Enantiomers share the same chemical formula but have different chemical structures, i.e., type of isomers. Enantiomers are present in several drugs, perfumes, food, and are a fundamental part of biomolecules. This subject is highly important for pharmaceutical companies. Enantiomeric drugs present different actuation in the human body; depending on the compound, one might combat the symptom, whereas its pair might cause damage. The separation of pairs of enantiomers requires a chiral environment that provokes a structural imbalance that conventional methods cannot provide. Enantioresolution is one of the most promissory studies that benefit several areas, such as pharmaceutical, biotechnology, food industry, and fine chemistry. Its resolution is of great importance, therefore, its main mechanisms of resolution will be explained herein.
Isomers are different compounds that share the same chemical formula but have different chemical structures. They are classified into structural and stereoisomers. Structural isomers might be subclassified into function, chain, position, metamerism and tautomerism, as exemplified in Table 1, the latter only existing in equilibrium. Stereoisomers are subclassified into diastereomers (diastereoisomers) and enantiomers (optical isomers). Isomers have different physicochemical properties such as their melting point, boiling point, solubility, and density. Enantiomers, unlike other isomers, share all these properties, but optical activity. Enantiomers are analogous to a pair of hands, an enantiomer is a specular image of the other.
Enantiomerism is present in several drugs, perfumes, food, and even in our own body. The response of human organisms to certain enantiomeric compounds might change dramatically depending on the enantiomer: one enantiomer in a drug might treat the disease whereas the other might cause harmful side effect. Thalidomide’s side effect is, perhaps, the most remarkable and unfortunate known case in the literature. It is a drug that was used by pregnant women in the 1960′s in the United Kingdom in order to combat morning sickness. However, the drug caused several birth defects [1]. This drug was sold in an equimolar mixture of enantiomer in which only one of them combats the symptom (eutomer), and the other caused side effects (deutomer) [2].
Large pharmaceutical companies aim to synthesize drugs that are quickly able to combat symptoms or illnesses with the least number of side effects by removing the deutomer. For this reason, enantioresolution is a crucial issue in the pharmaceutical industry. Distillation, decantation, and filtration are common methods of separation for compounds based on boiling point, density, and size, respectively. The resolution of compounds with different physicochemical properties might be simpler in comparison to enantioresolution. The separation of pairs of enantiomers, though, is not straightforward, and conventional methods are nearly ineffective. Crystallization, membrane, or chromatography are examples of processes used to separate enantiomers in a chiral environment, molecules that tend to bind to an enantiomer instead of the other [3].
Table 1. Types of isomers and their structural formula [3].
Optical activity is the phenomenon of shifting in the direction of the light plane when it passes through a compound. Light is an electromagnetic radiation that, when interacting with electrons in a molecule, slightly diverts its direction. Some molecules, though, do not present optical activity, i.e., for any light shift, either to the left or right, there is a molecule that shifts it in the opposite direction, nulling the optical activity. On the other hand, when light passes through pure there is a shift of the light; when light shifts to left, the enantiomer is called levorotatory (receives the prefix or ) and to the right it is called dextrorotatory (receives the prefix or ).
A polarimeter is the instrument responsible for reading the light rotation in degrees of a certain enantiomer concentration. This rotation must be converted into a specific rotation to take in account the polarimeter length and sample concentration, as given by:
A pair of enantiomers does not overlap by either transposition or rotation. The non-overlapping of molecules is known in chemistry as chirality and these compounds are therefore called chirals (from the Greek word χέριa [quéria], meaning hands). In order to be considered chiral, the molecule must have at least one tetrahedral carbon bound to four different groups, as shown in Figure 1. This carbon is known as chiral or asymmetric carbon [4]. There is also the possibility of chirality involving other atoms such as silicon, nitrogen, sulfur and phosphorus, coordination complexes, allenes and atropisomers, as shown in Figure 2; however, these are less common [5].
Figure 1. Chiral carbon (*) bound to four different groups in different representations.
