Team:UCL London/Economic Evaluation

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Latest revision as of 20:14, 26 October 2010

UCL IGEM 2010

Economic Evaluation

Through means of auto induction, we hope not only to revolutionize the biopharmaceutical industries approach to protein expression, but we also hope to bring a wave of economic benefits;

1. Cost of IPTG is approximately $600.00 for 10,000L fermentation.

2. Average Facility of a pharmaceutical plant: 50 batches per year, total of $30,000 saving.

3. Industry wide savings of millions of dollars.

4. Two tons of CO2 are produced for each innocculum volume of IPTG. (Source: BIA)

5. Saving an average facility 100 tons of CO2 annually

Calculations

Estimate of IPTG cost for an industrial scale fermentation - say 1000L

From Sigma Aldrich (readily available): Isopropyl-Beta-D-thiogalactopyranoside (IPTG) solution costs £32.30p for 200 mM IPTG

IPTG’s molar mass= 238.3 g/M

200* (1 M/ 1000 mM) = 0.2 M
0.2 M * (238.3 g/M) = 47.66 g

So its £32.30p for 47.66 grams, therefore £ 0.68 pence /gram

From literature: 0.1 mM (This value is usually used for a high FAb production)

So using 0.1 mM, how much IPTG you need in grams: 0.1 mM * (1M/1000mM) = 0.0001 M

238.3 g/M * (0.0001 M) = 0.02383 grams<<< this is
how many grams of IPTG you need per a kg of a feedstream.

Finally for a 1,000 L fermentation batch

Using SuperPro Designer you can assume kg = L

So for 1,000 kg/batch, this is how much IPTG you need:

1,000 * 0.02383 g * (1 kg/ 1,000 g) = 0.02383 kg /batch

Cost of IPTG per a batch:

0.02383 (kg/batch) * 0.6777 (£/ gram) * (1,000 gram / 1 kg) = £ 16. 15 p / batch

Below we have summarized the Economic Advantages and Disadvantages of Auto-Induction:

Advantages

• Simple procedure, expression strain inoculated in the auto-inducing media

- No holding tank required for IPTG, therefore cost saving in equipment costs (Note: lowering the equipment costs, also lowers the capital investment)

- And maybe a slight reduction in CIP and SIP costs

• High titres achieved when auto-inducing compared to using IPTG as proven by our circuit simulation

- Reduces size of fermenter required (as there is more target protein per volume of culture), which lowers the USP equipment costs.

- Also number of batches produced per year would be less

Disadvantages

• Auto-induction uses complex medium

- Complex medium, more expensive

- Could increase the Cost of Goods (COG’s), dependent on the prices of IPTG and complex media.

• At high titres, nature of the feedstream has an impact on the purification steps

- Protein A resin required to capture more product

- High titres bring about more impurities, purification steps may struggle to remove this higher level of impurities.

- Resin lifetime reduces due to fouling, therefore more resin required

- Protein A resin expensive and a significant cost driver for DSP costs

• Possibility of unintended induction

- Could potentially kill cells and produce unexpected impurities that cannot be removed downstream or require further purification steps

• Cultures grown using auto-inducing media may not be suitable as frozen stocks.

- Limited time for use

- Potential risk; loss of stocks due to decrease in viability

@@ Line 2: / Line 2: @@
 ==Economic Evaluation==
 [[Image:UCL-MONEYS1.png|300px|right]]
+Through means of auto induction, we hope not only to revolutionize the biopharmaceutical industries approach to protein expression, but we also hope to bring a wave of economic benefits;
+'''1. Cost of IPTG is approximately $600.00 for 10,000L fermentation.'''
+'''2. Average Facility of a pharmaceutical plant: 50 batches per year, total of $30,000 saving. '''
+'''3. Industry wide savings of millions of dollars.'''
+'''4. Two tons of CO2 are produced for each innocculum volume of IPTG. (Source: BIA)'''
+'''5. Saving an average facility 100 tons of CO2 annually'''
+'''''Calculations'''''
 Estimate of IPTG cost for an industrial scale fermentation - say 1000L
@@ Line 9: / Line 26: @@
 IPTG’s molar mass= 238.3 g/M
-* (1 M/ 1000 mM) = 0.2 M
-.2 M * (238.3 g/M) = 47.66 g
+* (1 M/ 1000 mM) = 0.2 M
+.2 M * (238.3 g/M) = 47.66 g
 So its £32.30p for 47.66 grams, therefore £ 0.68 pence /gram
 From literature: 0.1 mM (This value is usually used for a high FAb production)
 So using 0.1 mM, how much IPTG you need in grams: 0.1 mM * (1M/1000mM) = 0.0001 M
-.3 g/M * (0.0001 M) = 0.02383 grams<<< this is how many grams of IPTG you need per a kg of a feedstream.
+.3 g/M * (0.0001 M) = 0.02383 grams<<< this is
+ how many grams of IPTG you need per a kg of a feedstream.
 Finally for a 1,000 L fermentation batch
 Using SuperPro Designer you can assume kg = L
 So for 1,000 kg/batch, this is how much IPTG you need:
-,000 * 0.02383 g * (1 kg/ 1,000 g) = 0.02383 kg /batch
+,000 * 0.02383 g * (1 kg/ 1,000 g) = 0.02383 kg /batch
 Cost of IPTG per a batch:
 .02383 (kg/batch) * 0.6777 (£/ gram) * (1,000 gram / 1 kg) = £ 16. 15 p / batch
-Advantages and Disadvantages of Auto-Induction
+Below we have summarized the Economic Advantages and Disadvantages of Auto-Induction:
-===Advantages===
+==='''Advantages'''===
 •	Simple procedure, expression strain inoculated in the auto-inducing media
@@ Line 35: / Line 60: @@
 -	And maybe a slight reduction in CIP and SIP costs
-•	High titres achieved when auto-inducing compared to using IPTG
+•	High titres achieved when auto-inducing compared to using IPTG as proven by our circuit simulation
 -	Reduces size of fermenter required (as there is more target protein per volume of culture), which lowers the USP equipment costs.
--	Also number of batches produced per a year would be less
+-	Also number of batches produced per year would be less
+==='''Disadvantages'''===
-===Disadvantages===
-[[Image:UCL-MONEYS.png|300px|right]]
 •	Auto-induction uses complex medium