Wednesday, 29 December 2010
Altered States - C-H Borylation
Reference:
Iridium-Mediated Borylation of Benzylic C H Bonds by Borohydride, Christina Y. Tang, William Smith, Amber L. Thompson, Dragoslav Vidovic, and Simon Aldridge
Angew. Chem. Int. Ed.
A nice achievement in the field of C-H Borylation. The interesting aspect is the use of a borohydride (BH4-) as the ‘boryl’ source. The group has also proposed an intriguing mechanism to rationalize the selective borylation of the benzylic C-H bond. The methyl C-H bond is activated by the iridium catalyst, and is then followed by delivering the ‘boryl’ moiety to this particular C-H bond. This ‘closed’ reactive intermediate should explain the great selectivity of the borylation reaction. This is great work because further developments will surely expand the scope of reagents used for borylating organic substrates in synthesis.
Yet Another C-H Activation - in Organic Synthesis
Reference: To, C.T., Chan, T.L., Li, B.Z., Hui, Y.Y., Kwok, T.Y., Lam, S.Y., Chan, K.S., C-H Arylation of Unactivated Arenes with Aryl Halides Catalyzed by Cobalt Porphyrin, Tetrahedron Letters (2010)
Professor Chan's work is impressive. It represents yet another scrupulous use of C-H activation in organic synthesis, this time using Cobalt as the catalyst. This coupling reaction enables an unactivated aromatic (benzene) to be stitched onto a functionalized aryl halide, and the result is an arylation to form useful biaryls. As they have suggested, this prevents the use of hard reagents such as Grignards and organolithiums in the reaction.
A personal observation: we can see from a number of recent publications that Cobalt is emerging as a good metal for a number of useful organic transformations, especially coupling reactions. Watch out, Copper!
Thursday, 23 December 2010
Queen B's Badge
http://www.economist.com/blogs/babbage/2010/12/bee_biology
Bee Molecular Biology - see how the action of methylation (adding methyl 'CH3' groups) gives rise to intriguing differences for queen B and worker bees. This is something interesting from the emerging field of 'Epigenetics'.
Epigenetic anointment
Dec 23rd 2010 The Economist
Bee Molecular Biology - see how the action of methylation (adding methyl 'CH3' groups) gives rise to intriguing differences for queen B and worker bees. This is something interesting from the emerging field of 'Epigenetics'.
Epigenetic anointment
Dec 23rd 2010 The Economist
Catalyst Barred
Unusual deactivation in the asymmetric hydrogenation of itaconic acid
T. Schmidta, W. Baumanna, H.-J. Drexlera and D. Heller
Journal of Organometallic Chemistry, Article in Press, Accepted Manuscript
This article is important. Given that itaconic acid is biologically significant and is a precursor to many other biological compounds, and Rh-catalyzed hydrogenations are so important for asymmetric synthesis. The understanding of how this deactivation pathway for the catalyst will serve as important insights for future preparations of the useful enantiomeric compounds.
Link:
http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6TGW-51S6XJF-3&_user=121739&_coverDate=12/22/2010&_rdoc=1&_fmt=high&_orig=browse&_origin=browse&_zone=rslt_list_item&_srch=doc-info(%23toc%235265%239999%23999999999%2399999%23FLA%23display%23Articles)&_cdi=5265&_sort=d&_docanchor=&_ct=182&_acct=C000010018&_version=1&_urlVersion=0&_userid=121739&md5=22108964a831ee2923a23f9f75304b55&searchtype=a
T. Schmidta, W. Baumanna, H.-J. Drexlera and D. Heller
Journal of Organometallic Chemistry, Article in Press, Accepted Manuscript
This article is important. Given that itaconic acid is biologically significant and is a precursor to many other biological compounds, and Rh-catalyzed hydrogenations are so important for asymmetric synthesis. The understanding of how this deactivation pathway for the catalyst will serve as important insights for future preparations of the useful enantiomeric compounds.