Figure 2. Pairs of enantiomers of (a) chiral silicon, (b) chiral nitrogen, (c) chiral sulfur, (d) chiral phosphorus, (e) cobalt complex, (f) allenes and (g) atropisomers.
Figure 3. Number of enantiomers related to the numbers of chiral carbons (*) for (a) lactic acid and (b) isoleucine.
Figure 4. Tartaric acid presents (a) two enantiomers and (b) a meso isomer.
A pair of enantiomers is formed by two different compounds that must have two different names. The Chemical Abstracts Service Registry Numbers (CAS RN or CAS Number) is a registration system of different compounds. Chemical Abstract Service has registered over 190 million compounds since the XIX century and thousands are registered every day [6]. Its database includes inorganic and organic compounds; metals and alloys; polymers; isotopes; protein and nucleic acids; coordination compounds and organometallics; minerals; and even mixtures. In fact, not only the pure enantiomers, but racemates, a mixture of compounds, have their own CAS Number. For instance, limonene racemate’s, ( )-limonene’s and ( )-limonene’s CAS Numbers are, respectively, 138-86-3, 5989-27-5 and 5989-54-8. The CAS Number does not have a significance itself, as it is just based on the order of registration. On the other hand, prefixes ( and ( ), mentioned in the previous section, designates whether the compound shifts the light to the right or left, and does not distinguish enantiomers when there are four or more enantiomers, as shown in Figure 3b; therefore, this is not a form of naming either.
Pairs of enantiomers are named following a sequence of rules created by the chemists R.S. Cahn, C. Ingold, and V. Prelog. This is known as Cahn-Ingold-Prelog rules or R/S configuration, where R and S stand for rectus and sinister (right and left in Latin). The rules for enantiomer nomenclature are detailed in Table 2.
First, it is necessary to rank the atoms directly bounded to the chiral carbon from largest to smallest atomic number, even in the case of isotopes. When the atoms have the same atomic number, one must follow down to the next substituent until there is a divergence point. Then, the least atomic number substituent is posed at the rear from a 3D perspective (a molecular modeling kit might help), as shown in Table 2. Finally, one draws circle arrows from the first to the third position. If the arrow goes counterclockwise, the enantiomer is S, otherwise is R. This procedure must be repeated when the molecule has other chiral carbons.
It is worth noticing that the prefixes (R) and (S) have no correlation with the shift of light plan, as an enantiomer might receive a prefix (R) and shifts light to left and vice versa. For instance: (R)-limonene has a specific rotation of +12° whereas (R)-butanol presents -13.5°. Another important issue that should be noted that there is another form of nomenclature exclusive for amino acids and monosaccharides, and , which have nothing to do with prefixes (R)/(S) or ( )/( ). -amino acids and -monosaccharides are by far the most common types that are present in all forms of life, with -amino acids and -monosaccharides nearly inexistent. They receive the prefix when the amine or hydroxy group on the farthest carbon chiral from the carbonyl group is on the left side in a fisher projection, and prefix when is on the right, as shown in Figure 5.
Figure 5. (a) Amino acids and -Alanine and (b) monosaccharides and -Fructose.
Table 2. Rules for enantiomer nomenclature.
Several natural compounds have two or more enantiomeric forms due to the complexity of their molecules that hold one or more chiral carbons. The human body, in turn, is essentially asymmetric; several organic molecules present chiral carbon, such as deoxyribonucleic and ribonucleic acid and their monosaccharides deoxyribose and ribose, respectively, and monosaccharides of the natural polymer DNA and RNA, shown in Figure 6, are present in all human cells [7]. “Chirality represents an intrinsic property of the so-called ‘structural blocks of life’, such as amino acids and monosaccharides and, consequently, peptides, proteins and polysaccharides.” [8].
