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Chapter 5: Problem 2

Strategies for Product Separation Yeast cells \((a=3 \mu \mathrm{m})\) in a fermentor secrete a low molecular weight product at a concentration that produces uniform rod-shaped crystals \(2 \times 6 \mu \mathrm{m}\) at about 20 times the number concentration (particles/ml) as the cells. Using concise statements, design two possible strategies that take advantage of the particulate nature of the product to separate the product from the broth and from the cells. What additional information about the product crystals would be useful?

Short Answer

Expert verified
Two strategies for separating the product from the broth and the cells include filtration to separate the crystals from the broth due to their size difference, and centrifugation to separate the crystals from the yeast cells due to concentration and density differences. Additional information that can help refine these strategies include the density, specific gravity, solubility and chemical composition of the crystals.

Step by step solution

01

Isolating the Crystals from the Broth

The rod-shaped crystals from the yeast cells can be separated from the broth through techniques that take advantage of their specific physical characteristics. Filtration proves useful as the crystals have a significantly larger size compared to the molecules in the broth. A micro-filter with pore diameter somewhere between the size of the broth molecules and the size of the crystals \(2 \times 6 \mu m\) can be used to effectively separate the crystals from the broth.
02

Separating the Crystals from the Yeast Cells

Given the difference in concentration and presumably also density between the crystals and yeast cells, centrifugation can be used for further separation. The speed and duration of centrifugation can be tailored to obtain a pellet of yeast cells at the bottom and crystal suspension above, which can then be decanted.
03

Identifying Need for Additional Information

Additional information on the density, specific gravity, solubility and chemical composition of the product crystals would be useful. This information can contribute to refining the separation strategy - for example, differences in solubility or density can suggest the use of techniques such as crystallization or flotation.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Filtration
Filtration is a widely used method for separating solids from liquids by having a porous barrier that allows only the liquid to pass through while holding back the solid particles.

In our scenario, rod-shaped crystals with dimensions of \(2 \times 6 \mu m\) can be effectively isolated from the surrounding broth using micro-filtration. A micro-filter, which has pore sizes tailored to trap these crystals but allow broth molecules to pass, is an elegant solution to this separation challenge.

However, it's not just about choosing the right pore size; factors like filter material, operating pressures, and flow rates also play crucial roles. The efficiency of separation will depend on these conditions, which must be optimized based on the physical composition of the crystals and broth.
Centrifugation
Centrifugation is a process that employs the use of centrifugal force to separate components of different densities within a mixture. In the separation of yeast cells from the product crystals, adjusting the centrifuge's speed and time can sediment the denser yeast cells at the bottom, forming a pellet, while the less dense crystals remain suspended.

The biologist or chemical engineer must carefully calibrate centrifugal speed (measured in RPM) and the duration of the spin to achieve optimal separation. Insufficient force may not fully separate the components, and excessive force might cause damage or unwanted mixing.
Physical Characteristics of Crystals
Understanding the physical characteristics of crystals, such as their size, shape, density, and specific gravity, is paramount in designing effective product separation strategies.

In our exercise, having crystals that are rod-shaped and much larger than broth molecules is advantageous for filtration. Moreover, knowledge about the density and specific gravity would enhance the precision in centrifugation, as these properties determine how crystals behave under force. Additionally, given the crystalline nature of the product, knowing the solubility and chemical composition can aid in selecting the appropriate solutions for washing and further purification.
Crystallization
Crystallization is a technique used to form solid crystals from a homogeneous solution. It's a process that typically follows saturation of the solution wherein the solute molecules start to form a defined, ordered structure.

For the secreted product in our exercise, if additional information indicates a particular solubility profile, the process of crystallization can be optimized to increase yield and purity of product crystals. Factors like temperature, concentration, and the presence of impurities significantly impact the crystallization process and need careful control.
Flotation
Flotation is a separation technique based on differences in wettability of particles in a fluid. For instance, in ore processing, minerals with a hydrophobic surface attach to air bubbles and float to the surface, while hydrophilic particles sink.

