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Benzocaine Synthesis

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I. Introduction Esters are important compounds in organic chemistry. They are used in numerous types of synthetic reactions, to create different products for a vast array of purposes, including medicinal and cosmetic. To produce an ester, one can utilize an esterification reaction. In particular, the Fischer Esterification reaction was used in this lab to turn a carboxylic acid into an ester benzocaine. Esters are used in a wide range of fields, including the medical, cosmetology and fuels industry. For instance, biodiesel fuel is an alternative fuel source that is composed mainly of monoalkyl esters from vegetable oil or animal fats (1). Green, alternative energy sources are highly sought after in the increasingly global economy, which brings high importance to perfecting the synthesis of esters that can contribute to this. Other esters are used for their strong fruity smells in cosmetology for perfumes, while still others are used as flavor additives in foods. Benzocaine is an ester that has been used in the medical industry as a local anasethetic for decades. Some contribute the use of benzocaine as an anesthetic to cause methemoglobinemia, which is a negative disorder that is caused by high levels of methemglobin in the blood. A case has been documented of an 83 year old man who was diagnosed with methemoglobinemia and had symptoms of cyanosis and cardiovascular instability after benzocaine was used as the local anesthetic for a surgery. This was considered an extreme case however, and benzocaine is still used as a local anesthetic, and for commercial nasal and throat sprays for its numbing effect (2). Benzocaine is also used to dilute or “cut” illegal cocaine due to its similar appearance, and availability (3). 1
The mechanism of the Fischer Esterification that was utilized to produce benzocaine is very straightforward carbonyl chemistry. It begins with the carbonyl oxygen of a carboxylic acid being protonated by the catalytic sulfuric acid. Once the double bond is broken, the lone pair of the ethanol oxygen backside attacks the carbonyl carbon, forming the classic tetrahedral intermediate. The oxygen of the new ethanol substituent has a positive charge; this causes the lone pairs of the sulfuric acid to attack the hydrogen of the ethanol. Next, the lone pairs on the hydroxyl group attack a hydrogen atom from sulfuric acid, forming water, a quality leaving group. The lone pairs on the remaining hydroxyl group swing down to form a double bond with carbon and displace the water. The sulfuric acid then relieves the double bonded oxygen of the extra hydrogen and its unwanted positive charge. The final product is benzocaine, an ester. Figure 1: Fischer Esterification Mechanism of the Formation of Benzocaine 2
The purpose of this lab is to synthesize benzocaine, an ester, from p-aminobenzoic acid, a carboxylic acid, by Fischer Esterification. This is a common mechanism in organic chemistry, and its mastery is important in learning how carbonyl compounds behave. P-aminobenzoic acid will be combined with ethanol and sulfuric acid in a reflux reaction to yield the desired product. This product with then be analyzed by melting point, NMR, IR, and GC-MS to confirm its identity as benzocaine. A percent yield will be calculated to determine how much benzocaine was produced in lab, in comparison to how much was physically possible to synthesize. II. Experimental Benzocaine. P-aminobenzoic acid (119mg) and absolute ethanol (1.5mL) were added to a microscale reaction tube and heated with a sandbath until dissolved. The mixture was then cooled with ice and concentrated sulfuric acid (0.20mg) was added dropwise. An air condenser was used to reflux the reaction for one hour. The reaction mixture was then cooled to room temperature. The reaction mixture was transferred via Pasteur pipet to a 10-mL Erlenmeyer flask. Distilled water (3mL) was added. 1M sodium bicarbonate (3mL) was added dropwise; the reaction mixture was agitated after each addition. The pH was monitored until the reaction was sufficiently neutral (pH 8). A Hirsch funnel was then used in vacuum filtration to isolate the product. Crystals were washed with cold distilled water (3x 1mL). White, flaky crystals (85.8%) were dried over night. Melting Point : 88-89⁰C. Chemical Shift Splitting Pattern Integral Value 1.263 ppm Triplet 3 4.140 ppm Quartet 2 5.927 ppm Singlet 2 3
