Buffers can be used to evaluate compounds at specific pH values. In this section, you will record the absorbance spectrum of the indicator neutral red in various buffers. The protonated form of neutral red is red, and the deprotonated form is yellow-orange, meaning that they absorb green and blue-violet light, respectively. Thus, the acidic and basic forms have distinct absorption wavelengths. Protein binding alters the properties of neutral red, changing both its absorbance and its pKa.
After measuring the absorbance spectrum of free neutral red at several pH values, you will add riboflavin-binding protein, or RP, to the solutions and measure the absorbances again. Absorbance intensity is related to concentration, so you will use the spectra to determine the pKa of free and bound neutral red after the lab.
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Draw the following table in your lab notebook. Number the cuvettes 1 through 10 and list the nine buffer pH values that you will use. The 10th cuvette will be a deionized water blank.
Note: Always hold cuvettes by the textured sides and wipe the transparent sides just before putting the cuvette in the spectrophotometer. Remember to align the transparent sides with the beam of light in the spectrophotometer.
Table 2: Absorbance of Free and Bound Neutral Red
| Cuvette # |
Buffer pH |
Abs. at λmax (Free NRH+) |
Abs. at λmax (Bound NRH) |
| 1 |
5.0 |
|
|
| 2 |
5.5 |
|
|
| 3 |
6.0 |
|
|
| 4 |
6.5 |
|
|
| 5 |
7.0 |
|
|
| 6 |
7.5 |
|
|
| 7 |
8.0 |
|
|
| 8 |
8.5 |
|
|
| 9 |
11 |
|
|
| 10 |
blank |
|
|
Click Here to download Table 2
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Obtain ten 1.5-mL cuvettes and caps and label the caps 1 through 10 to match the table in your lab notebook.
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Label a 25-mL beaker as ‘DIH2O’ and fill it with deionized water.
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Flush your neutral aqueous waste down the drain and relabel the beaker as 'aqueous buffer waste'.
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Label a 400-mL beaker for used micropipette tips.
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Attach a tip to a 1-mL micropipette and use it to dispense 1000 µL of deionized water into cuvette 10. This is your solvent blank.
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Place 925 µL of your pH 7.0 monosodium phosphate buffer in cuvette 5.
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Bring the remaining empty cuvettes to the buffer table. Guided by the table in your lab notebook, dispense 925 µL of each buffer into the appropriate cuvette using the labeled micropipettes. Be careful not to use the same pipette tip for different buffers.
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Once you have finished, bring the buffers back to your workbench. There, set a 200-µL micropipette to dispense 75 µL, and attach a tip to the micropipette.
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Dispense 75 µL of neutral red into each of the nine buffer cuvettes. Invert each cuvette several times to thoroughly mix the solutions. Note: Replace the pipette tip if it touches a buffer.
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Once you have mixed neutral red with every buffer, take a picture, or write down the colors of the solutions.
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Turn on a hand-held spectrophotometer and allow the light source to warm up. Once it is ready, create a new experiment to measure absorbance versus wavelength for the free neutral red.
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Insert the cuvette of deionized water and acquire a spectrum of the deionized water. Set it as a solvent background or blank.
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Then, remove the blank and insert the cuvette of neutral red in the lowest pH buffer, which will have the highest concentration of protonated neutral red.
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Acquire a spectrum, which should show one strong peak. Identify the wavelength corresponding to the highest point of this peak, or the maximum. Record this wavelength in your lab notebook as lambda max for protonated free neutral red.
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Save the data and remove the cuvette. Record the absorbance in your notebook, then collect spectra for cuvettes 2 – 9 using the same procedure.
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Record the wavelength of the isosbestic point in your lab notebook. That is where all the spectra cross at a single wavelength. If a spectrum does not cross at that point, empty and clean the cuvette, prepare a fresh sample, and try again.
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Once you finish collecting spectra for all nine cuvettes, save and export the data.
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Create a new experiment to measure absorbance versus wavelength for the bound neutral red.
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Fit a new tip to the 200-µL micropipette and add 75 µL of riboflavin-binding protein solution to each cuvette, including the blank. Eject the tip, secure the cuvette caps, and invert the cuvette several times to mix the solutions.
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Insert cuvette 10 into the spectrophotometer and set it as the solvent blank.
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Acquire a spectrum of the lowest pH sample, and identify the wavelength corresponding to the maximum of the most intense peak. Record it in your lab notebook as the lambda max of protonated-bound neutral red.
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Acquire spectra for cuvettes 2 – 9 in the same way as you did for the free neutral red samples. Record the intensities at lambda max for protonated-bound neutral red in your table, along with the wavelength at the isosbestic point.
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When you are done, save your data, export it for later analysis, and shut down the spectrophotometer.
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Put away all equipment and dispose of your used pipette tips in an approved waste container or trash bin.
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Empty the cuvettes into the aqueous buffer waste beaker and rinse the cuvettes into the beaker with deionized water.
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Empty the excess NaOH into the basic waste and rinse the graduated cylinder with water.
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Flush the basic aqueous waste down the drain with copious tap water, along with the other aqueous waste.
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Wash your glassware, cuvette caps, and stir bar per your lab standard procedures. Clean your work surfaces with a damp paper towel and throw out used paper towels and lab wipes in the lab trash.
