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Michel Lotito (6/15/50-6/25/07) Monsieur Mangetout “Mr. Eat-Everything” Homeostatic Connections To pH • Carbon dioxide sensors in carotid artery measure blood pH and tell brain when to signal lungs to breathe • Absorption and digestion require specific pH • pH may prohibit parasitic infections • Changes in pH may alter or destroy enzymes How Is pH Maintained? • Body is slightly alkaline, but ranges from pH 2 to pH 11 in matter of centimeters • Excess hydronium and hydroxide ions must be neutralized • BUFFERS resist changes in pH What Are Buffers And How Do They Work? • Substances that resist changes in pH • Buffers are themselves weak acids and/or bases • These weak acids and/or bases disassociate in solution, neutralizing the excess hydronium (H+)or hydroxide (OH-) ions • As the excess H+ and OH- ions are no longer “free”, their concentration does not effectively increase; pH stays the same PURPOSE • To evaluate and compare the relative buffering capacity of seven organic and inorganic substances through calculation of ΔpH (change in pH) Seven Potential Buffers Albumin Casein Magnesium Hydroxide Sodium Bicarbonate Sodium Chloride Sodium Stearate Water Albumin • Protein found in egg whites • Comprised of amino acids which have a positive and negative functional groups Casein • Protein found in mammalian milk • Contains a water repelling core and polar/charged tails Magnesium Hydroxide • Active ingredient in Milk of Magnesia • An strong electrolyte, meaning rapid disassociation into ions Sodium Bicarbonate • Baking soda • Disassociates into two charged ions, sodium (+) and bicarbonate (-) Sodium Chloride • Table Salt • Inorganic substance with weak ionic bonding Sodium Stearate • Key ingredient of soap • Found in non-polar fats and oils Water • Amphoteric = may serve as an acid or a base when in solution • Neutral pH Buffering Capacity Protocol 1. Place 25mL of your first buffer into each of two beakers 2. Remove storage bottles from pH probes and immerse tip of probe in beaker. Record the initial pH in table 2 3. To the left beaker, add 5 drops 0.1M HCl 4. To the right beaker, 5 drops 0.1M NaOH 5. Record the pH for each probe in table 2 6. Repeat steps 3-5 until a total of 30 drops of acid and base have been added to their Protocol Part 2 • Discard the water-acid and water-base mixtures from the first experiment and rinse the beakers • Obtain 25mL of the next assigned buffer for each of the two beakers • Repeat the first protocol up to 30 drops of acid & base respectively, recording the pH values in table 1 • Calculate the ΔpH , ΔpH and ΔpH • Post your data on the board in the front of the room acid base total Calculating Buffering Capacity • To calculate ΔpHacid and ΔpHbase for a buffer, find the absolute value of the difference between the initial (0 drops) and final (30 drops) values for both probes. Record these values in table 1. • To determine and then rank the buffering capacities, calculate the ΔpHtotal by adding the ΔpHacid and ΔpHbase . Record these values in table 1. • For water’s buffering capacity, use the data you collected in the Acids, Bases & Indicators lab.