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Lipshutz Surfactants Portfolio

Introduction

Micellar catalysis has emerged as a sustainable mode of chemical synthesis, providing an effective alternative to environmentally egregious and waste-generating organic solvents, replacing them with an aqueous medium containing very limited amounts of a benign-by-design nonionic surfactant. These amphiphiles self-assemble into nanomicelles that host substrates and reagents, and/or catalysts, within their lipophilic cores, enabling their solubilization within a bulk aqueous medium while simultaneously protecting them from interactions with the surrounding water. Thus, reactions involving otherwise water-sensitive reagents (e.g., the in situ formation of organozinc reagents) become possible. Furthermore, the characteristically high concentrations within nanomicelles (typically ca. 2 M) often leads to higher reaction rates than when performed in organic solvents.

Over the last 15 years, the laboratories of Prof. Bruce Lipshutz have engineered a series of “designer” surfactants (so-named as they have been developed to maximize efficiency for reactions performed in water). These are listed below, and range from general purpose amphiphiles to those earmarked for specific needs.

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PTS

This 1st generation surfactant (Figure 1) continues to play an important role in micellar catalysis, as it serves as a testing ground that enables many of the earlier processes, first run in water, to be evaluated.

The structure of the surfactant PTS, also known as Polyoxyethanyl-α-tocopheryl sebacate, highlighting the different parts of the structure, the lipophilic vitamin E on one end, the sebacate linker, and the hydrophilic mPEG on the other end.

Figure 1.The structure of the surfactant PTS also known as Polyoxyethanyl-α-tocopheryl sebacate.

TPGS-750-M

This surfactant (Figure 2), as with PTS, is derived from vitamin E, but contains MPEG-750 attached via an inexpensive succinate linker. Introduced in 2011, it has long been the workhorse enabling a multitude of reactions to be run in water. Its versatility has been noted not only in terms of its usage in chemocatalysis, but also for its prominent role in biocatalyzed processes, which, when both are combined into sequential reactions in water, make it almost indispensable for applications to chemoenzymatic catalysis.

The structure of the surfactant TPGS-750-M, also known as DL-α-Tocopherol methoxypolyethylene glycol succinate, highlighting the different parts of the structure, the lipophilic vitamin E on one end, the succinate linker, and the hydrophilic mPEG on the other end.

Figure 2.The structure of TPGS-750-M which is also known as DL-α-Tocopherol methoxypolyethylene glycol succinate.

Nok (SPGS-550-M)

This 3rd generation surfactant (Figure 3) is constructed from β-sitosterol and MPEG-550, also attached (as with TPGS-750-M) via a succinate linker. It is another general-purpose alternative to vitamin E-based TPGS-750-M (and Savie; vide infra). Unlike most commercial sources of vitamin E used in the manufacture of these surfactants, the price of plant-derived β-sitosterol is not reliant on petroleum, and therefore is typically far less expensive, thereby potentially providing a more cost-effective means of enabling micellar catalysis. Nok has been shown, on occasion, to be an effective alternative to TPGS-750-M in a number of reactions using its nanorod-shaped micelles, rather than the spherical micellar arrays characteristic of the other amphiphiles described herein.

The structure of the surfactant Nok, also known as SPGS-550-M, highlighting the different parts of the structure, the lipophilic β-sitosterol on one end, the succinate linker, and the hydrophilic mPEG on the other end.

Figure 3.The structure of SPGS-550-M also known as NOK.

Savie

Savie (Figure 4) is the latest surfactant being added to the list containing a vitamin E-based lipophilic portion. The MPEG-750 is replaced by polysarcosine (PSar, which is just a polymer of N-methylglycine) that, likewise, enables reactions to be run in water. These range from varying types of Pd-catalyzed transformations to those catalyzed by numerous enzymes, including 1-pot, multistep chemoenzymatic sequences. In comparison to PEGylated surfactants, the PSar section of Savie is known to be fully biodegradable. In water, Savie gives rise to more stable emulsions, thereby reducing the need for organic co-solvents, and leading to more rapid rates of conversions, and hence, higher isolated yields for a given reaction time. It’s powdery consistency (as opposed to the waxes characteristic of PEGylated surfactants, including TPGS-750-M) makes it easy to handle and dispense, and it dissolves in water within seconds.

The structure of the surfactant Savie highlighting the different parts of the structure, the lipophilic vitamin E on one end and the hydrophilic polysarcosine (PSar) on the other end.

Figure 4.The structure of the surfactant Savie.

Coolade

Coolade (Figure 5) is a low-foaming, nonionic surfactant developed for use in gas-utilizing and/or -forming reactions. Surfactants, like soaps, tend to foam due to the hydrocarbon chains usually present in their makeup. With Coolade, however, made from grape-flavoring methyl anthranilate, the lack of such a structural feature leads to little-to-no frothing and hence, a simple solution to reactions that would otherwise require considerable headspace to accommodate gas usage and/or evolution. Applications of Coolade-derived micelles include Ni-catalyzed dehalogenation reactions, nitro group reductions, and the preparation of Pd nanoparticles with NaBH4.

The structure of the surfactant Coolade highlighting the different parts of the structure, the hydrophilic PEG centralized between succinate linkers and the lipophilic methyl anthranilate.

Figure 5.The structure of the surfactant Coolade.

MC-1

MC-1 (Figure 6) is a surfactant designed especially for enabling peptide coupling reactions in water. Its DMSO-like lipophilic core contains a polar sulfone moiety that houses polar amino acid coupling partners within the lipophilic interior of its self-assembled micelles. This simple change leads to greater rates of conversion compared to the purely hydrophobic micellar interiors formed by, e.g., TPGS-750-M.

The structure of the surfactant MC-1 highlighting its DMSO-like lipophilic core.

Figure 6.The structure of the surfactant MC-1.

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References

1.
Klumphu P, Lipshutz BH. 2014. “Nok”: A Phytosterol-Based Amphiphile Enabling Transition-Metal-Catalyzed Couplings in Water at Room Temperature. J. Org. Chem.. 79(3):888-900. https://doi.org/10.1021/jo401744b
2.
Lipshutz BH, Isley NA, Fennewald JC, Slack ED. 2013. Cover Picture: On the Way Towards Greener Transition-Metal-Catalyzed Processes as Quantified by E Factors (Angew. Chem. Int. Ed. 42/2013). Angew. Chem. Int. Ed.. 52(42):10911-10911. https://doi.org/10.1002/anie.201308153
3.
Lipshutz BH, Ghorai S, Abela AR, Moser R, Nishikata T, Duplais C, Krasovskiy A, Gaston RD, Gadwood RC. 2011. TPGS-750-M: A Second-Generation Amphiphile for Metal-Catalyzed Cross-Couplings in Water at Room Temperature. J. Org. Chem.. 76(11):4379-4391. https://doi.org/10.1021/jo101974u
4.
Lipshutz BH, Ghorai S. 2012. "Designer"-Surfactant-Enabled Cross-Couplings in Water at Room Temperature. Aldrichimica Acta. 45(1):3-16.
5.
Lipshutz BH, Ghorai S. 2008. Transition-Metal-Catalyzed Cross-Couplings Going Green: in Water at Room Temperature. Aldrichimica Acta. 41(3):59-72.
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