Abstract
We have measured the influence of mesoporous silica (MCM-41 and SBA-15) nanoparticles and dense silica nanoparticles on epinephrine oxidation, a pH-dependent reaction, whose rate is small in acidic or neutral solutions but much greater at higher pH. The reaction was measured by monitoring adrenochrome at 480 nm, the product of epinephrine oxidation. In distilled water (dH(2)O) with no particles present, the oxidation of epinephrine occurs slowly but more rapidly at higher pH. The presence of MCM-41 or silica spheres does not accelerate the oxidation, but SBA-15 does, showing that the difference in the structures of nanomaterials leads to differing effects on the epinephrine oxidative process. In phosphate buffered saline (PBS, pH = 7.4), epinephrine undergoes a much quicker oxidation, and, in this case, the presence of SBA-15 and MCM-41 makes it even more rapid. Silica spheres have no noticeable influence on the oxidation in PBS or in dH(2)O. The possibility that the catalytic effect of mesoporous silica nanoparticles (MSN) could result from the residue of templating chemicals, however, can be excluded due to the postsynthesis calcinations. Experiments with dithionite, added either earlier than or at the same time as the epinephrine addition, show that fast oxidation takes place only when dithionite and epinephrine are simultaneously added into PBS solution. This confirms a vital role of oxygen radicals (probably *O(2)(-)) in the oxidation of epinephrine. These oxygen radicals are likely to form and accumulate within the phosphate buffer or in the presence of MSN. Comparing the three kinds of silica nanoparticles applied, we note that mesoporous SBA-15 and MCM-41 materials own much larger surface area than solid silica particles do, whereas MCM-41 possesses a much narrower pore size (0.4-fold) than SBA-15. It seems, therefore, that large surface area, characteristic mesoporosity, and surface structures aid in the deposit of oxygen radicals inside MSN particles, which catalyze the epinephrine oxidation in a favorable phosphate environment.
Highlights
A family of biogenic amines, catecholamines take major responsibilities for the acute stress response perceived by mammals when sensing unexpected stimuli from either external or internal environment.1,2 Chemically, catecholamines are a group of hormones, biosynthesized from tyrosine and phenylalanine via hydroxylation to produce, among others, dopamine, norepinephrine, and epinephrine.3 All these hormones contain catechol and amine moieties as implied in the name
We have measured the influence of mesoporous silica (MCM-41 and SBA-15) nanoparticles and dense silica nanoparticles on epinephrine oxidation, a pH-dependent reaction, whose rate is small in acidic or neutral solutions but much greater at higher pH
The synthesis was followed by calcinations to remove the template, leading to the formation of ordered mesoporous silica nanoparticles (MSN)
Summary
A family of biogenic amines, catecholamines take major responsibilities for the acute stress response perceived by mammals when sensing unexpected stimuli from either external or internal environment. Chemically, catecholamines are a group of hormones, biosynthesized from tyrosine and phenylalanine via hydroxylation to produce, among others, dopamine, norepinephrine, and epinephrine. All these hormones contain catechol and amine moieties as implied in the name. Catecholamines are a group of hormones, biosynthesized from tyrosine and phenylalanine via hydroxylation to produce, among others, dopamine, norepinephrine, and epinephrine.. Catecholamines are a group of hormones, biosynthesized from tyrosine and phenylalanine via hydroxylation to produce, among others, dopamine, norepinephrine, and epinephrine.3 All these hormones contain catechol and amine moieties as implied in the name. A large number of cyclic adenosine monophosphates are produced to activate glycogen phosphorylases, which further accelerate glycogenolysis and liberate glucoses into the bloodstream.. A large number of cyclic adenosine monophosphates are produced to activate glycogen phosphorylases, which further accelerate glycogenolysis and liberate glucoses into the bloodstream.5-7 This sudden burst of energy stimulates the body to make a spontaneous decision;to fight or flight A large number of cyclic adenosine monophosphates are produced to activate glycogen phosphorylases, which further accelerate glycogenolysis and liberate glucoses into the bloodstream. This sudden burst of energy stimulates the body to make a spontaneous decision;to fight or flight
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