Precipitation (chemistry): Difference between revisions
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===Solubility of Macromolecules=== | ===Solubility of Macromolecules=== | ||
[[Solubility]] is the property of a substance ([[solute]]) – in either gas, liquid, or solid phases – to [[dissolve]] in a liquid (called the [[solvent]]) and form a [[homogenous]] (single-phase) solution. | '''[[Solubility]]''' is the property of a substance ([[solute]]) – in either gas, liquid, or solid phases – that determines the extent to which it [[dissolve]]s in a liquid (called the [[solvent]]) and form a [[homogenous]] (single-phase) solution. It is based on factors such as temperature, compatibility between the solute’s net charge and the solvent’s [[polarity]], the formation of [[hydration layer]]s, the presence and concentration of other solutes dissolved in the solvent, and solvent’s [[ionic strength]] and [[dielectric constant]].<br /><br />[[Macromolecules]] (such as [[protein]]s and [[nucleic acid]]s) are typically present in [[aqueous solvent]]s. They are able to dissolve as a result of assuming a stable conformation in the solvent and then being surrounded by hydration layer(s). When placed in an aqueous solution, the macromolecules adopt a structure in which most [[hydrophobic]] (nonpolar) portions of the molecules gather inwards, and most [[hydrophilic]] (charged/polar) portions surround the exterior, guided to a final conformation that has the lowest [[Gibbs free energy]]. The attraction between the hydrophilic surface of the macromolecule and the polar water molecules creates an interface in which similarly-oriented water molecules associate with, and surround, the solute’s surface to form a highly ordered layer, called the [[hydration layer]] (also called the interfacial double layer). The formation of hydration layers enhances the solubility of macromolecules by greatly reducing inter-macromolecular dipole-dipole attraction and thus preventing their association with other solutes. | ||
====Effects of Solute Net Charge==== | ====Effects of Solute Net Charge==== |
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The Process
Introduction
The process by which a dissolved chemical species comes out of solution as a solid is called precipitation. It is often employed in bioseparation applications for protein purification and concentration, although it may be used to isolate other compounds, such as nucleic acids and other cell components. Precipitation is achieved by altering the solubility of a target protein in a solution to cause it to become insoluble and thus precipitate, allowing for this concentrated solid to be more easily separated from the liquid phase (supernatant).
Solubility of Macromolecules
Solubility is the property of a substance (solute) – in either gas, liquid, or solid phases – that determines the extent to which it dissolves in a liquid (called the solvent) and form a homogenous (single-phase) solution. It is based on factors such as temperature, compatibility between the solute’s net charge and the solvent’s polarity, the formation of hydration layers, the presence and concentration of other solutes dissolved in the solvent, and solvent’s ionic strength and dielectric constant.
Macromolecules (such as proteins and nucleic acids) are typically present in aqueous solvents. They are able to dissolve as a result of assuming a stable conformation in the solvent and then being surrounded by hydration layer(s). When placed in an aqueous solution, the macromolecules adopt a structure in which most hydrophobic (nonpolar) portions of the molecules gather inwards, and most hydrophilic (charged/polar) portions surround the exterior, guided to a final conformation that has the lowest Gibbs free energy. The attraction between the hydrophilic surface of the macromolecule and the polar water molecules creates an interface in which similarly-oriented water molecules associate with, and surround, the solute’s surface to form a highly ordered layer, called the hydration layer (also called the interfacial double layer). The formation of hydration layers enhances the solubility of macromolecules by greatly reducing inter-macromolecular dipole-dipole attraction and thus preventing their association with other solutes.
Effects of Solute Net Charge
In an aqueous solvent solutes with a higher net charge are more soluble, due to their enhanced ability to associate with water molecules and create a hydration layer, and their lessened inter-solute interactions as a result of increased repulsion from like-charges.
Effects of Solvent Ionic Strength
Increasing a solvent’s ionic strength (the concentration of ions in solution) decreases the availability of unassociated water molecules, which are required for the formation of hydration layers. This increases intermolecular attraction between solutes and promotes coalescence, thus decreasing the solute’s solubility.