6.484 ppm Doublet 2 7.568 ppm Doublet 2 Figure 2: 1H NMR (60 MHz, CDCl3 ) for Benzocaine Functional Group Absorption Frequency (cm-1) N-H 3419.0 C-H for C6H6 3219.4 C=O for ester 1679.2 Figure 3: IR (ATR) for Benzocaine Component RT M/Z Percent Composition Benzocaine 18.94 165.0 100.00% Figure 4: GC-MS for Benzocaine III. Results and Discussions Fischer Esterification was used to synthesize benzocaine from p-aminobenzoic acid, or PABA. PABA was combined with excess absolute ethanol and catalytic sulfuric acid and was allowed to reflux for over an hour. Sodium bicarbonate was then added to neutralize the excess acid. The benzocaine crystals were then vacuum filtrated and washed with cold water to maximize yield and were allowed to dry overnight. Once dry, the crystals were analyzed by melting point, NMR, IR, GC-MS, and a percent yield was calculated. The theoretical yield of benzocaine was 144.5mg of product. The actual yield was 124.0mg, giving a percent yield of 85.8%. This is a high percent yield, indicating a successful synthesis. The melting point recorded in lab was 88-89⁰C; this is very close to the literature value of 88-90⁰C. This accuracy in melting point indicates a pure product. Impurities in the 4
benzocaine product would depress the melting point, and cause a wider melting point range. The short range and accuracy implies a successful synthesis. NMR was also used to analyze the product synthesized in lab. Five different peaks appeared in the NMR spectra of benzocaine (Figure 2, Supplemental Data), correlating to five different sets of chemically different protons. The first peak at 1.146ppm with an integral value of three displayed the protons at the end of the ethyl group bonded to the non-carbonyl oxygen of the ester as a triplet. Because these hydrogen atoms are the farthest from the electron withdrawing oxygen atoms, it makes sense that they would have the lowest chemical shift, and suffer the most shielding of all the protons of the molecule. The next peak, a quartet, at 4.140ppm corresponds to the hydrogen atoms on the carbon bonded to the non-carbonyl oxygen atom of the ester. This CH2 group has less shielding than the aforementioned CH3 group, and thus a higher chemical shift because it is closer to the oxygen atoms of the compound. The third peak at 5.927ppm displays the two hydrogen atoms bonded to the amine substituent on the benzyl functional group. These protons are deshielded by the nitrogen atom, but are not as shifted as far as the next two peaks because they are so far from the oxygen atoms of the ester. The next peak, a doublet with a chemical shift of 6.48ppm shows the symmetrical hydrogen atoms on the benzene ring closest to the ester substituent. These two protons are shifted so far down due to the deshielding caused by the ester and the amine substituents. The final peak at 7.568ppm is a doublet that shows the two symmetrical protons on the benzene ring closest to the amine group. These protons are close enough to the carbonyl ester and the amine to be deshielded the most and to have the highest chemical shift. This NMR spectrum accounted to for all the protons benzocaine should have, with peaks that had chemical shifts that made sense, indicating that it indeed was representing benzocaine. 5
IR was also a useful mode of analysis for the final results of the reaction. Several important peaks in the IR spectrum of benzocaine (Figure 3, Supplemental Data) were used to identify the product as benzocaine. A short sharp spike at 3419.0cm-1 indicates the presence of a nitrogen-hydrogen bond on the molecule, which corresponds to the structure of benzocaine. A peak at 1679.2cm-1 shows the ester group of benzocaine. An alcohol spike did not appear at 3500cm-1, which indicates the starting material, p-aminobenzoic acid, which has the OH group on the carboxylic acid, was not present in the IR sample. This shows that the reaction successfully went to completion. GC-MS was also used to analyze the crystals