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BIOL 2321_Microbiology for Science Majors - 2321_MW4_2_7_23_Lecture
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00:07 Okay. Mhm Yeah, I Hey folks, welcome, let me
00:41 this up a little bit. Testing. Can you hear me?
00:47 of low test casting, wow that's better. Okay, all
01:03 let's see. So there shouldn't be new information to anybody. I hope
01:09 , email. Uh So that's only in terms of being a little more
01:23 . So instead of the usual uh questions, this one is about 25
01:32 , you'll have 45 minutes. Um basically cover stuff since last, I
01:40 you can hear the 17th, 19th kind of only started a real
01:46 So uh basically chapter 134 and summer , whatever we cover on five on
01:54 . So Um so just know that have more time for this one
02:00 So uh of course the smart, work. Um the only difference there
02:07 you got something to do on but then two days later in Chapter
02:12 , which is not long, it's short, but I did it that
02:16 . So if you did have questions you at least have some time before
02:21 exam. Okay, so that's why put the due date on Wednesday for
02:26 . Um So again, exam is week from this friday, so I
02:35 have over a week yet until So but we'll start before that it
02:42 start viruses and this and this is one of those, I'll have the
02:52 uh set up for you. So the flip classes we'll we'll do a
02:57 of questions. Um too. that's not going to be on the
03:03 example. Okay. But just to you know, So we've got plenty
03:09 time, so likely um the the that ketchup day, we'll finish up
03:16 last bit of chapter five. That likely not be a an hour and
03:22 minutes class. Probably somewhere about 45 range. So anyway, so that's
03:27 coming up. So uh let's uh a brief recap. Um So we've
03:36 through, we haven't talked about this , but we'll go through that and
03:42 this in this today and maybe uh two? Uh short by comparison.
03:53 it only covers two topics. Uh films in those scores. Okay.
03:58 , well, we may or may get to some of that today.
04:02 see, but we've got plenty of . Um Alright, so we went
04:07 kind of uh alright, here's what need for growth. Right? So
04:14 kind of went down to the right? The C H O M
04:17 S. Okay. And then of , depending on the nutritional,
04:25 We need different forms of these Most of phosphate or phosphorous is a
04:34 , sulfurous sulfate content typically and so . But the kind of the one
04:38 the major dividing lines was a carbon C. 02 or something, a
04:42 more complex. Like a glucose or carbohydrates, or fat or what
04:48 Right? So you're distinction, So we looked at in terms of
04:54 , electrons right to remember us hetero and uh more manual for our
05:01 Right? We can eat carbohydrates and carbon from that. We can also
05:05 energy from that. Right? And from that as we'll see when we
05:10 into chapter two. Okay. So all depends on kind of the metabolic
05:15 and then we put those components together we make a media, right,
05:20 medium. And then uh we have types of growth media. We talked
05:24 uh complex divine. Right? We'll about a couple others today. And
05:31 and uh and ways to grow bacteria . So you can have can get
05:38 you want, so to speak. . And then uh so well today
05:45 get into uh growth dynamics. So growth, how fast can you
05:52 Uh quantitative them. And uh we'll a couple of problems. You're allowed
05:58 have a Hand held calculator. I care what type you just have to
06:04 able to do multiplication, division log base 10 function. That's pretty
06:10 . But there'll be a couple of . Maybe three at most have to
06:15 with that. But we'll go through today. There's nothing complicated. But
06:22 then it will end with this here of growth. So if we
06:33 Yeah, don't memorize anything. Um the um you know, actually the
06:43 you march your growth and you get get ages, right? They can
06:50 in terms of length and the former not as we'll talk about it.
06:55 uh that's the lag along station. read that face so I'm gonna talk
06:59 some of the variations of growth. this is an area here that if
07:05 a biotech major that's these are the of things you'll do actually we'll do
07:11 of these things as well. And so anyway, we'll take a
07:17 at that. So let's start with question. Okay. So it's kind
07:22 relates to this kind of relate to medium. And this question here,
07:29 . So you remember what is. . Um That's the key answering.
07:35 just a yes or no question. . So look at that gross medium
07:42 history and of course is amino So could a history in grow on
07:50 medium as is. Okay. All . Let's count down. Let me
08:28 that again. Who answered? I you to see you are correct.
08:35 , you're not correct. Alright there no C. Okay. Um Who
08:44 a Hey police 61 of you. you can have you know your 61
08:55 you answered. Yes. Okay. um Why tenant girl This video?
