steroid transformation, bioreactor and bioprocess engineering
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Steroid transformation, Bioreactor and Bioprocess
Engineering
Ritasree Sarma
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Steroids
Steroids are small organic molecules with a characteristic molecular structure containing four rings of carbon atoms synthesized in steroidogenic tissues
It include many hormones, alkaloids, and vitamins
It act on target sites to regulate a cascade of physiological functions
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Types of steroids
Sex hormones. These are the male hormones, including testosterone, which together are called androgens, and the female hormones, including estradiol, a type of estrogen.
Corticosteroids. Hormones include cortisone and cortisol. They are thought to have a role in the immune system.
Mineralocorticoids. These hormones maintain the balance of sodium and potassium in the body and include aldosterone.
Bile salts or bile acid. These steroids are made in the liver. They don't function as hormones, but are necessary for digestion and absorption of fats.
Sterols. The most commonly known of these is cholesterol. Other sterols help your body to make vitamin D from sunlight and to build cell walls.
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Steroidogenic EnzymesCommon name "Old"
nameCurrent name
Side-chain cleavage enzyme; desmolase
P450SCC CYP11A1
3 beta-hydroxysteroid dehydrogenase
3 beta-HSD 3 beta-HSD
17 alpha-hydroxylase/17,20 lyase
P450C17 CYP17
21-hydroxylase P450C21 CYP21A2
11 beta-hydroxylase P450C11 CYP11B1
Aldosterone synthase P450C11AS CYP11B2
Aromatase P450aro CYP19
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Steroid hormones and their derivatives have been used for a wide range of therapeutic purposes
Utilization as immunosuppressive, anti-inflammatory, anti-rheumatic, progestational, diuretic, sedative, anabolic and contraceptive agents
Recent applications of steroid compounds include the
treatment of some forms of cancer, osteoporosis, HIV infections and treatment of declared AIDS
The pharmaceutical industry has great interest in the transformation of steroids for the production of steroid hormones.
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Transformation of steroids
Transformation of steroids means conversion of precursor steroids to important drug intermediates and further conversion of these intermediates to active compounds by simple chemical or microbial processes.
The chemical synthesis and transformations of steroids requires multiple steps and makes the use of reagents that have health risks and cause serious environmental disposal problems.
Alternative is microbial transformation
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Transformation of steroids
Microbial transformation These involves simple, chemically defined reactions catalyzed by enzymes
present in the cell. Microbial cells provide the enzymes to catalyze the transformation reactions.
The microorganisms have got the ability to chemically modify a wide variety of organic compounds. These microbes during the bioconversion provide enzymes which act upon and convert the organic compound into other compounds or modify it.
Microbial transformations cleave the complex side chains of precursor steroids in one single step and incorporate desirable modifications in steroid nucleus.
Microbial transformations are regiospecific and stereospecific, whereby organic compounds are modified into desirable isomers of products involving simple chemically defined reactions catalyzed by the enzymes in the microbial cells.
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TYPES OF STEROIDAL TRANSFORMATION
Oxidation Hydroxylation Dehydrogenation Epoxidations Oxidation to ketone through hydroxylation Ring A Aromatization Degradation of steroid nucleus
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Transformation of steroids
Oxidation Oxidation of alcohols to ketone: 3β-OH to 3-keto Side chain cleavage of steroids Decarboxylation of acids
Hydroxylation
• Hydroxylation involves the substitution of hydroxyl group directly for the hydrogen at the position, be it or , in the steroid with a retention of configuration.
• The oxygen atom in the hydroxyl group is derived form molecular oxygen (gaseous), not from water, and the hydroxyl group thus formed always retains the stereochemical configuration of the hydrogen atom that has been replaced.
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Fungi are the most active hydroxylating microorganisms, but some bacteria particularly the Bacilli, Nocardia and Streptomyces show fair good activity.
The hydroxylation at the 11-position of progesterone was one of the first hydroxylation described
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Dehydrogenation
• Dehydrogenation with the concomitant introduction of a double bond has been reported for all four rings of the steroid nucleus
• The introduction of unsaturated bonds in Ring A is the only reactions of commercial importance.
Example :• In 1955, Charney and co-worker observed that they could greatly enhance
the anti-inflammatory properties of cortisol by causing the compound to be dehydrogenated at 1st position by Corynebacterium simplex.