In the context of product crystal separation, if the crystals have hydrophobic surfaces, flotation could potentially be utilized to separate the crystals from the aqueous broth. The process would involve bubbling air through the broth, whereby the crystals attach to bubbles and rise to the top for collection.
Bioprocess Engineering
Bioprocess engineering is a field that applies principles of biology, chemical engineering, and mathematics to develop and optimize processes for the production of biologically-derived substances. This includes the use of living cells or their components, such as enzymes, to create products ranging from medicines to biofuels.

In our exercise, a bioprocess engineer would apply the principles of this discipline to devise a strategy for separating yeast cells and the rod-shaped crystals. They would consider the biological properties of the yeast and the product, as well as the physical and chemical parameters involved in processes like filtration, centrifugation, crystallization, and flotation.

Understanding the complexities of the living systems involved, and combining this knowledge with engineering principles, allows for the creation of efficient and cost-effective separation techniques critical in industrial biotechnology.

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Most popular questions from this chapter

Estimation of Flow Rate for Centrifugation of Yeast Cells A maximum flow rate of 50 liters/min was achieved for the centrifugation of bacteria cells in a tubular centrifuge. The cells were \(2.0 \mu \mathrm{m}\) in diameter and had a density of \(1.08 \mathrm{~g} / \mathrm{cm}^{3}\). The medium had a density of \(1.01 \mathrm{~g} / \mathrm{cm}^{3}\) and viscosity of \(1.2 \mathrm{cp}\). It is desired to centrifuge yeast cells in this same centrifuge. The yeast cells have a diameter of \(5.0 \mu \mathrm{m}\) and a density of \(1.10 \mathrm{~g} / \mathrm{cm}^{3}\). The medium has a density of \(1.02\) \(\mathrm{g} / \mathrm{cm}^{3}\) and a viscosity of \(1.3 \mathrm{cp}\). Estimate the maximum flow rate that can be used to centrifuge the yeast cells.

Isopycnic Sedimentation You wish to capture \(3 \mu \mathrm{m}\) particles in a linear density gradient having a density of \(1.12 \mathrm{~g} / \mathrm{cm}^{3}\) at the bottom and \(1.00\) at the top. You layer a thin particle suspension on the top of the \(6 \mathrm{~cm}\) column of fluid with a viscosity of \(1.0 \mathrm{cp}\) and allow particles to settle at \(1 \mathrm{~g}\). (a) How long must you wait for the particles you want (density \(=1.07 \mathrm{~g} / \mathrm{cm}^{3}\) ) to sediment to within \(0.1 \mathrm{~cm}\) of their isopycnic level? Is it possible to determine the time required for particles to sediment to exactly their isopycnic level? (b) If instead of \(1 \mathrm{~g}\) you use a centrifuge running at \(800 \mathrm{rpm}\), and the top of the fluid is \(5 \mathrm{~cm}\) from the center of rotation, how long must you centrifuge for the particles to move to within \(0.1 \mathrm{~cm}\) of their isopycnic level?

Time Required for Sedimentation by Gravity A certain reagent is added to a suspension of cells \(4 \mu \mathrm{m}\) in diameter. These cells have a density of \(1.08 \mathrm{~g} / \mathrm{cm}^{3}\), and they are suspended in liquid with a density of \(1.00 \mathrm{~g} / \mathrm{cm}^{3}\) and viscosity of \(1.0 \mathrm{cp}\). This reagent causes about half of the cells to form fairly solid aggregates, all of which are \(90 \mu \mathrm{m}\) in diameter and have density midway between that of the liquid and the cells. How much time is required for all the aggregates to sediment to within \(1 \mathrm{~cm}\) of the bottom of a vessel filled with suspension that is \(0.5 \mathrm{~m}\) high? Approximately what fraction of the single cells would have sedimented to this depth in the same amount of time? How much time is required for all the single cells to sediment to within \(1 \mathrm{~cm}\) of the bottom of the vessel?

Bench Scale Tests for a Tubular Bowl Centrifuge You can bench-test a tubular bowl separation by first characterizing the product in a test-tube centrifugation. Without actually knowing the size and density of the particles in the suspension, derive an expression for the angular velocity required to capture the solids at a given volumetric flow rate \(Q\) in terms of the geometry of the tubular bowl and the quantities you would measure in the test tube centrifugation.
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