09:08 because that's right. So so number the history has to be supplied.
09:14 that's that's number one. The definition . This is a this is one
09:22 deficient in some sort of pathway can't in this case histamine or can't make
09:29 or whatever whatever the word is before control it can't make that. So
09:33 have to supply it's gonna grow. so knowing that then you look at
09:38 words medium and uh what's what's supplying history and potentially it's gonna be these
09:47 . Alright. Pepto beef extract, ? Complex nutrients. Let's think of
09:53 tone and beef extract. It's a about that flesh and bone. What's
10:01 to be in that? Everything amino , nucleotides, carbohydrates in different it's
10:08 gonna be there. So um certainly will be among those amino acids in
10:16 . Okay so yeah it will grow the complex meat. Now if you
10:24 it on this medium. Yes, minus that. Okay. In other
10:33 that would be a defined medium, , synthetic medium, minimal medium.
10:41 if you you could use that if just added which you can buy and
10:47 can buy history by itself and just that. You can do that.
10:54 you were if you were really testing examining the properties of this and how
11:02 could you know how much history would and that this and that that you
11:05 want to do that a minimal medium defined with history alone. So how
11:11 you control everything all the parameters? um But yeah so that's what we're
11:16 with. Castro that's what you got think about. How do I supply
11:20 nutrients. Okay so this question. so this isn't a quicker question.
11:28 um just focus on the components of media. Just bringing us into the
11:35 topic here. What would grow on medium Is something missing? It's something
11:45 think of the thinking. Six Right? six elements. Alright.
11:53 missing. Uh huh. Anybody else down mm hmm. Else it's not
12:13 , correct nitrogen. Okay so what grow on this? Oh there's your
12:20 . Right well couldn't grow on it the bacteria that are in this category
12:26 here they can actually take into and that. We'll talk about this later
12:33 the semester. And then that's that's nitrogen. Okay so this is the
12:39 of medium that's agriculture. This is example example of regiment culture. Okay
12:46 you formulate a growth medium with ingredients will allow for the growth of a
12:56 type. Certain okay um now there's we'll talk about selectively during a second
13:05 at me. It's a very subtle maybe between the two and all
13:12 You might you might argue that any is selective, right? Neutrino?
13:19 can be selective. It's not it's a second media and stand corrected.
13:24 I'm just saying you might argue idiots you can't grow everything we grow everything
13:32 that's able to be cultured. Certain can but not everything so well
13:38 No not quite. Okay so selective is where you are purposefully add a
13:46 component that you know will inhibit a particularly a certain class of bacteria.
13:53 common is and chemical agents that inhibit positives and inhibit gram negative. So
13:59 know and a and an antibiotic right any chemical that you know will inhibit
14:06 growth of certain types. So these all selected media. Okay. Enrichment
14:12 a little bit different to add a to the things you're trying to combine
14:19 components of the type of what we're growth of the type you're looking
14:26 Okay it would be right. You're adding something to inhibit chemical to inhibit
14:33 . You're just producing a media that will allow for the growth of a
14:37 select type of impact. Right? can adjust it right? But you're
14:43 to enrich for those types right? you try to look for one of
14:48 types. Okay one of these types . Okay use a nutrient auger.
14:58 would get in a handful of soil ? Because these are from the
15:04 You don't get all kinds of stuff out of plate and you may have
15:08 them fixers but you'd never probably find . Right so let's throw it on
15:14 medium instead. Okay and now only select few things are going to grow
15:22 that You enrich for their presence if will. Okay so it's kind of
15:28 little of a subtle distinction but that very 30 between the original culture and
15:32 can not selected. Right. Any about that? So um and so
15:41 talked about this before um Different types liquid and solid media, right?
15:47 um there's utilities for both. You use liquid cultures that you're trying to
15:53 large volumes of whatever microbe you're working because the amount of volume is
16:00 Right? Um And that's before. like if you want to get some
16:06 of molecule from yourself to grow them to get enough stuff, you can
16:10 with whether it's D. N. . Or uh plate. You
16:15 plates, let's call it a on plate. You would take something from
16:20 and transfer to a plate. All to get visible colony. So think
16:27 solid media gives you a way to . Um But this is a bowl
16:36 of the micro it's kind of But you know what's what's calling you
16:42 plate. You know that's that is representative of one type, right?