The resultant product, prednisolone, was 3-5 times more active than the parent compound and produced fewer side effects.
cortisol prednisolone
Corynebacterium simplex
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Epoxidation
• The epoxidation of steroidal double bonds is arare example of biological epoxidation. The 9,11-epoxidation of 9(11)-dehydro-compound , and the 14, 15-epoxidation of 14(15)-dehydro compounds, using Curvalaria lunata
CH3CH3
OCurvalaria lunata
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Ring A Aromatization
• The microbial aromatization of suitable steroid substrates can lead to ring A aromatic compounds, particularly the estrogens which constitutes an important ingredient in oral contraceptives drugs and play important role in replacement therapy for menopause treatment
• Cell free extracts of Pseudomonas testosteroni could transform 19-nor-testosterone into estrone with small quantities of estradiol-17.
19-nortestosterone Estrone Estradoil-17
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Reduction
Reduction of aldehydes and ketones to alcohols
OH
Estradiol
Streptimyces
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Hydrolysis
Hydrolysis of esters
Flavobacterium dehydrogenans contain a specific enzyme acetolase which hydrolyses the steroidal acetates
OAc
OH
EstradiolFlavobacterium dehydrogenans
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Esterification
Usually involve acetylation
O
OAndrostenedione
OAc
OTestosteron acetate
Sacromyces fragilis
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Steroid Ring Degradation
HO
O
O
O
O
O
OOH
O
HO
O
Cholesterol Androstenedione androstadiendione
9 ydroxy-androstadiendione
androstatriendione
Degradation of cholesterol by mycobacteria
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Fermentation condition of some steroids
M/O Steroid substrate
Steroid product
Length of incubation , temperature, aeration
Alcaligenes faecalis
Cholic acid Ketocholic acids (90-100%)
2 days (monoketo acid)4 days (diketo acid)6 days (triketo acid)37-39̊ ,surface culture
Fusarium solani Progesterone 1,4- androstadiene-3, 17-dione(85%)
4 days , 25̊ C , rotary shaker (100 rpm)
Corynebacterium mediolanum
21-acetoxy -3 β- hydroxy -5-pregnen-20-one
21-hydroxy-4-pregnene-3, 20-dione (30%)
6 days , 36-37̊ C , pure oxygen with agitation
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Advantages
Microorganisms have great potential for inducing new or novel enzyme systems capable of converting foreign substrates.
Microorganisms are capable of producing unique enzymes which are stable toward heat, alkali and acid. A combination of microbial transformation and chemical transformations (chemo-enzymatic synthesis) can be exploited for partial, as well as the total synthesis of the organic compounds
Disadvantages• If the substrate is toxic, it can kill the microorganisms. Hence no
transformation will be observed.• Very low chemical yields are obtained due to the involvement of a
complex biological system
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Bioreactor and Bioprocess Engineering
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Bioprocess engineering
Bioprocess engineering is a conglomerate of mathematics, biology and industrial design and consists of various spectrums like designing of bioreactors, study of fermentors (mode of operations etc.)
It also deals with studying various biotechnological processes used in industries for large scale production of biological product for optimization of yield in the end product and the quality of end product.
Bioprocess engineering may include the work of mechanical,
electrical, and industrial engineers to apply principles of their disciplines to processes based on using living cells or sub component of such cells.
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Contd..
Process for developing useful products by taking advantage of natural biological activities.
Classical example include making alcoholic beverages – the yeast cells and nutrients (cereal grains) formed a fermentation system in which the organisms consumed the nutrients for the growth and produced by-products (alcohol).
Today's modern bioprocess technology is based on the same principle: combining living matter (whole organisms or enzymes) with nutrients under the conditions necessary to make the desired end product
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GENERALIZED VIEW OF BIOPROCESS
GENERALIZED VIEW OF BIOPROCESS
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Bioreactor Bioreactor: device, usually a vessel, used to direct the activity of a
biological catalyst to achieve a desired chemical transformation
To reach its’ necessary goals, the biotechnological process has usually 3 major stages:
1. Preparation of nutrient media for the cultivated microorganism and the cultivation process
2.The course of the microorganism reproduction process in bioreactors (called also fermenters) or in other equipment;
3. Obtaining of the final product or substance from the cultivated medium. This stage includes operations such as separation, purification and other technologies, which are connected with obtaining the commodity form.