In their composition, many drugs have enantiomeric compounds that, in an asymmetric environment such as the human body, act completely different. There are several cases where one of the enantiomer is the active principle, while the other might cause side effects, prove to be toxic, ineffective or antagonist in the treatment [2,9–12]. Many drugs must be sold in its pure enantiomer form in order to be effective and/or harmless, for this reason, enantioresolution is one of the most important issues of the pharmaceutical industry. There are many known cases in the literature of different behaviors of enantiomers in pharmaceutical, agronomic and food applications, as shown in Table 3 [4,13,14].
Figure 6. Deoxyribose (a) and ribose (b) monosaccharides structural formulas from DNA and RNA and their chiral carbons.
Table 3. Difference in biological activities between enantiomers [4].
The reason for the distinct actuation of virtually identical compounds is found in the biological receptors in human cells. These are macromolecules present in cell membranes that mediate the effects of chemical messages, hormones, and drug actions in the body [13]. They are responsible for selecting which substance from extracellular fluid may or may not enter the cytoplasm [15]. Figure 7 illustrates this interaction between biological receptors and chiral molecules. In Figure 7a, the enantiomer interacts perfectly with the receptor, whereas in Figure 7b the connection is compromised, which might cause a side effect if any effect at all. The pharmacological properties, pharmacokinetic of adsorption, distribution, biotransformation and excretion, and drug toxicology of the enantiomeric drug must be well known and identified [8]. It is important to define the safe degree of purity for an enantiomeric drug before commercialization. Pharmaceutical companies are also interested in selling safe and efficient medicaments, especially in a highly competitive market of medicaments.
Figure 7. Perfect (a) and failed (b) connection between enantiomers and biological receptor.
Nearly 60% of prescribed drugs have an enantiomeric pair [16,17]. However, for a long time, it was a common practice to commercialize chiral drugs in their racemic mixture. Regulatory authorities have put pressure on pharmaceutical companies to sell enantiomeric medicaments in their pure form [2,4]. Ethambutol was the first drug to be commercialized as a single enantiomer in 1961 [18]. Since then, the number of enantiomers sold in their pure form has increased year after year. In 1994, only 20% of the top selling drugs were enantiomers in their pure form [4]. In 2005 this number was already 37% [19] and currently it is over 50% [20]. This increase is justified to regulators that increasingly require clinical control and commercialization of pure enantiomers [8]. An example is the American Federal Agency FDA (Food and Drug Administration), which requires toxicological data of each enantiomer individually [4,21,22].
In economic terms, there was a worldwide growth of USD 30 billion to USD 100 billion from 1992 to 2000 with about 24 companies specializing in enantiomer separation [8,23]. In 2002, this value was already USD 159 billion and in 2005 USD 225 billion [8,19,24]. Table 4 shows the top pharmaceutical companies worldwide in 2017 with regard to chiral active ingredients, according to Pharmacompass (2019), which taken together account for almost USD 58.4 billion.
In such a market, pharmaceutical industries increasingly require refined compounds, which act quickly, in order to stand out in a competitive market. Due to the difference in the performance of different enantiomers, the complexity of some compounds, and the economic-market importance, it is crucial to efficiently and economically obtain each compound separately, either by synthesis or separation.
Table 4. Top seller drugs worldwide in 2017 with chiral active ingredients (PHARMACOMPASS, 2019).