produced in lab. Only one peak was present in the GC-MS chromatogram (Figure 4, Supplemental Data). A peak appeared at 18.94 minutes; this corresponded to the peak on mass spectrum that had a value of 165.0m/z. This is exactly the molecular weight of benzocaine, which indicates that this is what was in the crystals produced in lab. Other ions of benzocaine were present in the mass spectrum, including a peak at 150.12m/z, which displays the ion of benzocaine that is missing the nitrogen group off of the benzene ring. Another peak in the mass spectrum was at 91.95m/z, which displays the ion that is lacking the ester group on the benzene ring. All of these molecular weight values line up with what the weight of the ion would be if it was missing said functional groups. This indicates that the GC-MS does indeed depict benzocaine, the desired product of the Fischer Esterification reaction. IV. Conclusion Fischer Esterification was used as a means to synthesize benzocaine, an ester, from p- aminobenzoic acid, a carboxylic acid. This is done by adding excess alcohol, in this case 6
ethanol, and catalytic sulfuric acid. The reaction takes place as a reflux, and yields large, white and flaky crystals. These crystals are the benzocaine product, and their identity was confirmed by melting point, NMR, IR, and GC-MS analysis. These techniques all gave confirming results that the crystals produced in lab were the desired benzocaine product. 7
V. References (1) Wang, P.S.; Tat, M.E.; Gerpen J.V. The Production of Fatty Acid Isopropyl Esters and their Use as a Diesel Engine Fuel. Journal of the American Oil Chemist’s Society. Springer, 2011. Volume 82, Number 11, 845-849. (2) Rodriguez, L.F.; Smolik, L.M.; Zbehlik, A.J. Benzocaine-induced Methemoglobinemia. The Annals of Pharmacotherapy. Harvey Whitney Books Company, 2012. Volume 28, Number 5, 643-649. (3) Freye, E.; Levy, J.V. Pharmacology, and Abuse of Cocaine, Amphetamines, Ecstasy, and Related Designer Drugs. Springer, 2009. 36. (4) Rummel, S.A. Lab Guide for Chemistry 213: Introductory Organic Chemistry Lab. Hayden, McNeil, 2011, pgs 65-82, 295-308. 8

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Benzocaine Synthesis

  • 1. I. Introduction Esters are important compounds in organic chemistry. They are used in numerous types of synthetic reactions, to create different products for a vast array of purposes, including medicinal and cosmetic. To produce an ester, one can utilize an esterification reaction. In particular, the Fischer Esterification reaction was used in this lab to turn a carboxylic acid into an ester benzocaine. Esters are used in a wide range of fields, including the medical, cosmetology and fuels industry. For instance, biodiesel fuel is an alternative fuel source that is composed mainly of monoalkyl esters from vegetable oil or animal fats (1). Green, alternative energy sources are highly sought after in the increasingly global economy, which brings high importance to perfecting the synthesis of esters that can contribute to this. Other esters are used for their strong fruity smells in cosmetology for perfumes, while still others are used as flavor additives in foods. Benzocaine is an ester that has been used in the medical industry as a local anasethetic for decades. Some contribute the use of benzocaine as an anesthetic to cause methemoglobinemia, which is a negative disorder that is caused by high levels of methemglobin in the blood. A case has been documented of an 83 year old man who was diagnosed with methemoglobinemia and had symptoms of cyanosis and cardiovascular instability after benzocaine was used as the local anesthetic for a surgery. This was considered an extreme case however, and benzocaine is still used as a local anesthetic, and for commercial nasal and throat sprays for its numbing effect (2). Benzocaine is also used to dilute or “cut” illegal cocaine due to its similar appearance, and availability (3). 1
