Chapter 10, Problem 01 Calculate the free energy change for glucose entry into cells when the...
Chapter 10, Problem 04 Calculate the free energy required to move 1 mol of K+ ions from the outside of the cell (where [K+] = 3.2 mm) to the inside (where [K+] = 147 mM) when the membrane potential is -77 mV and the temperature is 37.6°C. Give your answer in kJ/mol. kJ/mol the tolerance is +/-2%
Chapter 10, Problem 04 Calculate the free energy required to move 1 mol of K+ ions from the outside of the cell (where [K+] = 3.1 mm) to the inside (where [K+] = 134 mm) when the membrane potential is -77 mV and the temperature is 34.3°C. Give your answer in kJ/mol.
please show the work. thanks What is the free energy change for the transport of calcium ions into a cell. The intracellular [Ca2+] is 1 mM and extracellular [Ca2+] is 1 uM. Assume a membrane potential of -100 mV and T-25°C. Give your answer in kJ/mol to one decimal place.
5. What is the free energy change in transporting an uncharged molecule across the membrane of a cell from 10 M to 10 M? Is an input of free energy required for this transport? (5 points) 6. What is the free energy cost of pumping Ca out of a cell when the cytoplasmic concentration is 0.9 uM, the extracellular concentration is 1.5 mM, and the membrane potential is -70mV at a temperature of 25°C? What is the free energy cost...
The ΔG°′ for the conversion of glucose-1-phosphate (G1P) to glucose-6-phosphate is -7.1 kJ/mol. What is the ratio of the concentration of G6P to the concentration of G1P that provides a free energy change of –2.0 kJ · mol–1 at 37°C. [Express your answer in decimal form using 2 significant figures.]
1. Animal cells have a Na,K pump that couples the energy of ATP hydrolysis to transport 3 Na ions out of the cell and 2 K ions into the cell. Inside astrocytes, the concentration of Na is 20 mM and the concentration of K is 130 mM. The extracellular concentrations of Na and K are 145 mM and 5 mM, respectively. Calculate the energy required for the transport of Na and K , with this stoichiometry; assume that the cell...
CHEM 351 Biochemistry I - Fall 2018 Study Problems for Metabolism and Glucose Catabolism For the reaction: aA + bB =cC + dD Gibbs free energy: AG = AG" + RT IN THE glucose + glucose 6-phosphate + H20 1. The equilibrium constant for phosphorylation of glucose is: Ke = 3.97 x 10- a. Calculate the standard Gibbs free energy for the uncatalyzed reaction. b. Use the physiological concentrations for glucose (2.0 mm) and inorganic phosphate (20 mM) to determine...
In dog skeletal muscle, the extracellular and intracellular concentration of Na+ are 150 mM and 12 mM, and those of K+ are 2.7 mM and 140 mM, respectively. Calculate the total free energy change as 3 Na+ are transported out and 2 K+ are transported in by the Na+-K+ pump. Assume that the temperature is 25°C and the membrane potential is –60 mV. Give your answer in kJ/mol to 1 decimal place.
<Chapter 6 Required HW Assignment Problem 6.83 - Enhanced - with Feedback Calculate the energy change (in kilojoules per mole) for the formation of the following substances from their elements. 9 of 12 > Review Constants Periodic Table Part A LiF(s) [The sublimation energy for Li(s) is +159.4 kJ/mol. E; for Li(g) is 520 kJ/mol. E for F(g) is 328 kJ/mol, the bond dissociation energy of F2 (g) is +158 kJ/mol, and the lattice energy of Lif(s) is 1036 kJ/mol]...
Consider the following isomerization reactions of some simple sugars and values for their standard Gibbs free energy ΔG∘: reaction A:reaction B:glucose-1-phosphatefructose-6-phosphate⟶⟶glucose-6-phosphate,glucose-6-phosphate, ΔG∘=−7.28 kJ/mol ΔG∘=−1.67 kJ/mol Part A Calculate ΔG∘ for the isomerization of glucose-1-phosphate to fructose-6-phosphate. ΔG∘ = -5.61 kJ/mol Part B Calculate the equilibrium constant K for the isomerization of glucose-1-phosphate to fructose-6-phosphate at 298 K. Express your answer numerically using two significant figures. K = 9.6 Part C Calculate ΔG when the concentration of glucose-1-phosphate is 10 times greater than the concentration...