Currently, there are two pathways to obtain chiral compounds in their pure form, namely, synthesis (chiral route) or separation (racemic route), as shown in Figure 8. In the first case, each enantiomer is produced separately by using a chiral catalyst that induces selectivity for a given enantiomer, as shown in Figure 8a [4,8]. If the other enantiomer is also desired, it is necessary to develop a second synthesis with a different chiral catalyst. At first glance, the chiral route seems to be more advantageous than the racemic route (Figure 8b); they synthesize 100% of the intended enantiomer and there is no need for further separation and energetic expenses. On the other hand, racemic routes achieve up to 50% of the desired optically active isomer and racemic routes show inherently poor “atom economy”, i.e., part of the raw material is wasted, and the methods are not “elegant” [25–28]. However, chiral routes usually have low overall yields and only a few of them are applied for industrial purpose, especially at the early stages of new drugs development that requires pure enantiomers for pharmacological tests [2]. Keith, Larrow and Jacobsen (2001) list the following conditions that must be met in order to make the chiral route feasible: cheap racemate; poor CSP (Chiral Stationary Phase) enantioselectivity; highly selective catalyst for one enantiomer; inexpensive or efficiently recyclable catalyst and economical and safe reaction. Usually, these conditions are difficult to achieve, in a way that the production of the racemic mixture for further separation (Figure 8b) is normally favored. Furthermore, economic interest is the driving force that boosts the development of new enantioresolution technologies [2]. The cost of separation depends on the desired degree of purity and this affects the separation route [29].
Figure 8. Enantiomers obtained by Chiral Route (a) Racemic Route (b).
Several methods for enantioresolution have been carried out in chiral environments using CSP. Chiral stationary phases are more effective at binding to one of the enantiomers, according to Dalgliesh’s three-point rule [30], and analogous to biological receptor in Figure 7. This rule states that a chiral environment should have three interaction points with the retained compound either by H-bonding, electrostatic interaction, dipole stacking, inclusion complexion or steric bulk hindrance. When the enantiomer does not interact perfectly with the CSP, the connection weakens and the enantiomer is less retained in the chiral environment, promoting enantioseparation [31–33].
Enantioresolution methods have existed since the early works of Louis Pasteur, who was able to separate tartaric acid manually by crystallization [4]. Currently, there are several methods for enantioresolution, such as chromatography, crystallization, and membrane. Figure 9 summarizes the main methods for enantiomer separation that might be Crystallization, Membrane, and Chromatography. The latter can be divided into Gas Chromatography (GC), Supercritical Fluid Chromatography (SFC), and Liquid Chromatography (LC). The latter can be further classified into High Pressure Liquid Chromatography (HPLC), True Moving Bed (TMB) and Simulated Moving Bed (SMB) chromatography. All these methods have advantages and drawbacks and choosing the best one among numerous technologies is not straightforward; therefore, there is no single resolution method suitable for all racemate [8,29,34,35]. The main mechanisms for enantioresolution are going to be detailed in the following sections.
Figure 9. Main methods for enantiomer separation.
5.1. Crystallization
Crystallization is a stochastic phenomenon of molecular dynamics based on many variables such as temperature, pressure, glass-forming ability of liquids, among other not well understood [36]. Table 5 presents some examples of enantiomers resolved by crystallization methods in the literature. Crystals might be formed by either conglomerates or racemic crystals [37]. Conglomerates are mechanical mixtures of crystals macroscopically distinguished from the pure enantiomers. The first enantiomeric resolution was carried out by Louis Pasteur in 1848, who manually separated conglomerate crystals of sodium ammonium tartrate [37,38]. In racemic crystals, the two enantiomers crystallize together forming a one-phase crystal containing the same amounts of each enantiomer, as shown in Figure 10.
Conglomerate crystal separations are generally straightforward; during the process of crystallization, enantiomers separate spontaneously into two stable crystal-phases, this mechanism is called preferential (or direct) crystallization and it is a non-expensive and efficient method, even on large scales [39,40]. Unfortunately, crystals from conglomerates are rather rare, comprising only 5–10% of all racemate crystals [38,40–42].
Figure 10. Illustration of conglomerate (a) and racemic compound (b) crystals.
Table 5. Experimental studies of enantioresolutions applying crystallization.
Racemic crystals, in turn, require suitable resolving agents, which are optically active compounds that aid in their non-spontaneous separation. Resolving agents convert the enantiomeric pair into two different diastereomers (geometric isomers, see Table 1) with different Physico-chemical properties, as they are different compounds, such as solubility, thus, facilitating their separation [44,54]. This mechanism is the so-called Classical Resolution [38]. The main idea is to break the symmetry between enantiomers by adding a chiral agent in an achiral solvent, possibly forming non-covalent and covalent diastereomers. The former involves salt formation by adding acidic or basic substrates and is the most common resolution method and the latter is applied for molecules unable to form salt [40,54,55].
