Che 05022 Biochemical Engineering

Ministry of Science and Technology Technology Department of Technical Technical and Vocational Education B.E (Chemical) 2! "inal E#amination 2$%&%2! '$am% &&$am ChE 05022 Biochemical Engineering ns*er any fi+e ,uestions &.

Deri+e Deri+e the rate e,uati e,uation on for the follo*i follo*ing ng en-yme en-yme reaction reaction using using the Briggs% Briggs% aldane approach. / & / $ S0E ES ES 10E / 2

2.  su3st su3stanc ancee is con+er con+erted ted to a produc productt 3y the cataly catalytic tic action action of en-ym en-yme. e. ssume ssume that the Michaelis%Menten /inetic parameters for this en-yme reaction are 4 M 5 .$ mol6l7 r ma# ma# 5&$ mol6l%min (a) 8hat should should 3e the si-e of a steady%state steady%state CST9 to remo+e remo+e :; percent of incoming incoming su3strate ( Cso 5 & mol6l ) *ith a flo* rate of & l6hr< (3) 8hat should 3e the si-e of the reactor if you you employ a plug%flo* plug%flo* reactor instead of the CST9 in part (a)< $. 9oughly 9oughly s/etch a pro/aryo pro/aryotic tic cells7 la3el its parts7 and state a function function for each of these. =. 8hat are the 3asic procedures of recom3inant D> techni,ues< E#plain 3riefly these techni,ues *ith the help of flo* chart. ;. E#pl E#plain ain in deta detail il the the gro* gro*th th cycl cyclee of unice unicell llul ular ar micr micro%o o%org rgan anism ism for for 3atc 3atch h culti+ation. !. i3a et al.(&:!') reported the results of a chemostat study on the gro*th of a species strain of 3a/er?s yeast as sho*n in the follo*ing ta3le. The inlet stream of the chemostat did not contain any cells or products. Dilution ion @nlet Steady ady%st %state ate Stead eady%st %state 9ate Alucose Conc. Alucose Conc. Ethanol Conc. %& D7hr Csi 7g6l Cs7g6l C p 7g6l .'= 2&.; .;= .: .& &.: .: =. .&! 2&.2 .&$' '.; .&:' 2. .&'! '.== .2=2 &.' .22! =.;& (a) "ind the rate e,uation for cell gro*th. (3) "ind the rate e,uation for product (ethanol) formation.

Steady ady%st %state ate Cell Conc. C# 7g6l 2. &.2 2.= 2.$$ &.2;

$. 1ro/ 1ro/ar ary yotic otic cell cellss

&

Cell *all  ..

Cell mem3rane

.

9i3osome

. .. . .. .. . ..  .. Typical.. pro/aryotic cells .

>uclear region cytoplasm

.. pro/aryotic cells Typical The pro/aryotic cell is unit of structure7 t*o group micro3ial7 3acteria and 3lue green algae. 1ro/aryotic cell is simple and small. 1ro/aryotic cell is not compartmentali-ed 3y unit mem3rane. 1ro/aryotic cell ha+e t*o structurally distinguished t*o internal region cytoplasm and nuclear region. Cytoplasm contains graing dar/ spot due to the present of ri3osome. 9i3osome is the site of important 3iochemical reaction for protein synthesis. The nucleur contain deo#yri3ose nucleuic acid (D>) 7*hich contain genetic information that determine the production of protein and structure . The pro/aryotic cell is surrounded 3y cell *all and a cell mem3rane. The cell *all is considera3le thic/er than cell mem3rane7 and it protect cells from e#ternal influence. The cell mem3rane ser+e as the surface *hich other cells components attac/ and important cell function ta/e place. =. The 3asic procedures of recom3inant D> techni,ues ha+e t*o factor. They are (&) to oin the D> segment to the molecule and they can 3e replicated . (2) to pro+ide en+ironment that allo* the reproduction of oin D> molecules . The produce for the flo* chart of recom3inant D> techni,ues are

