Sciencemadness Discussion Board

Phenylacetaldehyde from Phenylalanine

JJay - 24-5-2016 at 14:37

In the thread on preparing phenylacetaldehyde from styrene, SM2 mentioned that it is possible to react bleach with phenylalanine to produce phenylacetaldehyde.

I attempted this today by dissolving 10 grams of phenylalanine in 500 mL of water and adding 14.5 mL of 8% bleach. The smell of flowers was almost immediately apparent. I let the solution sit for a few minutes and then extracted 3x with 10 mL DCM and then attempted to create the bisulfite adduct (I assumed 70% yield). My lab still smells like a rose garden but I got no product....

Questions:
1. How many equivalents of hypochlorite are necessary to do Strecker degradation of phenylanine?
2. Does the bleach really need to be concentrated?
3. How long does the reaction take? For that matter, does anyone know what reaction conditions to use? If I use a stoichiometric amount of bleach, I could do iodometric tests to see if the reaction is complete, but it would save a lot of time if someone has done this before....
4. Am I correct in assuming that I can extract phenylacetaldehyde with DCM and create the bisulfite adduct? That seems a lot easier than distillation from an aqueous mixture.
5. Is there any danger of accidentally overoxidizing the phenylacetaldehyde to phenylacetic acid? This is something I would actually like to avoid.

I'm certainly going to attempt this again soon, but I'd like to get a weighable product this time. If anyone has successfully degraded phenylalanine to phenylacetaldehyde before, your input is appreciated.

[Edited on 24-5-2016 by JJay]

DraconicAcid - 24-5-2016 at 14:41

Hmmm....it melts at 33 oC and is only slightly soluble in water. I wonder- if you do the reaction at low temperatures, will the solid precipitate out?

Merck Index says 33-34 oC, as does the 70th CRC.

[Edited on 24-5-2016 by DraconicAcid]

zed - 24-5-2016 at 15:09

The problem with oxidations, is putting on the brakes. Phenylacetaldehyde could be further oxidized to PhenylAcetic acid, and then Benzaldehyde or Benzoic acid. In fact, I think you can bet on it.

Sometimes, this tendency is combated, by using a two-phase solvent system. An aqueous-phase, and a non-polar phase. The Amino-Acid reacts with hypochlorite in the aqueous phase to produce Phenylacetaldehyde. The Phenylacetaldhyde, is much more soluble in the non-polar Phase, and it migrates there, where it is protected from further oxidation.

It works, but yer dancin' with the devil. Temperature control, speed of agitation, and working with massive volumes of dilute solutions, all come into play. Yields are often....meh.

Experimental details applied to tryptophane/indole-acetaldehyde, should be around.

https://www.erowid.org/archive/rhodium/chemistry/indoleaceta...





[Edited on 24-5-2016 by zed]

[Edited on 24-5-2016 by zed]

[Edited on 24-5-2016 by zed]

clearly_not_atara - 24-5-2016 at 15:29

IIRC, dehydroascorbic acid, the oxidized version of vitamin C, is an active oxidant for the concerted Strecker (as is any vicinal tricarbonyl). However, it tends to undergo anannulation to a hexahydrodifuran, so it has to be produced in situ.

I'm not aware of any reports using DHA as a Strecker reagent in vitro, but it has been suggested that Strecker reactions could mediate DHA toxicity in vivo.

Crowfjord - 24-5-2016 at 15:45

JJay: Did you see my post in that same thread? In order to isolate aldehyde in any decent yield, dilute conditions and pH control (buffer) are important. I can post the entire article later, if desired. I thought I had already posted it somewhere, but I can't find it.

JJay - 24-5-2016 at 16:26

From https://www.erowid.org/archive/rhodium/chemistry/indoleaceta...

Quote:

Preparation of 3-Indoleacetaldehyde from Tryptophan

To 100 ml. of distilled water were added 15 ml. of 10% NaOH solution and 3.0 g. of DL-tryptophan. After the tryptophan was completely dissolved, 4 N HCl was added until tryptophan crystals just started to separate at a pH near 8.5. The solution was diluted immediately with 1200 ml. of distilled water in a 4000-ml. Erlenmeyer flask. To this solution was added 700 ml. benzene followed by 200 ml. of 0.52% sodium hypochlorite solution made by mixing 1 part Chlorox with 9 parts water. The flask and contents were shaken with a swirling motion immediately after the addition of the hypochlorite and during the entire duration of the experiment so that the aldehyde was taken up in the benzene as soon as it was produced. Care was taken to avoid an excess of hypochlorite which produced brown-colored products. This also happened if dilute solutions were not used. The flask was immersed in a hot water bath, and the temperature of the contents was raised to 50 degrees C. over a period of 20 min. The temperature was held between 50 and 51 degrees C. for 15 min. more. The benzene layer became yellow in color and later turned orange. The benzene was separated from the aqueous phase with a separatory funnel while still warm.