5.2. Membrane
Membranes for enantiomer separation have advantages over other methods because they tend to be low energy consuming, can work in continuous operation, even in large scales, can be scaled up and down, have higher throughput than other methods and are eco-friendly [31,40,56–58]. The membranes provide good a transport rate, high selectivity, stability in wide range of pH among different solvents and might be produced from different polymeric materials [59]. Enantioselective membranes work as barriers with chiral recognition sites that selectively transport one of the enantiomers based on affinity between the enantiomer and chiral selectors. Table 6 presents some examples of enantiomers resolved by membrane methods in the literature.
Table 6. Experimental studies of enantioresolutions applying membranes.
Enantioselective membranes might be either liquid or solid [2,56]. Liquid membranes are formed by organic liquid with Chiral Selectors (CS) dissolved or suspended in it, such as cyclodextrins, crown ethers, chiral copper complexes, DNA, polypeptides, and enzymes. Solid membranes for enantiomer separation use chiral polymers as enantioselective compounds that interact to a specific enantiomer, as shown in Figure 11 [62]. They are either matrices of molecularly imprinted chiral polymers or membranes with the chiral polymeric selector immobilized (by impregnation, esterification, or grafting) on porous membranes [33,40,56,68,71].
5.3. Chromatography
Chromatographic processes are largely applied in several fields such as chemistry, pharmacy, and bioprocesses either for purification or recovery of different compounds [83]. Its separation is based on a physico-chemical phenomenon whereby a compound in a mobile phase known as the eluent, liquid or gaseous phase, is adsorbed onto the surface of a solid phase, usually a porous adsorbent. Chromatography displays some advantages over crystallization and membrane separations once it may be applied for a mixture of more than two chiral compounds and it can run with samples of small amount for analytical purposes [84]. Its separation is based on the chemical affinity of each compound to a stationary phase. In a chromatography equipment there are a solid stationary phase, generally porous, and a liquid or gaseous (solvent) mobile phase, which contains the mixture to be separated. Chromatographic methods have been the most effective for obtaining enantiomers with very high purity [4,8].
There are different chromatographic techniques for chiral resolution that are able to separate virtually all racemic compounds, that includes GC, SFC, and LC, as shown in Figure 9. Regardless of the chromatographic method applied, a Chiral Stationary Phase is applied, according to Dalgliesh’s three-point rule [30]. Figure 12 depicts adsorption of Enantiomer 1 (E1) onto chiral environment, following Dalgliesh’s three-point rules, whereas Enantiomer 2 (E2) has a compromised interaction to the surface, not fixing on it. CSPs are adsorbents usually based on cellulose such as the commercial products Chiralcel OD, CHIRALCEL OZ, CHIRALCEL OJ and CHIRALPAK AD, whereas common eluents are hexane, ethanol, and methanol. The enantiomers commonly resolved are pharmaceutical drugs such as Praziquantel and Guaifenesin.
Figure 12. Adsorbed Enantiomer 1 (E1) onto the chiral environment according to Dalgliesh’s three-point rule and non-absorbed Enantiomer 2 (E2).
All chromatographic techniques addresed to enatioresolution have their advantages and disadvantages. The next sections detail the differences among these chromatographic techniques, their functionalities and particularities.
5.3.1. GC—Gas Chromatography
Gas chromatography can be used by indirect or direct mechanisms [85]. In the former, enantiomers are converted into diastereomers by a resolving agent, analogous to a crystallization in racemic crystals, then they are separated in an achiral filling CG. The latter uses CSP that separates one of the enantiomers preferentially in a straightforward way by means of chemical affinity based on the three-point rule dismissing a pretreatment [86]. For the direct mechanism, GC requires the use of volatile and thermally stable compounds and the choice for a CSP is of paramount importance in order to resolve racemic mixtures [87].