2

D> "oreign

Stric/y end

D> @lagse Tranaformation

Transformation cell "ig  The procedure of recom3inant D> . "igure sho* the procedure of recom3inant D> techni,ues. The plasmid cut in definite si-e *ith restriction en-yme. The D> of the foreign clea+ed *ith restriction en-yme. Some of fragment ha+e interest gene. The plasmid and genome fragment mi#ed and oined 3y the D> Figases. The recom3inant plasmids are introduced into the 3acteria and coculati+ation of plasmid and 3acteria. s & .solution / & S0E

/ $ ES

ES

/ 2 The intermediate of reaction *ith respect to time is neglected. dCES 5 dt r CES 5 / &CsCE% / 2 CES% / $ CES 5  / &CsCE 5 / $ CES 0 / 2CES / &CsCE 5 (/ 2 0/ $ ) CES CE 5 (/ 2 0 / $ ) CES / &Cs rp 5 / $ CES

10E

(&)

(2)

By en-yme 3alance7 CEG 5 CE 0 CES 5 (/ 2 0 / $ ) CES / &Cs 5 ( / 2 0 / $ 0&) CES / &Cs CEG 5 (/ 2 0 / $ 0 / &Cs) CES / &Cs By di+iding 3y / & $

CES

5

CEGCS / 2 0 / $ 0Cs / &

By su3stituting of e, n (2) rp 5 / $ CES 5 / $ CEG CS / 2 0 / $ 0Cs / &

Comparing *ith r p 5 r ma# Cs / M 0CS / $ CEG CS 5 r ma# CS / 2 0 / $ 0Cs /M 0CS / &

∴ / 20/ $ ≅ / &

/ 2 / &

r ma# 5 / $CEG / M 5 / 20/ $ ≅ / 2 / & / &

2. Solution CS

Cs

/ M 5 .$ mol6F r ma# 5&$mol ∗ ! min 5 ' mol F min & hr F hr (a) + 5< #s 5:;H Cso 5& mol 6 F " 5 & F 6 hr CS5 CSG (&I #s) 5 & (& I .:;) 5 .; mol 6F

=

t the CST97 @nput I Gutput 0 general 5  "CSG I "CS 0r s+ 5 " (CSG ICS) 5 I r s+ " (CSG ICs) 5 r p+ " (CSG ICS) 5 r ma# Cs V 4 M 0CS

" V

5 r ma# Cs (4 M0CS)(CSG ICS)

" V

5 'J .; (.$0.;) (&%.;)

" V

5 $: .;$ J :.;

" V V

5 .=! hr %&

V V

5" .=!hr %& 5 & F6hr .=! 5 .&2: liter.

2 .(3)

CS

1lug "lo*

Cs

The plug flo* reactor 7 V 5 < IdCs 5 rma# Cs dt 4 M 0CS Cs I ∫ dcs 5 rma# Cs 5 Cs Cso dt 4M 0CS 4 M 0CS

t

∫ r ma# 

;

Cso t ∫ 4 M 0CS dCs 5 ∫ r ma# t Cs Cs  Cso Cso ∫ /M dCs 0 ∫ dCs 5 r ma# t Cs Cs / MlnCso 0 ( Cso ICs ) 5 r ma#t ( K plus 5 t 3atch ) / MlnCso 0 ( Cso ICs ) 5 r ma#K .$ ln & 0 (&%.;) 5 ' K .; .':: 0 :.; 5 'K :.:;':: 5 ' K K 5 .&2$hr K 5 V 6 " 5 .&2$hr V 5 .&2$ × & F6hr V 5 .&2$ Fiter

× hr

!. Soln (a) r # 5 < (3) r p 5 < L5

µ ma# Cs

ks + Cs

&

µ 5

y5

ks

&

µ ma# Cs

0

& µ ma#

m#0c

D 5 L hr %&

CS g6l

& C s

&

µ

.'= .& .&! .&:' .2=2

.;= .&! .&$ &'! .22!