16:48 a cure column, right? So can some of that material, you
16:54 go back to liquid video or do , but you can now have to
16:58 it in your culture. And so is essential for that. Getting pure
17:04 . Look what could be a part the process. But ultimately you got
17:07 put on a plate to see. gives you a visual representation of something
17:11 can work with. You can look the microscope, right? But you
17:16 sell a pair of tweezers. You need that plate for that.
17:21 , so and the plate will tell Well, there are other things mixed
17:25 there. Okay. So you can of weed things out. Alright.
17:30 everything has kind of its own And so selected media and different uh
17:37 , chemicals in there that will inhibit classes. A lot of these
17:41 So, let me talk about this the context of selective and differential.
17:49 . So both of these together. . Yes, there can be media
17:54 medium that is just selective. But very often you combine two or
18:02 selective differential. So differential medium gives a uh difference in terms of some
18:11 of chemical property that the cell does doesn't have a lot of these selected
18:18 media were developed for water quality analysis what I'm gonna tell you now,
18:29 not gonna test you on but it to uh explain. It kind of
18:33 in terms of what's going on So, the water quality uh one
18:38 the things you're very concerned about is presence of by definition coliform is a
18:51 a short program, gram negative lactose . That's what coliform is. All
18:58 . So these are indicators of fecal of water. Find something like this
19:06 your water. That's what you're looking a waterfall. Right? And e
19:11 is Okay. As are some And so um of course you see
19:17 in your water quality analysis. That's red flag obviously. So all these
19:22 differential media can quantitatively qualitatively show this you. Okay. And this is
19:30 type of such selective differential media. basically we're looking for a gram native
19:37 this water quality. So you don't to deal with grand positive. So
19:41 put a chemical here that will inhibit as a selective part, differential part
19:47 let's put in lactose sugar to see you can ferment or not.
19:52 And these visualizations of different colors on plate are typically due to ph differences
20:00 ph indicators, alternative certain color, know, fermentation or acidic. So
20:06 was fermenting. It will show either color or some other type of
20:11 depending on the ph indicator. Uh an aunt from Atlanta's. You won't
20:15 a color change. That's really a of what these are about. But
20:18 metabolic property we're looking at. Um so with this particular medium this heck
20:31 and you can differentiate coliform. So a coliform. They show up as
20:38 . They may not be may not enough contrast there, but the yellow
20:42 . So these are kind of the colorless opaque. And these are more
20:47 the yellowish types here and yellowish ones the lactose fermenters. Okay. You
20:57 there. So uh these two salmonella shigella most interest for museums? Both
21:10 . Um they don't so they give these totals colonies. They go well
21:17 can I differentiate? Um It's the of a black color. So you
21:22 salmonella is only showing the black color that's due to production of H.
21:27 S. There's like sulfur compounds that convert to H. Two.
21:35 So you can differentiate between the So this is actually kind of
21:38 You can differentiate, enters producers. so anyway the point is these color
21:48 can tell you something about their metabolism ? Whether they have it or
21:53 And so it gives you a really of a quick qualitative result. Um
21:59 easy to interpret. Okay and the quality analysis you often have people that
22:03 working there don't have. So you something that will be easily interpreted.
22:10 , so this is just another So blood auger is one that's used
22:16 often in uh diagnostic purposes uh throat depending what you get. You can
22:25 can indicate strep throat uh the bacterium causes it. Uh And so reactions
22:31 blood are are used for that So especially with the group called
22:40 Okay, this encompasses and we'll talk this later this semester but streptococcus has
22:46 number of pathogens um strep throat. called fever, flesh eating disease?
22:57 cavities Alright, tooth cavities uh gastrointestinal and so a lot of them.
