Green Synthesis, Composition Analysis and Surface Active Properties of Sodium Cocoyl Glycinate

Cocoyl glycine was synthesized directly from coconut oil and sodium glycinate in yield of 87%. IR, ESI-MS and LC/MS analysis results showed that cocoyl glycine consists of a series of acyl glycines with different acyl chain lengths, and the proportion of each component was consistent with the composition of fatty acids derived from coconut oil. The surface tension and the Critical Micelle Concentration (CMC) of corresponding sodium salt were evaluated. The result showed that sodium cocoyl glycinate reduced the surface tension of water to a minimum value of approximately 33 mN·m at CMC of 0.21 mmol·L.


Introduction
Acyl amino acid surfactants are considered modified fatty acids in which the hydrocarbon chains are interrupted by an amido linkage, which imparts greater solubility and enhances adsorption characteristics compared to the parent fatty acids [1].These surfactants are widely used in consumer product formulations because they interact favorably with skin and hair, and are of low toxicity and hypoallergenic, also do not cause eye irritation, and are readily biodegradable [2,3].Moreover, acyl amino acid surfactants have better stability towards hard water and high concentration electrolyte, and many of them possess excellent emulsifying and antimicrobial activities, which render them valuable as additives in the formulation of food, cosmetics, personal care and pharmaceutical products [1,[4][5].
Acyl amino acids are produced commercially by the Schotten-Baumann reaction in which condensation of a fatty acyl chloride with an amine is carried out under alkaline conditions [6][7][8][9][10], and the crude sodium salt is acidified to liberate the free fatty amino acid, which can be neutralized to form the corresponding salts, taking cocoyl glycine as an example shown in Figure 1, where RCO-represents the fatty acids derived from coconut oil.
However, the aforementioned process for acyl amino acids production usually uses toxic and irritant fatty acyl chlorides, as well as PCl 3 or SOCl 2 , giving rise to environmental pollution and also leading to undesirable odor and irritation of final products, which cannot be got rid of even by further purification steps.Some researchers have endeavoured to overcome such drawbacks by using biocatalysis instead of chemical process [11][12][13][14].Indeed, enzymatic reactions are alternative owing to their mild reaction conditions and the limited use of chemicals.Nevertheless, bio-catalytic reactions usually require long reaction time and high-cost, and bring about relatively low yields in some cases.
In this work, the green synthesis of cocoyl glycine directly from coconut oil and sodium glycinate was introduced, shown in Figure 2, where RCO-represents the fatty acids derived from coconut oil.
This process is simplified compared to Schotten-Baumann condensation.Most important of all, it is environmental-friendly, because of employing no toxic and irritant reagents.This paper describes the green production, characterization and composition analysis of cocoyl glycine using IR, ESI-MS and LC/MS methods, as well as surface active properties of sodium cocoyl glycinate.

Materials
Coconut oil was obtained from Kerry Oleochemical Industrial Co. Ltd., Shanghai.Glycine was provided by Biodee Biotechnology Co., Ltd., Beijing.Methanol and Formic acid (HPLC grade) were purchased from Dikma Technologies Inc., Beijing.Other materials and reagents were used as received.

Experimental Methods
The infrared (IR) spectra were recorded on a Thermo Fisher Nicolet iS10 FT-IR Spectrometer at room temperature (KBr).
Aqueous solution equilibrium surface tension values were obtained by the Wilhelmy plate method using a Dataphysics tensiometer, model DCAT11.The CMC value was taken at the intersection of the linear portions of the plots of the surface tension against the logarithm of the surfactant concentration.Surfactant solutions were prepared with distilled, deionized water.Sample temperatures were stable at 25˚C ± 0.2˚C.

Synthesis of Cocoyl Glycine
Sodium glycinate was obtained from glycine neutralized with NaOH aqoeous solution in a three-necked flask.After the water was evaporated, stoichiometric coconut oil and catalytic amount of CH 3 ONa were added with stirring, and the reaction solution was heated to about 160˚C and stirred for 4 -5 h.The reaction mixture was cooled to 60˚C and dissolved in water with acidification by HCl solution, leading to a white precipitate of cocoyl glycine in a yield of 87%.

Characterization of Cocoyl glycine
IR spectra of coconut oil and cocoyl glycine are shown in Figure 3.In comparison to starting material coconut oil, the appearance of new peaks at about 3310 cm −1 and 1643 cm −1 indicates the formation of amido linkage, which are ascribed to the N-H and C = O stretching vibration of the acylamino group, respectively [10,11].The absorption at about 1742 cm −1 is ascribed to the C = O stretching vibration of the ester linkage, While at about 1698 cm −1 is ascribed to the C = O stretching vibration of the carboxyl group.
Since coconut oil is a mixture of various triglycerides, the fatty acids of which consist of octanoic acid, decanoic acid, lauric acid, myristic acid, palmitic acid, stearic acid and a few unsaturated fatty acids [15,16].Consequently, the target product cocoyl glycine is also a mixture including a series of compounds with different acyl chain length.
Full-scan mass spectrum (ESI − ) of cocoyl glycine is shown in  and stearyl glycine, respectively.These results are consistent with aforesaid expectation.