  • 2. The mechanism of the Fischer Esterification that was utilized to produce benzocaine is very straightforward carbonyl chemistry. It begins with the carbonyl oxygen of a carboxylic acid being protonated by the catalytic sulfuric acid. Once the double bond is broken, the lone pair of the ethanol oxygen backside attacks the carbonyl carbon, forming the classic tetrahedral intermediate. The oxygen of the new ethanol substituent has a positive charge; this causes the lone pairs of the sulfuric acid to attack the hydrogen of the ethanol. Next, the lone pairs on the hydroxyl group attack a hydrogen atom from sulfuric acid, forming water, a quality leaving group. The lone pairs on the remaining hydroxyl group swing down to form a double bond with carbon and displace the water. The sulfuric acid then relieves the double bonded oxygen of the extra hydrogen and its unwanted positive charge. The final product is benzocaine, an ester. Figure 1: Fischer Esterification Mechanism of the Formation of Benzocaine 2
  • 3. The purpose of this lab is to synthesize benzocaine, an ester, from p-aminobenzoic acid, a carboxylic acid, by Fischer Esterification. This is a common mechanism in organic chemistry, and its mastery is important in learning how carbonyl compounds behave. P-aminobenzoic acid will be combined with ethanol and sulfuric acid in a reflux reaction to yield the desired product. This product with then be analyzed by melting point, NMR, IR, and GC-MS to confirm its identity as benzocaine. A percent yield will be calculated to determine how much benzocaine was produced in lab, in comparison to how much was physically possible to synthesize. II. Experimental Benzocaine. P-aminobenzoic acid (119mg) and absolute ethanol (1.5mL) were added to a microscale reaction tube and heated with a sandbath until dissolved. The mixture was then cooled with ice and concentrated sulfuric acid (0.20mg) was added dropwise. An air condenser was used to reflux the reaction for one hour. The reaction mixture was then cooled to room temperature. The reaction mixture was transferred via Pasteur pipet to a 10-mL Erlenmeyer flask. Distilled water (3mL) was added. 1M sodium bicarbonate (3mL) was added dropwise; the reaction mixture was agitated after each addition. The pH was monitored until the reaction was sufficiently neutral (pH 8). A Hirsch funnel was then used in vacuum filtration to isolate the product. Crystals were washed with cold distilled water (3x 1mL). White, flaky crystals (85.8%) were dried over night. Melting Point : 88-89⁰C. Chemical Shift Splitting Pattern Integral Value 1.263 ppm Triplet 3 4.140 ppm Quartet 2 5.927 ppm Singlet 2 3
  • 4. 6.484 ppm Doublet 2 7.568 ppm Doublet 2 Figure 2: 1H NMR (60 MHz, CDCl3 ) for Benzocaine Functional Group Absorption Frequency (cm-1) N-H 3419.0 C-H for C6H6 3219.4 C=O for ester 1679.2 Figure 3: IR (ATR) for Benzocaine Component RT M/Z Percent Composition Benzocaine 18.94 165.0 100.00% Figure 4: GC-MS for Benzocaine III. Results and Discussions Fischer Esterification was used to synthesize benzocaine from p-aminobenzoic acid, or PABA. PABA was combined with excess absolute ethanol and catalytic sulfuric acid and was allowed to reflux for over an hour. Sodium bicarbonate was then added to neutralize the excess acid. The benzocaine crystals were then vacuum filtrated and washed with cold water to maximize yield and were allowed to dry overnight. Once dry, the crystals were analyzed by melting point, NMR, IR, GC-MS, and a percent yield was calculated. The theoretical yield of benzocaine was 144.5mg of product. The actual yield was 124.0mg, giving a percent yield of 85.8%. This is a high percent yield, indicating a successful synthesis. The melting point recorded in lab was 88-89⁰C; this is very close to the literature value of 88-90⁰C. This accuracy in melting point indicates a pure product. Impurities in the 4
  • 5. benzocaine product would depress the melting point, and cause a wider melting point range. The short range and accuracy implies a successful synthesis. NMR was also used to analyze the product synthesized in lab. Five different peaks appeared in the NMR spectra of benzocaine (Figure 2, Supplemental Data), correlating to five different sets of chemically different protons. The first peak at 1.146ppm with an integral value of three displayed the protons at the end of the ethyl group bonded to the non-carbonyl oxygen of the ester as a triplet. Because these hydrogen atoms are the farthest from the electron withdrawing oxygen atoms, it makes sense that