The purified OXA-M290 enzyme can now be tested to determine which β-lactamase inhibitor is most effective. This inhibitor could be prescribed in combination with a β-lactam antibiotic to treat the infection caused by the E. coli KGH1 strain.

Before testing inhibitors against OXA-M290, the kinetic activity of this enzyme must first be measured.

The activity of OXA-M290 is measured using nitrocefin, a chromogenic β-lactam antibiotic. When nitrocefin is hydrolyzed by a β-lactamase, it changes from yellow to red in colour. The nitrocefin hydrolysis product has an extinction coefficient of 20,500 M^-1 cm^-1 at 486 nm.

The hydrolysis of 60 μM nitrocefin by 1 nM OXA-M290 is monitored using a microplate reader. The absorbance of the wells in the plate is measured at 486 nm every 30 seconds. This experiment is carried out with three replicates, generating the following data:

Time (min)	Absorbance of Replicate 1	Absorbance of Replicate 2	Absorbance of Replicate 3
0.5	0.0984	0.1368	0.1344
1.0	0.2544	0.2256	0.2448
1.5	0.3432	0.3744	0.3648
2.0	0.504	0.4476	0.4944
2.5	0.6732	0.6504	0.4956
3.0	0.732	0.7032	0.7344
3.5	0.8052	0.7968	0.8412
4.0	0.9144	0.9264	0.8928
4.5	0.9636	1.0104	0.9888
5.0	1.08	0.9852	1.0152
5.5	1.0944	1.0632	1.0848
6.0	1.1064	1.1208	1.0944
6.5	1.1352	1.104	1.1472
7.0	1.1472	1.1328	1.1424
7.5	1.1676	1.1436	1.1568
8.0	1.1712	1.1568	1.1616
8.5	1.1772	1.17	1.1892
9.0	1.2024	1.176	1.1904
9.5	1.2072	1.2168	1.1808
10.0	1.2024	1.2048	1.2024

Average absorbance of the three replicates for each of the 20 time points:

• Time 0.5 min: (0.0984 + 0.1368 + 0.1344) / 3 ≈ 0.1232
• Time 1.0 min: (0.2544 + 0.2256 + 0.2448) / 3 ≈ 0.2416
• Time 1.5 min: (0.3432 + 0.3744 + 0.3648) / 3 ≈ 0.3608
• Time 2.0 min: (0.504 + 0.4476 + 0.4944) / 3 ≈ 0.482
• Time 2.5 min: (0.6732 + 0.6504 + 0.4956) / 3 ≈ 0.6064
• Time 3.0 min: (0.732 + 0.7032 + 0.7344) / 3 ≈ 0.7239
• Time 3.5 min: (0.8052 + 0.7968 + 0.8412) / 3 ≈ 0.8144
• Time 4.0 min: (0.9144 + 0.9264 + 0.8928) / 3 ≈ 0.9112
• Time 4.5 min: (0.9636 + 1.0104 + 0.9888) / 3 ≈ 0.9876
• Time 5.0 min: (1.08 + 0.9852 + 1.0152) / 3 ≈ 1.0261
• Time 5.5 min: (1.0944 + 1.0632 + 1.0848) / 3 ≈ 1.0808
• Time 6.0 min: (1.1064 + 1.1208 + 1.0944) / 3 ≈ 1.1072
• Time 6.5 min: (1.1352 + 1.104 + 1.1472) / 3 ≈ 1.1288
• Time 7.0 min: (1.1472 + 1.1328 + 1.1424) / 3 ≈ 1.1408
• Time 7.5 min: (1.1676 + 1.1436 + 1.1568) / 3 ≈ 1.156
• Time 8.0 min: (1.1712 + 1.1568 + 1.1616) / 3 ≈ 1.1632
• Time 8.5 min: (1.1772 + 1.17 + 1.1892) / 3 ≈ 1.1785
• Time 9.0 min: (1.2024 + 1.176 + 1.1904) / 3 ≈ 1.1896
• Time 9.5 min: (1.2072 + 1.2168 + 1.1808) / 3 ≈ 1.2016
• Time 10.0 min: (1.2024 + 1.2048 + 1.2024) / 3 ≈ 1.2032

Using Beer's law and the average absorbance values calculated in the previous question, what is the concentration of hydrolyzed nitrocefin at each of the 20 time points? Assume that the path length is 1 cm, and use the extinction coefficient provided in Question 1.

Although you can do each calculation manually, it's far easier to use Microsoft Excel to fill in the formula used for this calculation.

Show a sample calculation for the first time point, and make sure to include units in your calculation and your answers. Provide your answers in μM (micromolar) units.