In organosulfur chemistry, a mesylate is any salt or ester of methanesulfonic acid (CH3SO3H). In salts, the mesylate is present as the CH3SO−3 anion. When modifying the international nonproprietary name of a pharmaceutical substance containing the group or anion, the spelling used is sometimes mesilate (as in imatinib mesilate, the mesylate salt of imatinib).[1]
Mesylate esters are a group of organic compounds that share a common functional group with the general structure CH3SO2O−R, abbreviated MsO−R, where R is an organic substituent. Mesylate is considered a leaving group in nucleophilic substitution reactions.[2]
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Oxygen As A Leaving Group Using Tosylate And Mesylate in Substitution and Elimination Reactions
Transcription
You can make mesylates and tosylates from alcohols. And you might want to do this, because mesylates and tosylates are better leaving groups. So if we look at a general reaction to form a tosylate, you would start with an alcohol and you'd add tosyl chlorides and also pyridine, and you would form your tosylate over here on the right. When we look at the mechanism, we start with tosyl chloride. If you focus in on the sulfur here, the sulfur is bonded to two oxygens and a chlorine. And we know that oxygen and chlorine are more electronegative than sulfur, so they're going to withdraw some electron density from that sulfur. And so since sulfur's losing some electron density, the sulfur becomes partially positive, and we have an electrophilic center. So the sulfur wants electrons. It can get electrons from the alcohol, so a lone pair of electrons on the alcohol here can attack the sulfur, so nucleophile attacks the electrophile. And these electrons could kick off onto the chlorine here to form the chloride anion. And let's go ahead and draw what we would make. So we would have an R group. We would have an oxygen. The oxygen would now be bonded to sulfur. We would also have still a hydrogen attached to that oxygen, and we'd still have a lone pair of electrons on that oxygen. So the oxygen gets a plus 1 formal charge. The sulfur is still double bonded to this oxygen and to another oxygen. And then we still have our ring attached to the sulfur. So put in our pi electrons here, and-- oops. That was a bad one. Let me fix that. So we have our pi electrons right here, and then a methyl group like that. So let's go ahead and follow those electrons. So the electrons in magenta right here on the oxygen formed a new bond to the sulfur, so here are those electrons in magenta. And the next step, we're going to take the proton off the oxygen here. And so the pyridine is going to function as a base. The lone pair of electrons on nitrogen is going to take this proton, leaving these electrons behind on the oxygen. So let's go ahead and draw what we would form. We would have an R group. We would have an oxygen, and our oxygen would have now two lone pairs of electrons. And we would have our sulfur double bonded to this oxygen, double bonded to this oxygen. And then we would have our ring like this. So let me just sketch that in really quickly, so we would have electrons here, here, and here. Our methyl group. And let's follow some of those electrons. So the electrons in this bond now end up on the oxygen like that. And we formed our toluenesulfonate ester, so also called a tosylate, so this is the exact same thing. So this compound and this compound are the same, the top way is just a way to abbreviate it. And so we formed our tosylate. So one reason to form a tosylate would be to have a better nucleophilic substitution reaction. So let's look at first forming a tosylate from this alcohol over here on the left. And so we know that this carbon is a chiral center, so that as a chiral center. But if we're forming a tosylate, the tosylate forms at this oxygen here. So let's go ahead and draw the product. We'd still have a wedge here, because again the reaction does not occur at the chirality center, the reaction occurs at the oxygen here. So the oxygen would now be bonded, so we'd form a tosylate group, which is a much better leaving group than this OH over here. So the tosylate's an excellent leaving group for nucleophilic substitution reactions. So if we went ahead and a did a nucleophilic substitution reaction, we could add something like sodium bromide, so Na plus and Br minus. So if this was an SN2 type mechanism, the bromide anion would attack this carbon right here, which is a little bit positive, so we have a partially positive carbon right here. And then we get nucleophilic attack from the bromide anion, so it attacks right here. And then SN2 type mechanism, you're going to get inversion of configuration. So you go ahead and draw your products like that. And so the formation of a tosylate just makes this process much easier. We could talk about formation of another good leaving group and that's a mesylate, so very similar to a tosylate. So if we look at the general reaction, once again we start with an alcohol. This time we add mesyl chloride, and this time triethylamine as the base that we will use to form our mesylate over here on the right. The mechanism is a little bit different from the formation of a tosylate, so let's go ahead and look and see what happens. At first, the triethylamine is going to function as a base and take this proton right here, so these electrons are going to remain behind on this carbon. So triethylamine reacts with-- this is mesyl chloride right here. So if we take a proton