23:05 they historically that you can kind of the types on how they behave on
23:10 augur right? Some some groups some group a strep licenses these red blood
23:18 so it gets a clear zone, zone around them. Others kept different
23:23 . So you kind of differentiating that . So anyway, differential selective
23:28 Okay. Just on the tool you use you know depending on kind of
23:33 you're doing in this case, water analysis or diagnosis of something can
23:38 Okay. Um All right. Any about that in the next 15 20
23:47 on quantity of bacterial growth? Okay we'll go through kind of step by
23:56 . Do a couple of problems and I said it's not that complicated but
24:01 get through it. So this is kind of intro intro not a clicker
24:05 . Um so it's just a It's kind of it's not gonna shock
24:11 . I don't think that just kind to show you, you know double
24:16 time and how that can be a that can indicate a lot of
24:22 Okay and so what we have here a bacterial two types of bacteria,
24:30 has a four hour doubling time and 1 15. Right so doubling time
24:42 the same thing as generation time. , bacteria that binary vision one generation
24:49 be one cell divide into two. . More practical standpoint. We use
24:55 We use generation time uh population to right when we're measuring growth. Okay
25:04 it's it's uh typically use optical We measure the cloudiness of liquid culture
25:13 as a parameter of their growth. optical O. D. Units refers
25:18 optical density. So it has an of 00.5 versus a 12 is much
25:27 . 1.5 indicates absorbed into light as grow as a culture of. So
25:35 you do is it's prone to .5 that time there was a generation
25:42 Okay. Time for it to So um so in on both sides
25:48 we have so so the equation we and this is the real basic equation
25:54 this thing here um Alright here my is not working. Okay. So
26:03 one here uh so in this population . So what's the population of eight
26:10 zero versus sometime in the future T Okay. And is generation
26:18 Okay Um so at 20 hours, many cells do we have, what
26:25 looking for on each side? How many generations are there in 20
26:30 ? OK And so it's a generation or doubling time? On the left
26:37 one generation every four hours and 40 ? We've got five generations. And
26:44 on this side. Oh I'm we keep going. So now we're
26:48 gonna plug in the values. So this is in is is that's
27:00 Not working? That's in. Okay we just plug it in and zero
27:06 10 cells right from up here. and uh multiplied by two to the
27:13 right to the ends we get 320 . But that was for anyway on
27:21 inside It's one generation. Every point every 15 minutes, 15 minutes,
27:29 generation every 15 minutes or .25 Right? 5 28 generations. And
27:36 think you already know how much we're to differ here numbers. Right?
27:41 that's two years of being an 10 to 25th, 7, 10
27:47 25th versus versace versace, jesus, on. Um this versus that huge
28:00 . Right? So just that what not seem like a big 10 times
28:05 huge in terms of how many cells get. E coli has something in
28:08 order of about 15, 20 minutes optimal conditions. Okay now um the
28:16 how fast can attend something in nature produce that many cells in a short
28:24 . Not very often, but there be influx of nutrients somehow that can
28:29 this to happen. We'll look at of those things when we talk about
28:33 ecology because there can be an influx nutrients that can cause of birth but
28:39 days are finite and generally there's very strict competition and nutrients are typically limiting
28:46 you don't get this kind of explosion growth but it can't happen here and
28:50 . So um as we look at , we're going to kind of get
28:56 somewhat from this, this basic Right? And then solve producer producing
29:03 we're in is more easily figure it . Okay, Because once we can
29:09 that number for a lot of different as well. See Okay, so
29:16 so as mentioned you can look at that's certainly producing one generation. They're
29:23 but again we use typically the time a population that double as our generation
29:28 unlimited growth. You may have. recalled from ecology you talked about um
29:37 in the context of microbes necessarily but all fits um remember recall the J
29:44 curve. Right? So if you in our context here with time,
29:52 axis number of cells on this A J shaped curve gives you that
30:01 rapid growth. Of course that doesn't on forever as we all know.
30:06 , it flattens out, right, talk about this in the next section
30:11 on growth curves. Right. But exponential growth can be on occasion where
30:16 does happen, but again it's a thing. And so with the way
30:22 course microbes grow Exponential growth and exponential growth growth are kind of used
30:31 Okay, it just means a very growth 4-8-16 and so forth. This
30:37 of progression here. Okay. And um and so we're dealing with a
30:45 that can change and very big, range of numbers from small to very
30:52 , right? Like a ph scale also a water based and scale.
30:57 ? So you try to kind of compress so you can make it more
31:02 . And when you plot data in way there is a typical growth curve
31:08 would uh get here. So here's density. So again using measurement of
31:16 cloudy liquid getting is bacteria growing um taking the log values of that log
31:25 gives you a this would be the of the very rapid growth that would
31:32 . Okay. And so um so very easy to measure. Okay this
31:38 respected thermometer and liquid culture of bacteria just take samples and you measure any
31:46 . So um so let's uh look uh converting this equation here here into
31:58 that is more manageable as we'll see . Okay. So we're gonna do
32:03 we're gonna solve this equation for little Number of generations. Um so what
32:10 do is we start to start going a lot of the base 10.