Link:
http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6TGW-51S6XJF-3&_user=121739&_coverDate=12/22/2010&_rdoc=1&_fmt=high&_orig=browse&_origin=browse&_zone=rslt_list_item&_srch=doc-info(%23toc%235265%239999%23999999999%2399999%23FLA%23display%23Articles)&_cdi=5265&_sort=d&_docanchor=&_ct=182&_acct=C000010018&_version=1&_urlVersion=0&_userid=121739&md5=22108964a831ee2923a23f9f75304b55&searchtype=a
Molecular Lego - Again!!
A great methodology for catalytic pyrrole synthesis by the Master of Atom Economy, Prof. Trost. This method can lead to useful pyrrole derivatives. The 'Molecular Lego'-style chemistry will prove to be important foe better and more efficient syntheses.
*Diagram from J. Am. Chem. Soc. Webpage
Reference:
An Atom-Economic Synthesis of Nitrogen Heterocycles from Alkynes
Barry M. Trost*, Jean-Philip Lumb, and Joseph M. Azzarelli
J. Am. Chem. Soc., Article ASAP
Cutting edge chemistry in 2010 - Article from RSC Chemistry World Magazine
http://www.rsc.org/chemistryworld/News/2010/December/21121001.asp
C-H Activation of Alkanes in Organic Synthesis - Aromatic synthesis
What an achievement in catalysis. These workers are using the inert alkanes as starting materials, and convert them into aromatic compounds under iridium catalysis - an atom-economical dehydrogenative reaction. This sets a standard for the kind of chemistry we want in an era after ‘cross-coupling chemistry are awarded a Nobel prize’ : C-H Activation of the most unreactive substrates to give useful chemical compounds.
*Diagrams above from Nature Chemistry and http://www.rsc.org/chemistryworld/News/2010/December/19121001.asp
Catalytic dehydroaromatization of n-alkanes by pincer-ligated iridium complexes
Ritu Ahuja, Benudhar Punji, Michael Findlater, Carolyn Supplee, William Schinski, Maurice Brookhart & Alan S. Goldman, NATURE CHEMISTRY
http://www.nature.com.eproxy1.lib.hku.hk/nchem/journal/vaop/ncurrent/abs/nchem.946.html
This achievment is covered in RSC Chemistry World Magazine
http://www.rsc.org/chemistryworld/News/2010/December/19121001.asp
Thursday, 24 June 2010
Reversal of Fortune - The Amide Umpolung
http://www.nature.com/nature/journal/v465/n7301/abs/nature09125.html
Commentary:
http://www.nature.com/nature/journal/v465/n7301/full/4651020a.html
^o^: Finally, an unconventional solution for the classic problem of amide-bond formation, and an innovative excuse for an alternative exam answer! Instead of the condensation of an carboxylic acid and an amine, Sehn et. al. proposed an 'umpolung' (reversal of polarity) approach which uses the nitroalkane as the NUCLEOPHILIC partner and an [iodine-activated] amine as the ELECTROPHILIC partner, to afford the amide product. It is of no surprise that the use of nitroalkane (-CH2NO2) as an enolate equivalent - only as an umpolung - has seen a fruitful development in the field of Henry reaction, and also because of its unmasking into a carbonyl group via the McMurry Reaction or ouch(!), the Nef Reaction. This novel concept has seen a wide substrate scope and the authors have expanded this methodolgy to some sort of a 3-component reaction (fist a Henry reaction between an imine and nitroalkane, then the coupling) in an attempt to control the formation of a stereogenic center alpha to the resultant amide. The mechanism is intriguing and they have done some control experiments to rule out other possibilities (e.g. a Nef-like mechanism). It is also encouraging to learn that they have started to look into the asymmetric version of this methodology, and given the exciting field in the catalysis of Henry reaction, it should come as no surprise there will be new inpisrations in the form of organocatalsysis / Lewis Acid catalysis for this methodology.