they would have the lowest chemical shift, and suffer the most shielding of all the protons of the molecule. The next peak, a quartet, at 4.140ppm corresponds to the hydrogen atoms on the carbon bonded to the non-carbonyl oxygen atom of the ester. This CH2 group has less shielding than the aforementioned CH3 group, and thus a higher chemical shift because it is closer to the oxygen atoms of the compound. The third peak at 5.927ppm displays the two hydrogen atoms bonded to the amine substituent on the benzyl functional group. These protons are deshielded by the nitrogen atom, but are not as shifted as far as the next two peaks because they are so far from the oxygen atoms of the ester. The next peak, a doublet with a chemical shift of 6.48ppm shows the symmetrical hydrogen atoms on the benzene ring closest to the ester substituent. These two protons are shifted so far down due to the deshielding caused by the ester and the amine substituents. The final peak at 7.568ppm is a doublet that shows the two symmetrical protons on the benzene ring closest to the amine group. These protons are close enough to the carbonyl ester and the amine to be deshielded the most and to have the highest chemical shift. This NMR spectrum accounted to for all the protons benzocaine should have, with peaks that had chemical shifts that made sense, indicating that it indeed was representing benzocaine. 5
  • 6. IR was also a useful mode of analysis for the final results of the reaction. Several important peaks in the IR spectrum of benzocaine (Figure 3, Supplemental Data) were used to identify the product as benzocaine. A short sharp spike at 3419.0cm-1 indicates the presence of a nitrogen-hydrogen bond on the molecule, which corresponds to the structure of benzocaine. A peak at 1679.2cm-1 shows the ester group of benzocaine. An alcohol spike did not appear at 3500cm-1, which indicates the starting material, p-aminobenzoic acid, which has the OH group on the carboxylic acid, was not present in the IR sample. This shows that the reaction successfully went to completion. GC-MS was also used to analyze the crystals produced in lab. Only one peak was present in the GC-MS chromatogram (Figure 4, Supplemental Data). A peak appeared at 18.94 minutes; this corresponded to the peak on mass spectrum that had a value of 165.0m/z. This is exactly the molecular weight of benzocaine, which indicates that this is what was in the crystals produced in lab. Other ions of benzocaine were present in the mass spectrum, including a peak at 150.12m/z, which displays the ion of benzocaine that is missing the nitrogen group off of the benzene ring. Another peak in the mass spectrum was at 91.95m/z, which displays the ion that is lacking the ester group on the benzene ring. All of these molecular weight values line up with what the weight of the ion would be if it was missing said functional groups. This indicates that the GC-MS does indeed depict benzocaine, the desired product of the Fischer Esterification reaction. IV. Conclusion Fischer Esterification was used as a means to synthesize benzocaine, an ester, from p- aminobenzoic acid, a carboxylic acid. This is done by adding excess alcohol, in this case 6
  • 7. ethanol, and catalytic sulfuric acid. The reaction takes place as a reflux, and yields large, white and flaky crystals. These crystals are the benzocaine product, and their identity was confirmed by melting point, NMR, IR, and GC-MS analysis. These techniques all gave confirming results that the crystals produced in lab were the desired benzocaine product. 7
  • 8. V. References (1) Wang, P.S.; Tat, M.E.; Gerpen J.V. The Production of Fatty Acid Isopropyl Esters and their Use as a Diesel Engine Fuel. Journal of the American Oil Chemist’s Society. Springer, 2011. Volume 82, Number 11, 845-849. (2) Rodriguez, L.F.; Smolik, L.M.; Zbehlik, A.J. Benzocaine-induced Methemoglobinemia. The Annals of Pharmacotherapy. Harvey Whitney Books Company, 2012. Volume 28, Number 5, 643-649. (3) Freye, E.; Levy, J.V. Pharmacology, and Abuse of Cocaine, Amphetamines, Ecstasy, and Related Designer Drugs. Springer, 2009. 36. (4) Rummel, S.A. Lab Guide for Chemistry 213: Introductory Organic Chemistry Lab. Hayden, McNeil, 2011, pgs 65-82, 295-308. 8