&&.: & !.2; ;.; =.&$

&'.; &2.! .2; ;.$' =.=2

"rom graph7 C5

& µ ma#

5 &.!

!

&

Lma# 5

5 .!2;

&.!

ks

m5

µ ma#

5

.' &.2

5 .!!

/s 5 .=2 g6l !. (a) r # 5 < µ ma# Cs r # 5 k s + C s .!2;Cs

r # 5

.=2 + Cs

!. (3) r p 5 < r p 5

dCx YX 6 P dt &

µ ma# C s C x

&

5

k s

YX 6 P

+

C s

YX P 5

∆C x ∆C p

5

C x C p

YX P 5

5

2 6 B.:B + &.2 6 =.B + 2.= 6 '.;B + 2.$$ 6 '.=: + &.2; 6 =.;& ;

.2; + .2! + .2' + .2' + .2' ;

YX P 5 .2 &

r p 5

µ ma# C s C x

YX 6 P

k s

&

.!2;C S

.2B

.=2 + C S

r p 5

+

C s

2.$&C S .=2 + C S

&.(a) The rates of product formation and su3stance of consumption are dC p dt dC S

5 / $CES

5 / &CsCE  / 2CES → (&) dt ssume that the change of C ES *ith time7 d C ES6dt7 is negli3le compared to that of C 1 or CS . %



dC ES

5 / &CSCE  / 2 CES  / $ CES ≅  → (2) dt Su3stituting E, (&) into E, (2) confirms that the rate of product7 formation and that of the su3strate consumption are the same7 that is 7 dC p dC S r5 5% 5 / $ CES dt dt @f *e assume that the total en-yme contents are conser+ed7 CEG 5 CE 0 CES → ($) Su3stituting E, ($) into E, (2) for C E7 and rearranging for C ES CES 5

r5

C EoC S k 2

+

dC p dt

k $

+

k &C S

dC S

5%

dt

k $ C EO C S k 2

5

+

k $

k &

+

C S

5

r ma#C S K M

+

C S

8hile in the Briggs% aldane approach7 it is e,ual to ( / 2 0 / $ ) 6 / & . CS

Cs

2. 4 M 5 .$ mol6lit ma# 5 &$ mol6lit CSG 5 & mol6lit " 5 & F 6 hr

×

&hr & 5 Fit 6 min ! min !

(a) V 5< 7 CS 5 .; C SG 5 .; mol 6 lit (a) CST9 @nput  output 0 generation 5 accumulation dC S "CSG I "CS 0 µS V 5V 5  dt " (CSGI CS) 5 I µS V F V F V

5 I 5

V5

µ S

C SO

−

C S

µ ma#C S

( K M

F ( K M

+

C S )(C SO

+

−

C S )(C SO

C S )

−

C S )

µ ma# C S

&

5 !

(.$ + .;)(& − .;) &$ × .;

'

5 .&2: Fit. (3) V 5<

F C

CS

SO

"or plug flo* reaction µ =

−

dC S dt

K M

− ∫ C C

S

SO S

K M C S

K M ln

µ ma# C S

K M

+ C S

C S

SO

∫ C C

=

C S C S

.$ ln

dC S

+

& .;

C S

dC S

+ ∫ C C

SO S

(C SO +

+

−

= µ ∫ t dt ma#

dC S



= µ

ma#

t

C S ) = µ ma#t

(& − .;)

= &$ ×

V & 6 !