The first GC with a Chiral Stationary Phase was applied to resolve 2-nalkanols [85]. Since this achievement, GC has been extensively used in academia and industry due to its advantages of being high efficient, simple, and sensitive in comparison to other methods [85,86,88,89]. On the other hand, GC has the drawbacks of being very difficult to scale up and their CSPs usually racemize, decompose and bleed at high temperatures, thereby diminishing its separation factor [87,90]. Table 7 presents some examples of enantiomers resolved by gas chromatography methods.
Table 7. Experimental studies of enantioresolutions applying gas chromatography.
5.3.2. SFC—Supercritical Fluid Chromatography
Supercritical fluids display transient properties between liquid and gas phases; therefore SFC works as an intermediate between GC and LC [117]. At the supercritical condition, the substances are above its critical temperature and pressure [118,119]. Supercritical fluid was firstly used as an eluent for chromatographic separation in 1962 by Klesper, Iiber and Clark using chlorofluoromethanes at 140 bar and 150–170 °C [120,121]. Supercritical fluids have advantages over liquid and gas states and they are a better solvent due to their higher density in comparison to gas states as they are faster (shorter run times), require lower pressure across column and require lower volume due to its lower viscosity and higher diffusivity over liquid states [118–120,122–127]. The most commonly applied supercritical fluid is carbon dioxide; however, the mentioned features are not exclusive to fluids over the critical point, and equal properties are seen in subcritical regions, since there are no abrupt changes of properties in the transition to a supercritical phase. This means that the fluid must not be at a supercritical condition to perform an SFC [118]. Table 8 presents some examples of enantiomers resolved by SFC methods reported in the literature.
Table 8. Experimental studies of enantioresolutions applying Supercritical Fluid Chromatography.
Additionally, CO2 is the most used eluent in SFC due to its relatively low critical point (304.12 K and 73 atm), and it can be purified and reused after analysis; moreover it is inert, non-toxic, non-flammable cheap and relatively safe gas, therefore being considered a green solvent [118,119]. Due to its low critical temperature point, operating CO2 in SFC reduces the likelihood of CSP racemization, improving enantioselectivity [124,153].
5.3.3. LC—Liquid Chromatography
Liquid chromatography has been growing in importance in the last decade due to the variety of enantioseparation modalities [5,154,155]. In LC, the eluent and compounds cross the fixed bed column (adsorber) by means of gravity and this can prove to be lengthy in some procedures. The time-consumption of LC can be overcome by means of a pump, low-dead-volume injectors, and detectors. An enhancement of LC is the so-called High-Performance Liquid Chromatography (HPLC—also known as High-Pressure Liquid Chromatography). HPLC is suitable for a wide range of applications, such as pharmaceuticals and food analysis. HPLC has the advantage of running a fast analysis and high resolution; however, in HPLC (and LC) the adsorber must be constantly regenerated, once it will be contaminated by the more retained enantiomer. Table 9 presents some examples of enantiomers resolved by HPLC methods.
Table 9. Experimental studies of enantioresolutions applying HPLC Chromatography.
True Moving Bed (TMB) is an attempt to develop a continuous liquid chromatography based on the counter-current movement of eluent and solid. Its separation is maximized by a constant flow of solid and liquid phases counter-currently. In this chromatography, the CSP adsorber retaines one of the compounds due to its enantioselectivity nature. This leads to different velocities of displacement of enantiomers along the column. The more retained enantiomer takes longer to reach the end of the column than the less retained compound and, for better separation, the column must be long enough [83]. In TMB chromatography, the adsorber is constantly being regenerated by the eluent. In TMB chromatography, there is constant liquid and solid recirculation, as shown in Figure 13. The liquid stream leaves the top of the column at Section IV and is recycled to Section I, while the solid stream (adsorbent) moves in the opposite direction, being recycled from Section I to Section IV. The eluent and racemate feed the system (respectively, streams E and F in Figure 13). As shown in Figure 13, the more retained compound leaves the system in the Extract Stream (X), whereas the less retained compound is removed in the Raffinate Stream (R). The system has four sections with different functions [83], as explained in Table 10. Due to the counter-current flows, TMB should reach higher purity, even if the adsorbent (solid phase) presents low selectivity, in contrast to conventional chromatography where high selectivity is crucial [83]. However, from an engineering perspective, solid movement is difficult to attain and can cause mechanical erosion in the adsorbent phase, equipment abrasion, and difficulties in maintaining plug flow for the solid [4,83]. The TMB system is a theoretical concept and to solve such problems, an SMB chromatographic unit was developed.