off, let's go ahead and draw what we would have. We would have our sulfur double bonded to this oxygen, sulfur double bonded to another oxygen, the chlorine right here. And we would now have a carbon bonded to only two hydrogens and a lone pair of electrons on this carbon, so it's a carbanion, so it's a negative 1 formal charge. So let's show those electrons. So these electrons in this bond were left behind on the carbon to form our carbanion. So in the next step, these electrons in magenta are going to move in here to form a double bond between the sulfur and the carbon, and that would kick these electrons off onto chlorine to form the chloride anion. And let's go ahead and draw what we would make. So now we would have sulfur, sulfur would be double bonded to an oxygen, sulfur is double bonded to another oxygen, and now there's a double bond between sulfur and this carbon. This carbon is bonded to two hydrogens like that. Once again, we can think about sulfur as being electrophilic, because this sulfur right here is bonded to these oxygens, which are more electronegative. They're going to withdraw electron density from that sulfur, leaving that sulfur partially positive. And so our electrophilic center, once again we're going to have our alcohol function as a nucleophile. So a lone pair of electrons on our alcohol are going to go all the way to here, they're going to attack our electrophile, and when they do that they push these electrons back off onto the carbon. So let's get a little more space down here so we can draw what happens. So this is a sulfine right here, so the alcohol attacks the sulfine nucleophile, electrophile. Now let's go ahead and draw what we would make. So now we would have an R group bonded to an oxygen. We would have a hydrogen. And this is the oxygen from the alcohol, which attacked the sulfur so now there's a bond between the oxygen and the sulfur. There's still a lone pair of electrons on that oxygen, giving it a plus 1 formal charge. And the sulfur is double bonded to this oxygen, double bonded to this oxygen, and bonded to this carbon. This carbon has two hydrogens on it. It also has a lone pair of electrons, so that's a negative 1 formal charge. So once again, let's identify those electrons. So these electrons right here moved off onto the carbon to form our carbanion. And we could identify some electrons on our alcohol, too. So let's make it red here. These electrons right here on the oxygen, those are the ones that form the bond between the oxygen and the sulfur, so you could say that those electrons are these electrons in here. And so in the last step of our mechanism, the carbanion is going to function as a base. And this lone pair of electrons here is going to take this proton, leaving these electrons behind on our oxygen. So let's go ahead and draw what we would make. So we would have an R group over here, we would have oxygen, and the oxygen would have two lone pairs of electrons. The oxygen is bonded to a sulfur. The sulfur is double bonded to this oxygen, double bonded to this oxygen. And then we would have a CH3 group over here. So a CH3 group, because this carbon-- I'm going to go ahead and identify it in magenta. This carbon picked up this proton here-- so you could say it's that one if you wanted to-- and we formed our mesylate. So this is the exact same thing. We could just abbreviate it here. We could say it's R, O, and then an Ms here. So that's how to form mesylates and tosylates, which are excellent leaving groups.
Preparation
Mesylate esters are generally prepared by treating an alcohol and methanesulfonyl chloride in the presence of a base, such as triethylamine.[3]
Mesyl
Related to mesylate is the mesyl (Ms) or methanesulfonyl (CH3SO2) functional group. Methanesulfonyl chloride is often referred to as mesyl chloride. Whereas mesylates are often hydrolytically labile, mesyl groups, when attached to nitrogen, are resistant to hydrolysis.[4] This functional group appears in a variety of medications, particularly cardiac (antiarrhythmic) drugs, as a sulfonamide moiety. Examples include sotalol, ibutilide, sematilide, dronedarone, dofetilide, E-4031, and bitopertin.[citation needed]
Natural occurrence
Ice core samples from a single spot in Antarctica were found to have tiny inclusions of magnesium methanesulfonate dodecahydrate. This natural phase is recognized as the mineral ernstburkeite. It is extremely rare.[5][6]
See also
References
- ^ International Nonproprietary Names Modified (PDF) (Report). World Health Organization. February 2006. INN Working Document 05.167/3. Retrieved 5 December 2008.
- ^ Smith, Michael B.; March, Jerry (2007). March's Advanced Organic Chemistry (6th ed.). John Wiley & Sons. p. 497. ISBN 978-0-471-72091-1.
- ^ Rick L. Danheiser; Yeun-Min Tsai; David M. Fink (1966). "A General Method for the Synthesis of Allenylsilanes: 1-Methyl-1-(trimethylsilyl)allene". Organic Syntheses. doi:10.15227/orgsyn.066.0001. (a procedure illustrating the use of mesylates).
- ^ Valerie Vaillancourt, Michele M. Cudahy, Matthew M. Kreilein and Danielle L. Jacobs "Methanesulfonyl Chloride" in E-EROS Encyclopedia for Reagents in Organic Synthesis. doi:10.1002/047084289X.rm070.pub2
- ^ Güner, Fatma Elif Genceli; Sakurai, Toshimitsu; Hondoh, Takeo (2013). "Ernstburkeite, Mg(CH3SO3)2·12H2O, a new mineral from Antarctica". European Journal of Mineralogy. 25 (1): 78–83. Bibcode:2013EJMin..25...78G. doi:10.1127/0935-1221/2013/0025-2257.
- ^ Ernstburkeite, Mindat
This page was last edited on 16 February 2024, at 22:32