An interesting observation is that the nitro-bromo intermedaite (Figure 3, 10) can be hydrolysed, presumably via the aqueous workup, into the ketone (detach the amide N for the moment) in a rather mild condition. Given that the hydrolytic transformation of a nitro into a ketone is often harsh (see the Nef reaction), it may serve as an implication that the bromide may somehow aid in the hydrolysis of the nitro group. This observation somewhat gives weight to the value of using these bromo-nitro functionalities in synthesis.
by Ed Law
24/06/2010
Thursday, 17 June 2010
Synthesis of 2-Boryl- and Silylindoles by Copper-Catalyzed Borylative and Silylative Cyclization of 2-Alkenylaryl Isocyanides
Mamoru Tobisu, Hirokazu Fujihara, Keika Koh and Naoto Chatani
J. Org. Chem., Article ASAP
DOI: 10.1021/jo101024f
Publication Date (Web): June 17, 2010
^o^: This type of sequence signifies an interesting methodology that has the potential to lead to a versatile intermediate (a boron / silicon handle) that will provide further entries into other biological significant compounds. The peculiar behaviour of the isocyanide makes it a nice synthon in the area of ring synthesis. In a sub-conscious level, we can indeed draw parallels from some nice Sawamura-type chemistry[1].
by Ed Law
17/06/2010
Reference:
[1] For some recent work by Sawamura, see: (a) Org. Lett., 2010, 12 (10), pp 2438–2440; (b) J. Am. Chem. Soc., 2010, 132 (17), pp 5990–5992
Monday, 14 June 2010
Iodine Wonder
Quaternary Ammonium (Hypo)iodite Catalysis for Enantioselective Oxidative Cycloetherification
Muhammet Uyanik, Hiroaki Okamoto, Takeshi Yasui, and Kazuaki Ishihara
Science 11 June 2010 328: 1376-1379
Also featured in:
C & EN June 14, 2010 Volume 88, Number 24 p. 11
Iodine Catalysis Goes Green
Sarah Everts
http://pubs.acs.org/cen/news/88/i24/8824notw4.html
^o^: If a synthetic chemistry article is on the SCIENCE magazine, it has got to be great! It should come as no surprise, given that iodine reagents (espc. hypervalent iodine, the 'cationic' types - meaning those with positive oxidation states) are emerging as rising stars in synthetic chemistry, and often catalysis can be done METAL-FREE and in a GREEN (environmental friendly) way - an achievement in organocatalysis. Yet this time, the iodine fella is an ANIONIC (-ve charge) iodite rather than a positive-charged one. The philosophy behind this catalytic strategy is that the authors are playing with the oxidation states of the iodine species to effect the oxidative cyclization reactions. Indeed, from their screening studies the cationic iodine species (e.g. the hypervalent ones) afford 'messy' results (the way the authors put it in the article) and it is the 'I minus' that does all the magic here. Do not divert our focus, however, from its positive charge partner in crime, the quaternary ammonium salt, as it is the one which provides the products with impressive enantioselectivities. The co-oxidant is the common hydrogen peroxide (H2O2) and the reactions are carried out in a mixture of organic solvent and WATER - likely due to the 'greasiness' of the substrates, and the authors can possibly push it forward to a greener process. Overall an intriguing reaction with an iodite salt - yet another great contribution to green chemistry. And don't forget the reaction is ATOM-ECONOMICAL too.
by Ed Law 14/06/2010
Sunday, 13 June 2010
Atom Economy (原子經濟性)
Doing chemistry is very much like commitments in economic activities: the ultimate aim to minimize COST. One of the most iconic aspects of a chemical reaction is the combination of a number of reactants (the players in the reaction flasks, A and B, Figure 1) to afford a number of products (C, D ,E). We are all happy because the equation is balanced.
A + B --------- > C [+ D + E ]
where A, B = reactants
C = desired product
D, E = unwanted WASTES
Figure 1. A normal chemical reaction.
Now focus on the right hand side of the equation, which is the interesting aspect as it is why doing the chemistry at first place. Compound C is indeed the target we want, and the mission is accomplished. However, the watchful readers will be uncomfortable to observe the acquaintance of 2 further compounds, namely D and E. We will assume in this discussion that D and E are not any desired products and of no further uses . In other words, D and E represent the WASTES generated through the reaction between A and B. The nature of the waste is diverse: it can be water, a gas, or even worse, an organic compound (with substantial carbon content). The problem with this seemingly inevitable result is the efforts required to get rid of these undesirable bystanders – which is done practically in the workup and purification stages in a chemical experiment - can be enormous. Not only these represent an investment in much time and effort, the creation of (toxic) waste also provides a longterm impact to the environment, against the realm of Green Chemistry. Worse still, the removal of such wastes from our desired product can be tricky sometimes (vide infra).