Common Methods of Precipitation
Salting Out
A common method of protein precipitation is called salting out, and is achieved by increasing an aqueous solvent’s ionic strength by dissolving a salt. Increases in salt concentrations steadily decrease the solubility of proteins in the solution, until the proteins become insoluble and precipitate out of solution. Since proteins generally differ in their solubility, slowly adding salt allows for selective precipitation of dissolved proteins in order of lowest to highest solubility. This process is described empirically by the Cohn equation:
where is the solubility of the protein in mol/L, is the solubility at zero ionic strength in mol/L, is the protein’s characteristic salting-out constant (no units), and is the concentration of ions in solution in mol/L.
The most commonly used salt for this procedure is ammonium sulfate, (NH4)2SO4 due to its high solubility, lack of buffering capacity, minimal cost, and the low density of the resulting solution relative to other salts, which aids in centrifugation separation.
Isoelectric Precipitation
At its isoelectric pH, called the pI, a macromolecule possesses no net charge and thus no like-charge repulsion occurs between solutes. This results in weaker interactions with water molecules and makes the macromolecule more hydrophobic, increasing its affinity for combining with other solutes, and thus allowing for precipitation.
Changing Solvents & Alcohol Precipitation
The addition of a nonpolar solvent like ethanol to a solution typically decreases solubility of highly charged solutes, and is commonly used in nucleic acid precipitation. The nonpolar alcohols compete with water for association with the dissolved solute and destabilize the hydration layer, increasing the solute’s ability to form hydrophobic interactions with other solutes, and decreasing its solubility as a result.
Flocculation
Flocculation is a process in which particles of an insoluble, dispersed (but not dissolved), and colloidal substance join together to form what are called flocs, which are flaky aggregations of the substance. Typically, most biological particles suspended in a solution possess a negative charge reference. This creates repulsion between the particles, which is counteracted by a mutual attraction due to van der Waals force. Although at short range the van der Waals force is much more powerful, it decays rapidly with distance and the inter-particle repulsive forces, which act a greater range, typically prevent particles from achieving this required approach distance.
Flocculation is achieved by minimizing the contribution of repulsive forces in order to maximize the effect of the van der Waals force, to an extent that allows the particles to move sufficiently close to permit the van der Waals force to drive particle aggregation. The most common process to produce this effect is to increase the ionic strength of the solution by dissolving a salt, whose charged ions interfere with inter-solute repulsion.
Precipitate Formation
When the concentration of a solute is greater than its equilibrium solubility, it is termed supersaturated. The process of precipitation begins in a supersaturated solution first by nucleation, in which ultramicroscopic clusters of particles are generated. Following nucleation, diffusion-limited growth of the particles occurs until the particles reach a diameter limited by the shear field of the fluid. The rate at which particles aggregate may be described by the following rate equation:
where is the number of the ultramicroscopic clusters initially created by nucleation, is the diffusivity, and is the diameter of the particles. Integrating the equation gives:
where is the initial number of particles. After reaching their critical size, the clusters undergo a flocculation process in which their continued growth is governed by fluid motion, which causes them to collide and stick together. This growth is described by the equation:
where is the fraction of collisions that result in permanent aggregates, is the number of particles, is time elapsed, is the diameter of the particles, and is the shear rate. The flocs reach a stable size after a period called the “aging” time elapses.
History
This section should describe the invention and development of the process. If the section runs long, divide it into chronological subsections, for example:
Invention and early development
This subsection should provide some historical context for the development of your process, describe its invention, and name some early developers and/or applications.[1]
Recent developments
This section should discuss new developments in the field. Don't hesitate to drop in brief mentions of processes or features you don't intend to discuss in depth. By so doing you are planting seeds of articles which will eventually be developed by others.[2]
Design and Operation
Use lots of subsections here as you describe various aspects of the process .[3]
Applications
This section should discuss how the process is used in practice.[4]
Examples
If you have used a lot of equations in your article, this may be a good place to show an example of how they are used. See the article on the Antoine Equation for an example.
References
- ↑ John Q. Sample, Chromatography, a new analytical tool. City: Publisher, 1885.
- ↑ "New Directions for Flocculation," American Flocculation Society. 2006. Retrieved July 21, 2009 from http://www.amflocsoc.org/future_devs.html
- ↑ First Author and Second Author, "Electro-absorpto-crossflow-sedimento-extractofractionation," Journal of Superspecialized Bioseparation Arcana 36:2 (2010) pp. 86-52.
- ↑ "Major Success for Bioprocess Fractionation," Anytown Daily News, January 1, 2015, p. A6.