LC/MS Analysis
The surface properties of acyl amino acid surfactants are closely related to their structures, such as their acyl chain length [4].It is essential to explore the composition of cocoyl glycine by LC/MS analysis.
The total ion chromatorgraphy of cocoyl glycine is shown in Figure 5. Ascription of each single peak is according to mass spectra at corresponding retention time, shown in Figure 6.While the mass spectrum at 17.39min (C18:2) is not listed due to weak singals.It is also shown that cocoyl glycine consists of a series of acyl glycines with different acyl chain length according to LC/MS results.A summary of the data is complied in Table 1.The most prominent component in cocoyl glycine is lauryl glycine (C12:0) (43%), and myristyl glycine (C14:0) (21%) takes the second place.Besides a series of saturated homologous compounds, there are also a few unsaturated acyl glycines (C18:1, C18:2) (7%, 1%) in the mixture.
This outcome is approximately in line with the reported results about fatty acid composition of coconut oil [15,16], which indicates that acylation of glycine has no selectivity for fatty acids with different chain length.

Equilibrium Surface Tension Measurements
The synthesized cocoyl glycine is in its acidic form, having free carboxylic group.Since the surface activity of surfactants is ensured by the presence of both hydrophilic and hydrophobic parts, the cocoyl glycine was neutralized with a NaOH solution in order to provide the affinity for water.
The equilibrium surface tensions of dilute aqueous solutions of sodium cocoyl glycinate were measured and shown in Figure 7.
The minimum surface tension (γ CMC ) values were acquired by analyzing the plateau region of the plots.The critical micelle concentrations (CMC) of sodium cocoyl glycinate were acquired by analyzing the intersection point of the plateau region and the steeply downward sloping portion of the plots.
The surface excess of sodium cocoyl glycinate at the CMC (Γ max ) was obtained from the Gibbs absorption equation: where γ represents the surface tension in mN•m −1 , R is the gas constant (8.3144J•mol −1 •K −1 ), T is absolute temperature, C is surfactant concentration,  γ/  logC was obtained from the slope of the linear surface tension (γ) versus logC plot.In our solution, we can set n = 1 [17].
The minimum area of the amphiphile head group at the surfactant saturated monolayer at the air/solution interface (A min ) was obtained from the relation: where N A is Avogadro's number.The free energy of micellization (ΔG) of sodium cocoyl glycinate was obtained from the CMC value.
The interfacial parameters are presented in Table 2. Sodium cocoyl glycinate reduced the surface tension of water to a minimum value of approximately 33 mN•m −1 at the CMC of 0.21 mmol•L −1 .While the CMC of sodium lauroyl glycinate was 12 mmol•L −1 [18], which is higher than that of sodium cocoyl glycinate by two orders of magnitude [18].Similarly, the CMC of sodium lauroyl sarcosinate produced was 14.3 mmol•L −1 at 298 K [19], which is also much higher than that of sodium cocoyl glycinate [19].For sodium salts of stearoyl amino acids, the CMC was about 10 −3 magnitude [20], which is higher than that of sodium cocoyl glycinate by one order of magnitude as well.
The Γ max value of sodium cocoyl glycinate is larger than that of sodium lauroyl sarcosinate, while the A min is less than the latter [19].This results from smaller hydrophilic head group of glycinate.The ΔG value reveals that the process of micellization in solution is thermodynamically favored.

Conclusions
Cocoyl glycine was synthesized using coconut oil and sodium glycinate as raw materials.To the best of our knowledge, this is the first time to employ oil (fatty acid glyceride) as acylation regent rather than fatty acyl chloride to prepare acyl amino acid surfactants.
The structure and composition of cocoyl glycine have been identified by IR, ESI-MS and LC/MS analysis.The results showed that cocoyl glycine consists of a series of acyl glycines with different acyl chain lengths, and the proportion of each component is consistent with the composition of fatty acids derived from coconut oil.
The equilibrium surface tension results showed that sodium cocoyl glycinate possesses considerably lower CMC than that of sodium lauroyl glycinate, sodium lauroyl sarcosinate, and sodium salts of stearoyl amino acids as well, which may be related to its multi-constituents.It is very attractive to investigate the composition-property relationship of sodium cocoyl glycinate and other oleo-based amino acid surfactants thoroughly.

Figure 2 .
Figure 2. Green synthesis of cocoyl glycine from coconut oil and sodium glycinate.

Figure 7 .
Figure 7. Plot of equilibrium surface tensions of aqueous solution of sodium cocoyl glycinate versus log mole concentration.