This situation is best illustrated by examples. Assume compound A and B (Figure 2) react to give our desirable compound C. A combination of 18 carbon atoms end up giving only 7 carbons in our product C - which means we are destined to lose 11 carbon atoms, and we can’t avoid it. An analogy is that you put 1kg of flour into a bread-making machine (if there exists one of this goodies out there) and ends up getting 5g of bread out, as the rest was burnt up in the machine. What a waste!
A + B --------- > C [+ D + E …]
where A = 6 carbons
B = 12 carbons
Product C only has 7 carbons , waste = 11 carbons!!
Figure 2. A reaction which is NOT very atom-ceonomical.
The ideal outcome we want is: if we have invested 18 carbon atoms in the reactions, we want all 18 atoms on the target molecule we desire – and we have lost and wasted nothing (Figure 3).
A + B --------- > C
where A = 6 carbons
B = 12 carbons
Product C has 18 carbons, Waste = 0 carbons!! [you has lost nothing]
Figure 3. An atom-economical reaction.
A real example that nicely illustrates this notion is a modern classic, the Wittig reaction, FOR which Prof. Georg Wittig was awarded the Nobel Prize in Chemistry in 1979. It can be said to serve as the ultimate solution to make an alkene (carbon-carbon double bondS) with controllable stereochemical outcomes (E/Z isomers). Looking at the reaction, a worrying aspect becomes apparent (Figure 4).
Figure 4. A real reaction (Wittig reaction) in action. Notice the rightmost phosphorus compound is a pretty nuisance. (adapted from Wikipedia)
It is that legendary phosphorus compound, triphenylphosphine oxide (Ph3P=O, MW – 278.29g/mol !!) that attracts the siren: doing the reaction leads to the desired alkene and the concomitant formation of triphenylphosphine oxide (18 carbon atoms, 1 phosphorus, 1 oxygen), and unfortunately the mechanism of the reaction dictates that there is no way you can avoid this phosphorus fella. If we include the carbon atoms on the phosphorus in our calculations , that means we will lose no less than 18 carbon atoms at the end. Worse still, the removal of triphenylphosphine oxide can be very tricky in most cases. If you are not convinced, ask anyone who has done a normal Wittig / Mitsunobu reaction before.
Therefore the type of reaction we are aiming for are those represented by the reactions that follow. This can somewhat ensure the minimal efforts and waste generated as a result. Indeed, Prof. Barry Trost, a famous organic chemistry professor in Stanford, suggested the concept of atom economy about 2 decades ago[1]. His group has also been committing to develop novel reactions that embraces this important philosophy, something that will contribute towards the notion of Green Chemistry. Some of the following examples are illustrative.
1. ISOMERIZATIONS
One of the most obvious ways not to lose carbon atoms is an isomerization reaction. Isomers of the same compound have the same carbon counts but they differ in their structural arrangements. Thus an isomerization can cause a subtle change in the molecular skeleton, yet it will not change the number of carbon atoms present – so everything is conserved. Even if the structure of the molecular skeletons are relatively similar before and after the reaction, differences can still occur as the ‘movement’ of the functional groups, that signify the chemical compound’s ‘behaviour’ , can re-organize to something totally different. Many of these examples can be termed as ‘redox isomerizations’ since we are fiddling with the oxidation states of the compounds. The mechanism often involves acid / base concepts and proton transfers (which has found plenty of parallels in biological mechanisms). Since many of these reactions may require a harsh temperature to be realized, transition metal catalysis comes to rescue. For example Trost has used his Ruthenium complex to effect a number of redox isomerizations in different organic substrates in a totally atom-economical manner (Figure 5)[2.3]. Note the intriguing design in the first reaction scheme in Figure 5 [2]. Through the isomerization reaction, a propargylic alcohol (alkyne next to a hydroxyl) is ‘switched’ to a,b-unsaturated aldehyde, which then reacts in tandem with a nucleophilic hydroxyl to the oxygen ring in an efficient reaction (Figure 5, above). This represents some form of a ‘reactivity switch’ – once the functional group is switched ON (the Michael acceptor), it reacts nicely. Indeed, the brilliance behind Trost’s work is that by using one type of Ruthenium catalyst, some 20 diverse types of reactivities can be entrained – and all are atom-economical[4].