The benzene solution was concentrated to 65 ml. in a large evaporating dish placed in a swift current of air in a fume hood. Slight heat was supplied with a warm water bath at 40-50 degrees C. The resulting benzene solution was shaken with 50 ml. of saturated sodium bisulfate solution in a closed wide-mouth bottle. Crystals of the IAc.NaHSO3 formed immediately and were filtered almost dry by suction.. The product was resuspended twice and shaken vigorously in 95% ethanol and filtered each time. The crystals were washed again with absolute alcohol and finally with ether. After drying at room temperature, the yield was 4.06 g. of white crystalline material. The yield was 90% of theoretical based on the amount of tryptophan used. Most of the IAc.NaHSO3 was dissolved in a small amount of water making a saturated solution. The solution was filtered, and the IAc.NaHSO3 was recrystallized by adding absolute ethanol to a final concentration of 90% ethanol, yielding 2.5 g. of recrystallized product.

To obtain the free aldehyde, 200 mg. of the IAc.NaHSO3 was dissolved in 8 ml. water. A few drops of a saturated solution of Na2CO3 was added until the solution turned slightly turbid. After standing a few minutes, the free aldehyde was extracted by shaking the solution with three portions of peroxide-free ether. After evaporation of the ether and drying at reduced pressure, 82 mg. IAc was obtained as a colorless sirupy liquid.


I suspect that the major step I left out was the heating step. It also looks as if I should have used twice as much hypochlorite.

That seems like an awful waste of benzene... with such a dilute aqueous solution, it may be required to ensure that two layers form, but wouldn't the nitrogen in the amino acid be considerably more nucleophilic than the carbonyl in the aldehyde? And the hypochlorite oxidation is SN2, right?

I'm not that concerned about forming a little tar.

[Edited on 25-5-2016 by JJay]

[Edited on 25-5-2016 by JJay]

JJay - 24-5-2016 at 16:28

Quote: Originally posted by Crowfjord  
JJay: Did you see my post in that same thread? In order to isolate aldehyde in any decent yield, dilute conditions and pH control (buffer) are important. I can post the entire article later, if desired. I thought I had already posted it somewhere, but I can't find it.


Found it: https://www.sciencemadness.org/whisper/viewthread.php?tid=22...

Those are indeed extremely dilute reaction conditions. I don't see how a phosphate buffer would be beneficial under those conditions, but maybe I'm missing something... I think pH could matter, but I'm trying to wrap my head around exactly why.



[Edited on 25-5-2016 by JJay]

Crowfjord - 24-5-2016 at 22:05

Here's the paper and supplemental materials.

Facile one-pot synthesis of tetrahydroisoquinolines from
amino acids via hypochlorite-mediated decarboxylation
and Pictet–Spengler condensation


Maresh, J. et. al.
Tetrahedron Letters 55 (2014) 5047–5051



Attachment: Facile one-pot synthesis of tetrahydroisoquinolines from amino acids via hypochlorite-mediated decarboxylation and Picte (815kB)
This file has been downloaded 1033 times

Attachment: Facile one-pot synthesis of tetrahydroisoquinolines from amino acids via hypochlorite-mediated decarboxylation and Picte (2.7MB)
This file has been downloaded 1231 times


JJay - 25-5-2016 at 01:18

I can't seem to find Figure S2, referenced in the PDF. The other file appears to be a Microsoft Word file and has a caption for it, but I don't see the figure.

Crowfjord - 25-5-2016 at 07:19


I converted the supplementary materials to a PDF. Maybe that will help.



Attachment: Supplementary Info.pdf (3.4MB)
This file has been downloaded 943 times

[Edited on 25-5-2016 by Crowfjord]

Cryolite - 25-5-2016 at 11:02

Another potential route to phenylacetaldehyde from phenylalanine would be oxidation to phenylacetonitrile with TCCA (DOI: 10.1055/s-0029-1218827), followed by reduction of the nitrile to the aldehyde, via a great many possible methods: SnCl2/HCl is the classical Stephen aldehyde synthesis, Helvetica Chemica Acta 243, pg 2560 claims that zinc/AcOH/cobalamin works, but the reference is in German, and http://www.scielo.org.za/pdf/sajc/v61/27.pdf discusses several methods using Raney nickel.

This is two steps as opposed to one, and phenylacetonitrile is a DEA listed precursor (really, what isn't when talking about ethylbenzene derivatives?), but both reactions can proceed in fairly concentrated conditions and are high yielding and well documented-- the yield of phenylacetonitrile in DOI: 10.1081/SCC-200030958 by TCCA oxidation is 77% after purification.

[Edited on 25-5-2016 by Cryolite]

DraconicAcid - 25-5-2016 at 11:09

Quote: Originally posted by Crowfjord  

I converted the supplementary materials to a PDF. Maybe that will help.


My computer doesn't recognize that as a pdf....

careysub - 25-5-2016 at 11:33

Quote: Originally posted by DraconicAcid  
Quote: Originally posted by Crowfjord  

I converted the supplementary materials to a PDF. Maybe that will help.


My computer doesn't recognize that as a pdf....


Try editing the very long file name to include ".pdf" on the end after it is dowloaded.

Generally it is a bad idea to try to make an abstract into a file name.