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Typical Bioprocess Flow Sheet
RAW MATERIASNutrients and Reactants
in Aqueous Solution(may contain insoluble
organic and/or inorganicmaterials)
Air
CELL SEPARATION
1). CELL DISTRUPTION2). PRODUCT EXTRACTION
PRODUCT CONCENTRATION
PROCESS
FINAL PRODUCT
DRYING
PURIFICATION
PRODUCT SEPARATION
PREPARATIONOF BIOMASS
Innoculum StagesFOAM CONTROL
Antifoam AdditionpH CONTROL
Acid-Alkali Addition
Extracellularproduct
Intracellularproduct
STERILIZATION
BIOREACTOR
Free Cells,Immoblized Cells
or Enzyme Bioreactor
PRODUCT RECOVERY
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Design of a bioreactor
The basic points of consideration while designing a fermenter: Productivity and yield Fermenter operability and reliability Product purification Water management Energy requirements Waste treatment
Other significant factors to be taken in account: Design in features so that process control will be possible over
reasonable ranges of process variables. Operation should be reliable Operation should be contamination free
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Types of bioreactor
Bioreactors are generally classified into two broad groups;
1. SUSPENDED GROWTH BIOREACTORS
The reactors use microbial metabolism under aerobic, anaerobic, or sequential anaerobic/aerobic conditions to biosorb organic compounds andbiodegrade them to innocuous residuals.
The microbial activity in the systems produces biomass that is removed by gravity sedimentation, with a portion of the settled biomass recycled to maintain a desired mixed liquor suspended solids concentration in the bioreactor.
Eg Batch reactors, CSTR’S, Plug-flow reactors etc
2. BIOFILM BIOREACTORS
In biofilm reactors most of the microorganisms are attached to a surface, and in this manner kept within the reactor.
The different kinds of biofilm reactors include membrane, fluidized bed, packed bed, airlift, reactor.
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The batch bioreactor: A typical batch reactor consists of a tank with an agitator and
integral heating/cooling system. These vessels may vary in size from less than 1 litre to more than 15,000 litres.
They are usually fabricated in steel, stainless steel, glass lined
steel, glass or exotic alloy.
Liquids and solids are usually charged via connections in the top cover of the reactor. Vapors and gases also discharge
through connections in the top. Liquids are usually discharged out of the bottom.
Advantages of the batch bioreactor
Easy operation and absence of mechanical pumps Versatility; a single vessel can carry out a sequence of different operations
Disadvantages where mixing is a critical parameter , they are not the ideal solution
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THE CONTINUOUS STIRRED TANK REACTOR:
The liquid or slurry stream is continuously introduced and liquid contents are continuously removed from the reactor.
The basic characteristic of the ideal CSTR is that the concentration of the substrate and microorganisms are the same everywhere through out the reactor.
• Advantages :The rate of many chemical reactions is dependent on concentration, continuous reactors are generally able to cope with high concentrations due to their superior heat transfer capabilities
•Disadvantages:Consumption of more power due the presence of mechanical pumps
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THE PLUG FLOW REACTOR
The liquid or slurry stream continuously enters one end of the reactor and leaves at the other end.
The concentration of substrates and microorganisms vary throughout the reactor. Concentrations of substrates are highest at the entrance of the reactor, which tends to make rates there quite high
ADVANTAGES:1. Can run for long periods of time without
maintenance.2. The heat transfer rate can be optimized by
using more, thinner tubes or fewer, thicker tubes in parallel.
DISADVANTAGES:1. Temperatures are hard to control and can
result in undesirable temperature gradients2. Expensive to maintain.
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Packed bed bioreactors
• A bed of solid particles usually with compressing walls constitute packed bed.
• Biocatalyst is supported in porous or non porous bed.
• Fluid comprising of dissolved nutrient and substrate flows through the solid bed. The Flow rate and in term the residence time of substrate is manipulated to increase or decrease substrate contact with the bed (microorganisms)
• Commonly packed bed reactors are used for aerobic treatment of waste waters and are known as tricking filters and or biological towers
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Fluidized Bed Reactor
• In this type of reactor, a fluid (gas or liquid) is passed through a granular solid material at high enough velocities to suspend the solid and cause it to behave as though it were a fluid. This process, known as fluidization
• ADVANTAGES: 1. Uniform particle mixing2.Uniform temperature gradients3. The ability to operate reactor in continues state.
• DISADVANTAGE:1. Increased reactor vessel size2. pumping requirements and pressure drop
• Typical application of these reactor is in waste treatment.
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Lab scale bioreactorPilot scale bioreactor
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