Figure 5. Redox Isomerizations by Trost et. al. (adapted from Ref. [2] and [3]).
Figure 6. The many faces of isomerization reactions. (adapted from Ref. [5])
The importance of these types of reactions (Figure 6), [5] has been nicely discussed in a perspective article in , rather interestingly, Daltons Transactions lately, since it is focused on possibilities in transition metal catalysis. All these reactions are totally atom economical and, from the article one is easily surmised that the diverse opportunities these methodolgies can deliver. An equally intriguing reaction is the Meyer-Schuster reaction (Figure 7), [5], which has also be implied in the biosynthesis of some fragrant norisoprenoids, including damascenone, a ‘rose-fragrant’ compound that contributes to the nice taste in red wines [6]. It was proposed that the diverse biosynthetic precursors undergo the Meyer-Schuster reaction towards damascenone.
Figure 7. The Meyer-Schuster Reaction (adapted from Ref. [5]).
Figure 8. Damascenone (adapted from Wikipedia).
2. COUPLING REACTIONS
Coupling reaction is a form of molecular LEGO. It involves assembling 2 bricks , reactant A and B, and becomes the product A-B. In normal cirsumstances it will the lead to loss the of a halogen atom (via oxidative addition), and also the metal fragments on its coupling partner. Yet look at Trost’s type of coupling reactions (Figure 9,) [7] - again with complete atom economy. The mechanism is also interesting as they involve some ‘ruthenacycle’ (ruthenium ring) intermediates, which is rather unorthodox for normal cross-coupling reactions [4,7].
Figure 9. An alkene -alkyne coupling reaction. (Adapted from Ref. [7]).
Another great example to cite is Prof. M.J. Krische’s work on C-C coupling reactions (Figure 10), [8,9]. Not only these methodologies are atom-economical, the fantastic aspect is how they play with the oxidation states of reactants. In normal cases, the correct oxidation state for the reactants to become an alcohol product is that of aldehyde or ketone (C=O). Yet they succeeded in submitting a reactant with a ‘wrong’ oxidation level (an alcohol, C-OH) to afford the product under Ir, Ru, or Rh catalysis. Presumably the alcohol substate is oxidized through the catalysis to generate the ‘right’ oxidation state (C=O) for the reaction to occur. The concept is reminiscent of putting 2 ‘chemical bricks’ together, and can also be rewarded with an impressive enantioselectivity (>90%e.e.)
Figure 10. Krische-type C-C coupling reactions. (Adapted from Ref. [8,9]).
Conclusion
It is obvious that , at least on an environmental perspective, working towards new reactions which are atom-economical is a clear long-term goal. Not only this will require the creativity of chemists, in many cases we need to draw a lot of inspirations from Nature, the ultimate synthetic chemist of all.
IN SHORT:
*A reaction which is not atom-economical is a waste of resources, efforts and often has negative impacts on the environment.
*Atom-economical chemical convertions can often be achieved through careful designs, and in many cases we do need inspirations from Nature. Isomerizations serve as a nice example, it is like moving something (the functional groups) on a track (molecular skeleton) with a defined number of components (the carbon atoms), without throwing any of them away in the end.
*In some cases, coupling reactions can be atom-economical too.
by Ed Law 13/06/2010
References:
1. (a) Barry M. Trost (1991) Science , 254, 1471 ; (b) Barry M. Trost (1995) Angew. Chem. Int. Ed. Engl. 34 (3): 259–281.