V 5.&2$lit $. The pro/aryotic cell is the unit of structure in t*o micro3ial groups 3acteria and 3lue%green algae. The pro/aryotic is small and simple 7 as sho*n in fig 7 *hich is not compartmentali-ed 3y unit mem3rane systems .The cell has only t*o structurally distinguisha3le internal regions cytoplasm and nuclear region (or nucleoplasm ).The cytoplasm has grainy dar/ spots as a result of its content of ri3osomes7 *hich are composed of protein and ri3onucleic acid (9>) . The ri3osome is the site of important 3iochemical reactions for protein synthesis. The nuclear region is of irregular shape 7 sharply segregated e+en though it is not 3ounded 3y mem3rane .The nuclear region contains deo#yri3onucleic acid (D>) 7*hich contains genetic information that determines the production of proteins and other cellular su3stances and structures . The pro/aryotic cell is surrounded *ith a cell *all and a cell mem3rane. The cell *all7 considera3ly thic/er than the cell mem3rane7 protects the cell from e#ternal influences. The cell mem3rane (or cytoplasmic mem3rane) is a selecti+e 3arrier 3et*een the interior of the cell and the e#ternal en+ironment . The largest molecules /no*n to cross this mem3rane are D> fragments and lo*%molecular%*eight proteins. The cell mem3rane can 3e folded and e#tended into the cytoplasm or internal mem3ranes. The cell mem3rane ser+es as the surface onto *hich other cell su3stances attach and upon *hich many important cell functions ta/e place.

:

 .. .  .

=

Cell *all Cell mem3rane 9i3osome >uclear region

cytoplasm ... . .. . .. .. . 1lasmld ..  .. .. . 9estrictio n en-yme ..

"oreign D>

NStric/y endN

D> @lagse Tranaformation

Transformed cell "ig7 Method for the production of recom3inant D> "ig sho*s the o+erall procedure for the production of recom3inant D> .The plasmid is cut at a num3er of defined sites *ith a restriction en-yme. The D> of a foreign genome is clea+ed *ith a restriction en-yme. Some of the resulting fragments may ha+e the gene of interest. 1lasmids and genome fragments are mi#ed and oined 3y D> ligase. The recom3inant plasmids are introduced into 3acteria 3y coculti+ation of plasmids and 3acteria. ;. Aro*th Cycle for Batch Culti+ation @f you inoculate unicellular microorganisms into a fresh sterili-ed medium and measure the cell num3er density *ith respect to time and plot it7 you may find that there are si# phases of gro*th and death7as sho*n in "ig. They are &. Fag phase  period of time *hen the change of cell num3er is -ero. 2. ccelerated gro*th phase The cell num3er starts to increase and the di+ision rate increases to reach a ma#imum. $. E#ponential gro*th phase The cell num3er increases e#ponentially as the cells start to di+ide. The gro*th rate is increasing during this phase7 3ut the di+ision rate *hich is proportional to d ln Cno 6 dt7 is constant at its ma#imum +alue7 as illustrated in fig .

&

=. Decelerated Aro*th phas fter the gro*th rate reaches a ma#imum7 it is follo*ed 3y the deceleration of 3oth gro*th rate and the di+ision rate . ;. Stationary phase The cell population *ill reach a ma#imum +alue and *ill not increase any further. !. Death phase fter nutrients a+aila3le for the cells are depleted7 cells *ill start to die and the num3er of +ia3le cells *ill decrease. & Fag 1hase The lag phase (or initial stationary7 or latent) is an initial period of culti+ation during *hich the change of cell num3er is -ero or negligi3le. E+en though the cell num3er does not increase7 the cells may gro* in si-e during this period. The length of this lag period depends on many factors such as the type and age of the microorganisms7 the si-e of the inoculum7 and culture conditions. The lag usually occurs 3ecause the cells must adust to the ne* medium 3efore gro*th can 3egin. @f microorganisms are inoculated from a medium *ith a lo* nutrient concentration to a medium *ith a high concentration7 the length of the lag period is usually long. This is 3ecause the cells must produce the en-ymes necessary for the meta3oli-ation of the a+aila3le nutrients. @f they are mo+ed from a high to a lo* nutrient concentration7 there is usually no lag phase. nother important factor affection the length of the lag phase is the si-e of the inoculum. @f a small amount of cells are inoculated into a large +olume7 they *ill ha+e a long lag phase. "or large%scale operation of the cell culture7 it is our o3ecti+e to ma/e this lag phase as short as possi3le. Therefore7 to inoculate a large fermenter7 *e need to ha+e a series of progressi+ely larger seed tan/s to minimi-e the effect of the lag phase. B



