3. Equilibrium
Insulin resistance occurs when cells no longer bind insulin in a normal manner, thus inhibiting the cells from transporting glucose inside the cell. Without intercellular glucose the cells cannot produce energy to support life.
Letâs suppose part of your project requires you to study the equilibrium reaction between the new variation of insulin you synthesized and cell receptors on the walls of cells. This is the equilibrium expression you propose.
cell receptor + free insulin cell receptor-insulin complex
or in abbreviated terms
R + I R-I
You devise a method of measuring the free insulin in solution. You run two experiments under the same conditions, except one experiment uses your modified insulin and the other experiment uses normal insulin. Table 1 below provides the initial conditions of your experiment and Table 2 provides the data you collected after equilibrium was established.
Initial Conditions for both experiments â all environmental conditions are kept constant (e.g. temperature at 34oC, pressure at 1 atm, pH at 7.4). A single stock nutrient and cell receptor solution was prepared with a concentration of 70 uM. 50 mL the solution was used in all experiments. The insulins were added as powders, so the volumes essentially remained unchanged.
Table 1: Initial Experimental Conditions
Experiment 1
Experiment Control
[free modified insulin] = 100.0 uM
[free normal insulin] = 100.0 uM
[cell receptor] = 70.0 uM
[cell receptor] = 70.0 uM
Table 2: Unbound Free Modified Insulin and Unbound Free Normal Insulin Levels at Equilibrium
Experiment 1
Experimental Control
[free modified insulin] = 35.0 uM
[free normal insulin] = 50.0 uM
Write the equilibrium expression for this reaction using [I] to represent the insulin concentration, [R] the cell receptor concentration, and [I-R] to represent the cell receptor-insulin complex concentration. (10 pts) Show all work.
Determine an equilibrium constant for both the modified insulin and the normal insulin reaction at 34oC based on the data above. (10 pts)
[free modified insulin]
[receptor]
[Insulin-receptor]
I
C
E
[free normal insulin]
[receptor]
[Insulin-receptor]
I
C
E
Which type of insulin binds more strongly to the cell receptor? Explain your answer. (10 pts)
Suppose the concentration of the receptor in the stock solution dropped to 50.0 uM. If you ran the experiment again with the same initial concentration of free modified insulin as above, what would you expect the free modified insulinâs equilibrium concentration to be? (10 pts)
[free modified insulin]
[receptor]
[Insulin-receptor]
I
C
E
Can someone please help me with this? I dont understand what to fill in the ice tables.
3. Equilibrium
Insulin resistance occurs when cells no longer bind insulin in a normal manner, thus inhibiting the cells from transporting glucose inside the cell. Without intercellular glucose the cells cannot produce energy to support life.
Letâs suppose part of your project requires you to study the equilibrium reaction between the new variation of insulin you synthesized and cell receptors on the walls of cells. This is the equilibrium expression you propose.
cell receptor + free insulin cell receptor-insulin complex
or in abbreviated terms
R + I R-I
You devise a method of measuring the free insulin in solution. You run two experiments under the same conditions, except one experiment uses your modified insulin and the other experiment uses normal insulin. Table 1 below provides the initial conditions of your experiment and Table 2 provides the data you collected after equilibrium was established.
Initial Conditions for both experiments â all environmental conditions are kept constant (e.g. temperature at 34oC, pressure at 1 atm, pH at 7.4). A single stock nutrient and cell receptor solution was prepared with a concentration of 70 uM. 50 mL the solution was used in all experiments. The insulins were added as powders, so the volumes essentially remained unchanged.
Table 1: Initial Experimental Conditions
| Experiment 1 | Experiment Control |
| [free modified insulin] = 100.0 uM | [free normal insulin] = 100.0 uM |
| [cell receptor] = 70.0 uM | [cell receptor] = 70.0 uM |
Table 2: Unbound Free Modified Insulin and Unbound Free Normal Insulin Levels at Equilibrium
| Experiment 1 | Experimental Control |
| [free modified insulin] = 35.0 uM | [free normal insulin] = 50.0 uM |
Write the equilibrium expression for this reaction using [I] to represent the insulin concentration, [R] the cell receptor concentration, and [I-R] to represent the cell receptor-insulin complex concentration. (10 pts) Show all work.
Determine an equilibrium constant for both the modified insulin and the normal insulin reaction at 34oC based on the data above. (10 pts)
| [free modified insulin] | [receptor] | [Insulin-receptor] | |
| I | |||
| C | |||
| E |
| [free normal insulin] | [receptor] | [Insulin-receptor] | |
| I | |||
| C | |||
| E |
Which type of insulin binds more strongly to the cell receptor? Explain your answer. (10 pts)
Suppose the concentration of the receptor in the stock solution dropped to 50.0 uM. If you ran the experiment again with the same initial concentration of free modified insulin as above, what would you expect the free modified insulinâs equilibrium concentration to be? (10 pts)
| [free modified insulin] | [receptor] | [Insulin-receptor] | |
| I | |||
| C | |||
| E |
Can someone please help me with this? I dont understand what to fill in the ice tables.