A Simulated Moving Bed is a powerful technology for the preparative and analytical scale in laboratory or in industry [83]. SMB chromatography was first presented by UOP (Universal Oil Products) through a United States Patent [4,179–181], known as the Sorbex Process, which was designed for oil refining purposes [4]. The technology soon found other industrial applications, such as in biotechnology, pharmaceutical and fine chemistry, as it is a separation system with advantages over batch chromatographic systems and traditional processes (PAIS, 1999). Negawa and Shoji (1992) were the first authors to carry out an enantioresolution in an SMB chromatography, they resolved 1-phenylethanol on CHIRALCEL OD as CSP. Since then, there have been several enantioresolutions reported in the literature, as summarized in Table 11.
Figure 13. Schematic diagram of a TMB chromatograph.
Table 10. Functions of the TMB sections.
Table 11. Experimental studies of enantioresolutions applying SMB chromatography.
SMB simulates TMB counter-current flows and overcomes its intrinsic solid movement problems by keeping the solid phase fixed and switching the input and output streams cyclically and periodically (time switch) in a multi-column system, as shown in Figure 14, by simulating a bed movement [208]. SMB has four sections for which the function is analogous to TMB, as shown in Figure 13. The SMB system is fed with an eluent (stream E in Figure 14) and racemate to be separated (stream F in Figure 14). Two outlet streams remove the more and the less retained compounds, respectively, in the extract and raffinate streams (streams X and R, respectively in Figure 14). At the time instant t1, the inlet and outlet streams are set as shown in Figure 14. At time t2, they move clockwise from their current positions to the next ones. Next, they proceed to t3 and so on until they return to their original positions, thus finishing the cycle. The separation is promoted by adsorption of the enantiomer with greater chemical affinity onto the porous solid phase, as zoomed in Figure 14.
Figure 14. Schematic diagram of an SMB chromatograph and its operation where the more retained compound is adsorbed onto the solid porous phase.
Optimal SMB operation depends upon several factors, such as reasonable operating conditions of its streams, switching time, eluent, and the chiral stationary phase. Engineering practices have shown that the scenario of SMB operating conditions is rather limited; a poor set of the pump flowrates may lead to contamination of the outlet streams, thus compromising the separation. The Simulated Moving Bed has been gaining prominence due to its advantageous features such as cleanliness, small size, security, and fast procedure when compared to other systems. Moreover, the method has presented great performance in the separation of enantiomeric drugs such as praziquantel [209], which is a drug frequently used to combat schistosomiasis.
Due to the importance of enantiomer in several fields, especially for pharmaceutical companies that strive to diminish drug side effects, this article approaches different features of enantiomers. The article defines what an enantiomer is, presents related nomenclature, optical activity, enantiomers actuation in human body, enantiomers in biomolecules, market and pharmaceutical demands, and enantioresolution methods such as membranes, crystallization, and chromatography, especially TMB and SMB. It also reports on the features of the most applied enantioresolution methods, main enantiomers, eluents, and chiral stationary phases, with an emphasis on the cyclic adsorption processes. Through the comprehension of the aspects related to enantiomers, the authors of this articles hope to raise the interest of incoming students of chemical engineering to enantioresolution, control, and optimization field.