JJay - 25-5-2016 at 12:28

I can see the figure in that PDF. Upon giving this further thought, I suppose that I should be thinking about the intermediates when considering side reactions and the effects of differing reaction conditions... I really need to find a better description of the mechanism than a short Wikipedia article....

It looks as though they think that 5 mmol is the optimum concentration (for tyrosine oxidation). I have to wonder about the concentrations of these byproducts....

I found this old paper on hypochlorite oxidations of amino acids... Langheld claimed to have obtained 2.5 grams of isoveraldehyde from 5 grams of leucine, which he first made into a sodium salt and then reacted (in strong concentration--I'm not completely sure I'm understanding this, but it looks like 50 mL of water was used) with 0.1 M hypochlorite. That works out to a 76% yield. I don't speak German, but it looks to me as though he removed the product by steam distillation (isoveraldehyde forms an azeotrope with water at 70 C).

I'm still not seeing why removing the product as it forms would be terribly necessary, though it would improve yields... of course, phenylacetaldehyde would be harder to remove by distillation.... I might give this a try later today with phenylalanine and isolate the product with nonpolar extraction / bisulfite adduct formation and see if I get anything.

Attachment: Uber den Abbau der alpha-Aminosauren zu fetten Aldehyden mittels Natriumhypochlorit.pdf (101kB)
This file has been downloaded 709 times

[Edited on 25-5-2016 by JJay]

Crowfjord - 25-5-2016 at 14:18

Quote: Originally posted by careysub  
Quote: Originally posted by DraconicAcid  

My computer doesn't recognize that as a pdf....


Try editing the very long file name to include ".pdf" on the end after it is dowloaded.

Generally it is a bad idea to try to make an abstract into a file name.


Sorry about that. I edited the post and file for everyone's convenience.

zed - 26-5-2016 at 15:00

Ummm. Theoretically, trans-amination would do the trick.

Formation of Phenyl-pyruvic acid, followed by decarboxylation.

That being said. Regarding hypochlorite.... I would carefully follow a known procedure, first. Before, trying to tweak reaction conditions. Guys have reported dismal results, even when they towed the line.

I am reminded of a passage from SNL. There is a little bit of Eve in all of us.

http://www.hulu.com/watch/606107




JJay - 26-5-2016 at 21:00

Reading over that German paper again... at high magnification, it looks like Langheld used 4/10 N (??) hypochlorite. The numbers in the concentration of sodium hydroxide are obscured, but I can't see how they could be anything other than 1/4 N. That's consistent with others who have cited the paper who have said that the reaction was carried out in alkali (I'm referring in particular to Schonberg and Maubacher's "The Strecker Degradation of α-Amino Acids"). So his initial experiment translates something like: "The amino acid (about 0.1 g) was dissolved in .25 M sodium hydroxide (1-2 mL) and then combined with 2 mL of 0.4 M sodium hypochlorite." This works out to a stoichiometric amount of hypochlorite.... Langheld believed that sodium hypochlorite chlorinated the amino acid at the nitrogen, and that the product hydrolized to an imine - giving off hydrochloric acid and carbon dioxide, and that the imine hydrolized in the presence of water to the aldehyde.

I'm not sure what the role of alkali is here... I'm actually wondering why this isn't done in glacial acetic acid... there is water in the hypochlorite solution....







[Edited on 27-5-2016 by JJay]

Refinery - 9-5-2020 at 12:48

The Phenylalanine definitely produces phenylacetaldehyde in such amounts that it is clearly detectable.

I dissolved 1g of L-Phen in 50mL of water and added 3mL of bleach and heated it at water bath. The aldehyde smell of flowers hit the air immediately after first drop, and soon after my whole apartment smells like flowers. I kinda like the smell, but it gets sort of annoying after a while. My flatmate turned right after 2 minutes to ask what is that smell. The solution turned yellowish after a while, and when the flask was moved to salt ice bath, it turned cloudy. After an hour a few particles have settled to the bottom, but mostly it is just colloidal solution if anything. Note, this is not balanced reaction, just a proof of concept that something actually happens. Having a bag of L-Phen hanging around, could consider running an actual balanced reaction to find out if anything can be extracted.

I detect this smell from previous test where styrene was oxidized and then isomerized.

JJay - 9-5-2020 at 14:17

As it turns out, monochlorination of phenylalanine leads to a degradation that produces phenylacetaldehyde, and dichlorination produces phenylacetonitrile, which is responsible for most of the odor: https://www.sciencedirect.com/science/article/abs/pii/S00431...

I will be checking this forum infrequently for the next few months, but I will be back for a short time in August and hopefully shoot some colorimetry demonstrations.



[Edited on 10-5-2020 by JJay]

arkoma - 10-5-2020 at 11:40

Quote: Originally posted by JJay  
As it turns out, monochlorination of phenylalanine leads to a degradation that produces phenylacetaldehyde, and dichlorination produces phenylacetonitrile, which is responsible for most of the odor: https://www.sciencedirect.com/science/article/abs/pii/S00431...

I will be checking this forum infrequently for the next few months, but I will be back for a short time in August and hopefully shoot some colorimetry demonstrations.



[Edited on 10-5-2020 by JJay]


Your back.......Yay