2.Barry M. Trost, Alicia C. Gutierrez and Robert C. Livingston
Org. Lett., 2009, 11 (12), pp 2539–2542.
3. Barry M. Trost and Robert C. Livingston
J. Am. Chem. Soc., 2008, 130 (36), pp 11970–11978
4. Barry M. Trost
Acc. Chem. Res., 2002, 35 (9), pp 695–705
5. Victorio Cadierno, Pascale Crochet, Sergio E. García-Garrido, José Gimeno
Dalton Trans., 2010, (17),4015-4031
6. Andrew L. Waterhouse, Susan E. Ebeler. Chemistry of Wine Flavor (1998).
7. Barry M. Trost and Alicia Martos-Redruejo
Org. Lett., 2009, 11 (5), pp 1071–1074
8. Soo Bong Han, Xin Gao and Michael J. Krische
J. Am. Chem. Soc., Articles ASAP (As Soon As Publishable)
9. Hoon Han and Michael J. Krische
Org. Lett., 2010, 12 (12), pp 2844–2846
Also see:
http://en.wikipedia.org/wiki/Atom_economy
A + B --------- > C [+ D + E ]
where A, B = reactants
C = desired product
D, E = unwanted WASTES
Figure 1. A normal chemical reaction.
Now focus on the right hand side of the equation, which is the interesting aspect as it is why doing the chemistry at first place. Compound C is indeed the target we want, and the mission is accomplished. However, the watchful readers will be uncomfortable to observe the acquaintance of 2 further compounds, namely D and E. We will assume in this discussion that D and E are not any desired products and of no further uses . In other words, D and E represent the WASTES generated through the reaction between A and B. The nature of the waste is diverse: it can be water, a gas, or even worse, an organic compound (with substantial carbon content). The problem with this seemingly inevitable result is the efforts required to get rid of these undesirable bystanders – which is done practically in the workup and purification stages in a chemical experiment - can be enormous. Not only these represent an investment in much time and effort, the creation of (toxic) waste also provides a longterm impact to the environment, against the realm of Green Chemistry. Worse still, the removal of such wastes from our desired product can be tricky sometimes (vide infra).
This situation is best illustrated by examples. Assume compound A and B (Figure 2) react to give our desirable compound C. A combination of 18 carbon atoms end up giving only 7 carbons in our product C - which means we are destined to lose 11 carbon atoms, and we can’t avoid it. An analogy is that you put 1kg of flour into a bread-making machine (if there exists one of this goodies out there) and ends up getting 5g of bread out, as the rest was burnt up in the machine. What a waste!
A + B --------- > C [+ D + E …]
where A = 6 carbons
B = 12 carbons
Product C only has 7 carbons , waste = 11 carbons!!
Figure 2. A reaction which is NOT very atom-ceonomical.
The ideal outcome we want is: if we have invested 18 carbon atoms in the reactions, we want all 18 atoms on the target molecule we desire – and we have lost and wasted nothing (Figure 3).
A + B --------- > C
where A = 6 carbons
B = 12 carbons
Product C has 18 carbons, Waste = 0 carbons!! [you has lost nothing]
Figure 3. An atom-economical reaction.
A real example that nicely illustrates this notion is a modern classic, the Wittig reaction, FOR which Prof. Georg Wittig was awarded the Nobel Prize in Chemistry in 1979. It can be said to serve as the ultimate solution to make an alkene (carbon-carbon double bondS) with controllable stereochemical outcomes (E/Z isomers). Looking at the reaction, a worrying aspect becomes apparent (Figure 4).
Figure 4. A real reaction (Wittig reaction) in action. Notice the rightmost phosphorus compound is a pretty nuisance. (adapted from Wikipedia)
It is that legendary phosphorus compound, triphenylphosphine oxide (Ph3P=O, MW – 278.29g/mol !!) that attracts the siren: doing the reaction leads to the desired alkene and the concomitant formation of triphenylphosphine oxide (18 carbon atoms, 1 phosphorus, 1 oxygen), and unfortunately the mechanism of the reaction dictates that there is no way you can avoid this phosphorus fella. If we include the carbon atoms on the phosphorus in our calculations , that means we will lose no less than 18 carbon atoms at the end. Worse still, the removal of triphenylphosphine oxide can be very tricky in most cases. If you are not convinced, ask anyone who has done a normal Wittig / Mitsunobu reaction before.