C

D

E

"

&2 & '

t "ig Typical gro*th cur+e of unicellular organisms () lag phaseO (B) accelerated gro*th phaseO (C) e#ponential phaseO (D) decelerated gro*th phaseO (E) stationary phaseO (") death phase. t the end of the lag phase7 *hen gro*th 3egins7 the di+ision rate increases gradually and reaches a ma#imum +alue in the e#ponential gro*th period7 as sho*n 3y the rising inflection at B in fig. This transitional period is commonly called the accelerated gro*th phase and is often included as a part of the lat phase. @n unicellular organisms7 the progressi+e dou3ling of cell num3er results in a continually increasing rate of gro*n in the population.  3acterial culture undergoing 3alanced gro*th mimics a first%order autocatalytic chemical reaction. Therefore7 the rate of the num3er density (C n) of 3acteria present at that time r n

=

dC n dt

=

µ C n *here

the constant

µ is

/no*n as the specific gro*th rate

hr −& .The specific gro*th rate should not 3e confused *ith the gro*th rate7 *hich has

&&

different units and meaning. The gro*th rate is the change of the cell num3er density *ith time7 *hile the specific gro*th rate is & dC n

µ =

C n

dt

=

d ln C n dt

The gro*th of micro3ial populations is normally limited either 3y the e#haustion of a+aila3le nutrients or 3y the accumulation of to#ic products of meta3olism. s a conse,uence7 the rate of gro*th declines and gro*th e+entually stops. t this point a culture is said to 3e in the stationary phase. The transition 3et*een the e#ponential phase and the stationary phase in+ol+es a period of un3alanced gro*th during *hich the +arious cellular components are synthesi-ed at une,ual rates. Conse,uently7 cells in the stationary phase ha+e a chemical composition different from that of cells in the e#ponential phase. The stationary phase is usually follo*ed 3y a death phase in *hich the organisms in the population die. Death occurs either 3ecause of the depletion of the cellular reser+es of energy7 or the accumulation of to#ic products. Fi/e gro*th7 death is an e#ponential function. @n some cases7 the organisms not only die 3ut also disintegrate7 a process called lysis. !. (a) C#i5 

7 Csi 5 

µ =

&

=

µ

& D

=

1lot

µ ma# C S K S

+

C S

K S µ ma#C S

K S

µ ma#

&

D

Vs

&

+

µ ma# C S

&

&

+

µ maz

&

7 slope =

C S

K S µ ma#

D 5 L hr %&

&

=

@ntercept

µ ma#

CS g6l

& C s

&

µ

.'= .& .&! .&:' .2=2 Slope 5

.;= .&! .&$ &'! .22! K S

&&.: & !.2; ;.; =.&$ =

µ ma#

.!: 7 @ntercept

=

&'.; &2.! .2; ;.$' =.=2 & µ ma#

5 &.2

µ ma# =

ν x

=

µ C x

=

.'$$C S .;B; + C S

.'

.C x

!. (3) Material 3alance for 1dt in CST" 7 FC Pi

−

F (C Pi

FC P

r V

+ P

− C p ) +

r P V

=

=

 

&2

F (C Pi

− C p ) = − r p V

V F

V F

C Pi

=

−

C P

r

=

C P − C Pi r P

− P

=

C P r P

"or S.S CST" *ith sterile feed7 r P &

D =

= µ

τ m

7

r P

=

=

C P

=

τ m

C P µ

"rom Manod7 r P

=

5 ∴ plot

& D

Vs

& C B

C P µ

C P .

µ ma# C S

K S

+

µ ma# C P

K S

+

C S

C s

.C B

→

straight line

&$

&=

&;

&!

&

Che 05022 Biochemical Engineering

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