease in the water level.

no change in the concentration of NaCl and glucose and an increase in the water level.

It will have no unfavorable effect as long as the water is free of viruses and bacteria.

The patient's red blood cells will shrivel up because the blood fluid has become hypotonic compared to the cells.

The patient's red blood cells will swell because the blood fluid has become hypotonic compared to the cells.

The patient's red blood cells will shrivel up because the blood fluid has become hypertonic compared to the cells.

The patient's red blood cells will burst because the blood fluid has become hypertonic compared to the cells.

decreasing extracellular sucrose concentration

decreasing extracellular pH by allowing more H+ to leave the cell

decreasing cytoplasmic pH by pumping more H+ ions into the cell

adding an inhibitor that blocks the regeneration of ATP

adding a substance that makes the membrane more permeable to hydrogen ions

The hydrolysis of ATP by the Sucrose-H+ cotransporter pumps sucrose against its concentration gradient.

Sucrose flows through the cotransporter via facilitated diffusion.

The sucrose is pushed through the cotransporter by the water potential outside the cell.

The cotransporter harnesses energy from allowing H+ ions to flow down their electrochemical gradient.