Therefore the type of reaction we are aiming for are those represented by the reactions that follow. This can somewhat ensure the minimal efforts and waste generated as a result. Indeed, Prof. Barry Trost, a famous organic chemistry professor in Stanford, suggested the concept of atom economy about 2 decades ago[1]. His group has also been committing to develop novel reactions that embraces this important philosophy, something that will contribute towards the notion of Green Chemistry. Some of the following examples are illustrative.
1. ISOMERIZATIONS
One of the most obvious ways not to lose carbon atoms is an isomerization reaction. Isomers of the same compound have the same carbon counts but they differ in their structural arrangements. Thus an isomerization can cause a subtle change in the molecular skeleton, yet it will not change the number of carbon atoms present – so everything is conserved. Even if the structure of the molecular skeletons are relatively similar before and after the reaction, differences can still occur as the ‘movement’ of the functional groups, that signify the chemical compound’s ‘behaviour’ , can re-organize to something totally different. Many of these examples can be termed as ‘redox isomerizations’ since we are fiddling with the oxidation states of the compounds. The mechanism often involves acid / base concepts and proton transfers (which has found plenty of parallels in biological mechanisms). Since many of these reactions may require a harsh temperature to be realized, transition metal catalysis comes to rescue. For example Trost has used his Ruthenium complex to effect a number of redox isomerizations in different organic substrates in a totally atom-economical manner (Figure 5)[2.3]. Note the intriguing design in the first reaction scheme in Figure 5 [2]. Through the isomerization reaction, a propargylic alcohol (alkyne next to a hydroxyl) is ‘switched’ to a,b-unsaturated aldehyde, which then reacts in tandem with a nucleophilic hydroxyl to the oxygen ring in an efficient reaction (Figure 5, above). This represents some form of a ‘reactivity switch’ – once the functional group is switched ON (the Michael acceptor), it reacts nicely. Indeed, the brilliance behind Trost’s work is that by using one type of Ruthenium catalyst, some 20 diverse types of reactivities can be entrained – and all are atom-economical[4].
Figure 5. Redox Isomerizations by Trost et. al. (adapted from Ref. [2] and [3]).
Figure 6. The many faces of isomerization reactions. (adapted from Ref. [5])
The importance of these types of reactions (Figure 6), [5] has been nicely discussed in a perspective article in , rather interestingly, Daltons Transactions lately, since it is focused on possibilities in transition metal catalysis. All these reactions are totally atom economical and, from the article one is easily surmised that the diverse opportunities these methodolgies can deliver. An equally intriguing reaction is the Meyer-Schuster reaction (Figure 7), [5], which has also be implied in the biosynthesis of some fragrant norisoprenoids, including damascenone, a ‘rose-fragrant’ compound that contributes to the nice taste in red wines [6]. It was proposed that the diverse biosynthetic precursors undergo the Meyer-Schuster reaction towards damascenone.
Figure 7. The Meyer-Schuster Reaction (adapted from Ref. [5]).
Figure 8. Damascenone (adapted from Wikipedia).
2. COUPLING REACTIONS
Coupling reaction is a form of molecular LEGO. It involves assembling 2 bricks , reactant A and B, and becomes the product A-B. In normal cirsumstances it will the lead to loss the of a halogen atom (via oxidative addition), and also the metal fragments on its coupling partner. Yet look at Trost’s type of coupling reactions (Figure 9,) [7] - again with complete atom economy. The mechanism is also interesting as they involve some ‘ruthenacycle’ (ruthenium ring) intermediates, which is rather unorthodox for normal cross-coupling reactions [4,7].
Figure 9. An alkene -alkyne coupling reaction. (Adapted from Ref. [7]).
