Physiological Buffering Flashcards
Define the terms acid
A proton donor (increases H+ concentration in a solution
Define the term base
A proton acceptor (decreases H+ concentration in a solution)
Outline the dissociation constant
ka = [H+][A-]/[HA]
Define the term pKa
The pH at which 50% of the molecules are ionised – ie there are equal numbers of ionised and non-ionised.
pKa = -log ka
Define the terms buffer solution
A buffer is a substance (solution) that resists change in pH when small amounts of acids or alkalis are added
Appreciate the importance of the modified Henderson equation in buffering and acid base physiology
Many drugs as weak acids or bases as unionised drugs cross the membranes and enter the bloodstream more easily.
It is important to note that the environment (being either acidic or basic) will impact upon the ratio of ionised (A-) to unionised (AH)
These are weak acids or bases that exist at equilibrium with the conjugate
For biological solutions it’s vital to maintain a steady pH
Outline the Henderson Hasselbalch Equation
pH = pKa + log ([A-] / [HA])
Outline some clinical examples of the importance of the HH equation
Aspirin is a weak acid with pKa 3.4
Stomach pH 1.4
-Meaning Aspirin dissociates by 50% at pKa 3.4, so less than 3.4 less of the acid will be dissociated meaning there is a higher number of non ionised molecules which can then be more easily absorbed.
But weak bases in an acidic environment – don’t work so well
Bupivacaine (local anaesthetic) is a weak base with pKa 8.1
-Acidic (such as infected tissue) tissue has a pH 4, which is not optimal for bupivacaine – so don’t use local anaesthetics in infected tissue
-Can change the pH of the area to optimise effect of Bupivacaine
Indicate the major buffering systems present in mammalian blood
ISF
-Bicarbonate
-Phosphate
-Protein
Blood
-Bicarbonate
-Haemoglobin
-Plasma protein
ICF
-Proteins
-Phosphate
Urine
-Phosphate
-Ammonia
Bone
-Ca Carbonate
How do small pH fluctuations (e.g. 0.5) cause so much damage?
pH is a logarithmic scale – a small change in pH is BIG change in [H+]
Understand the role of protein buffers with an increase of pH
Increase in pH
Protein molecule will buffer by donating H+ to bring H+ levels back up to normal
Sites
-The carboxyl group (-COOH) can dissociate and act as a weak acid releasing H+ becoming as carboxylate ion (-COO-)
-The R group contain an imidazole ring which can donate H+ f pH climbs too high
Identify the important protein molecules utilised in the buffer system in response to increase of pH
Histidine and cysteine are very important within ECF and ICF
Histidine can be a proton donor or acceptor at physiological pH
Albumin contains more histidine residues than globulin
Understand the role of protein buffers with an decrease of pH
Decrease in pH
Protein molecule will buffer by accepting H+ to bring H+ levels back down to normal
Sites
-The carboxylate ion (-COO-) acts as weak base and accept H+ forming carboxyl group (-COOH)
-The amino group (NH2) acts as weak bases and accept H+ forming an amnio ion (-NH3+)
Understand the role of a haemoglobin buffer
Hb accounts for the majority (75%) of the overall protein buffering capacity of the body.
CO2 diffuses into the blood stream where 7% remains in the plasma and 93% is diffused into RBCs
23% of this binds to Hb forming Hb.CO2 (carbaminohaemoglobin)
70% is converted to H2CO3 by carbonic anhydrase
H2CO3 dissociates into H+ and HCO3-
H+ buffered by Hb
HCO3- moves into the ECF in exchange for Cl-
Explain the Bohr effect and the important role Haemoglobin buffer system plays within it
Capacity of hemoglobin to form ionic bonds with H+ ions is also related to haemoglobin’s ability to transport oxygen
When a hemoglobin molecule ionically bonds with H+ ions it tends to favour a consequent dissociation from oxygen
Therefore, in the presence of increased hydrogen ions, hemoglobin has less affinity for oxygen and this means that hemoglobin will “unload” oxygen more readily in the capillaries of metabolically active tissues which are liberating H+ ions and CO2, both of which contribute to a more acidic pH environment;