Another great example to cite is Prof. M.J. Krische’s work on C-C coupling reactions (Figure 10), [8,9]. Not only these methodologies are atom-economical, the fantastic aspect is how they play with the oxidation states of reactants. In normal cases, the correct oxidation state for the reactants to become an alcohol product is that of aldehyde or ketone (C=O). Yet they succeeded in submitting a reactant with a ‘wrong’ oxidation level (an alcohol, C-OH) to afford the product under Ir, Ru, or Rh catalysis. Presumably the alcohol substate is oxidized through the catalysis to generate the ‘right’ oxidation state (C=O) for the reaction to occur. The concept is reminiscent of putting 2 ‘chemical bricks’ together, and can also be rewarded with an impressive enantioselectivity (>90%e.e.)
Figure 10. Krische-type C-C coupling reactions. (Adapted from Ref. [8,9]).
Conclusion
It is obvious that , at least on an environmental perspective, working towards new reactions which are atom-economical is a clear long-term goal. Not only this will require the creativity of chemists, in many cases we need to draw a lot of inspirations from Nature, the ultimate synthetic chemist of all.
IN SHORT:
*A reaction which is not atom-economical is a waste of resources, efforts and often has negative impacts on the environment.
*Atom-economical chemical convertions can often be achieved through careful designs, and in many cases we do need inspirations from Nature. Isomerizations serve as a nice example, it is like moving something (the functional groups) on a track (molecular skeleton) with a defined number of components (the carbon atoms), without throwing any of them away in the end.
*In some cases, coupling reactions can be atom-economical too.
by Ed Law 13/06/2010
References:
1. (a) Barry M. Trost (1991) Science , 254, 1471 ; (b) Barry M. Trost (1995) Angew. Chem. Int. Ed. Engl. 34 (3): 259–281.
2.Barry M. Trost, Alicia C. Gutierrez and Robert C. Livingston
Org. Lett., 2009, 11 (12), pp 2539–2542.
3. Barry M. Trost and Robert C. Livingston
J. Am. Chem. Soc., 2008, 130 (36), pp 11970–11978
4. Barry M. Trost
Acc. Chem. Res., 2002, 35 (9), pp 695–705
5. Victorio Cadierno, Pascale Crochet, Sergio E. García-Garrido, José Gimeno
Dalton Trans., 2010, (17),4015-4031
6. Andrew L. Waterhouse, Susan E. Ebeler. Chemistry of Wine Flavor (1998).
7. Barry M. Trost and Alicia Martos-Redruejo
Org. Lett., 2009, 11 (5), pp 1071–1074
8. Soo Bong Han, Xin Gao and Michael J. Krische
J. Am. Chem. Soc., Articles ASAP (As Soon As Publishable)
9. Hoon Han and Michael J. Krische
Org. Lett., 2010, 12 (12), pp 2844–2846
Also see:
http://en.wikipedia.org/wiki/Atom_economy
Friday, 11 June 2010
Catalysis - Gold Chemistry
Carboxylation of C−H Bonds Using N-Heterocyclic Carbene Gold(I) Complexes
Ine I. F. Boogaerts and Steven P. Nolan*
J. Am. Chem. Soc., Article ASAP
DOI: 10.1021/ja103429q
Publication Date (Web): June 11, 2010
http://pubs.acs.org/doi/abs/10.1021/ja103429q
^o^: An impressive piece of work by Nolan. They addressed an extremely important concept of functionalizing C-H bonds on heterocycles, in which chemists in pharma industry will definitely be enthusiatic about. The great thing about this piece of chemistry is that the reactions in question can be done in AIR - no inert atmosphere required. An interesting aspect is the hydroxyl (OH) ligand on the gold catalyst, which have drawn parellels in the field of Rh catalysed conjugate additions (e.g. Hayashi et. al.). It would be exciting to see if this aspect have any implications on the chemistry itself , for example, what will be the effect of WATER on the reaction profile? Clearly the next step to assess this methodology is the functionalizations of more useful chemical entities onto the heterocyclic rings.
P.S. It would be nice if they can use dry ice as the source of CO2...
by Ed Law ^o^ - 11/6/2010
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