32:14 . And we we remember logs Multiplying dividing of logs is a little
32:22 . Okay. And so this expression can be simplified you see in the
32:33 . Right? So this will simplify that so long as the base 10
32:40 the end is the same as Times log base 10 of two.
32:45 that number equals 20.301. Right? that equals that. Okay so you
32:56 so think of that as the as power of growth. Right? This
33:01 growth. Okay? And so then can just solve for n. And
33:06 get that. Okay, so uh very often what we like to do
33:14 a time element to that. so measuring number of generations over time
33:19 can do that. We can get it's called a growth rate comes about
33:24 . Notice just adding time to right? Right here. T.
33:31 T. Okay, so every species kind of growth rate constant,
33:37 Uh brought you grow it there will a growth rate you'll get every time
33:45 grow it you can go the same your bras, you'll always get that
33:49 growth rate constant. Okay, For any species. Okay. And
33:55 the other thing to value here is generation time rights. Okay, this
34:02 per time. Right? So remember this, right? This this right
34:12 , is that which is generations. ? And so we're just putting a
34:18 element to it as well, generations time. So the inverse of that
34:22 the generation time. Okay, so gonna use and these will be again
34:29 to you. So we're gonna use We're gonna use this one.
34:38 And this one for our problems. And it's typical that generation times in
34:48 but you may not see it in for something that's really slow.
34:53 pretty much it's usually minutes. so we're gonna look at this
34:57 I'm not gonna ask you to derive equation on a on a test,
35:04 be given this formula. Um So won't need to memorize that. Okay
35:12 as we do the problems, you'll how this all works. Okay so
35:16 first one here, let's try it your own first. Yeah you do
35:23 not sure about it. It's That's why we're gonna go through
35:26 Um step by step. So the houstonians, cougar Insys has a generation
35:40 . 40 minutes. Okay. Starting five cells in log phase. How
35:46 minutes to produce? About 10,000 Okay so the way I'm gonna show
36:25 you're gonna think it's probably kind of but I just kind of set it
36:29 up. Right? So you kind know logically how we go through each
36:35 . Okay. Okay. It's just camp down. Yeah if you're not
37:05 , just Give it your best Okay. Alright I'm counting down from
37:18 . You anything. Alright so let's through it. So step one like
37:30 said I keep it kind of basic set everything up here so you can
37:34 the logic. So uh so we're zero N. T. Perhaps.
37:39 so going for 5 to 10,000, long is it gonna take? Right
37:44 what we're asking. Okay so we this right generation time is minutes per
37:50 so if you can figure out right basically asking actually uh Yeah,
37:58 we can figure out in, So we can figure out this that's
38:05 end value, Right? Number That's in. Alright. So that's
38:08 this right here. Okay. So know N. T. And
38:12 Zero right here and there. So plug it in. Right? So
38:18 we'll do is we know that. right. 40 minutes per generation is
38:21 we're given. Um If you can a number of generations, right?
38:27 figure this out. Um Then we use that to multiply by our generation
38:36 . Not give us minutes because generations cancel out. Okay? So here's
38:41 we do it, right? So then plug in R. N.
38:46 . Uh N. Zero values five 10,000. Do the math. And
38:51 get 11 generations. Okay. Then we take that multiplied by generation
38:59 is canceled, right? We have minutes, which is 60 minutes in
39:05 hour, 60 times seven is 4 at seven hours. A little over
39:09 hours back to right this one lower . Okay. Um That's okay.
39:22 if you just if you set it like I like I did then I
39:27 it makes sense logically. Okay. wise. Okay. Um And uh
39:34 questions. It's not clicking yet. mean I also know that um because
39:43 says here uh There's like there's like practice problems. Either two of
39:50 There's three new ones in there, there is a sheet in there that
39:54 you the blow by blow like I did it here. It works it
39:57 out. So you're having it's not quick and look through that,
40:03 If you have questions let me Okay um Okay so here's another way
40:09 ask a question. Okay this is for a generation time. Okay.
40:15 actually calculated generation time, so that's generation time is, right? So
40:22 if we have not heard cells for hours That produces over three million
40:30 what will be the generation time? So let's see if we can do
40:34 one timer's on. Okay let's count 54. Okay uh see what we
42:19 here. So we set it Okay parameters 900 minutes. So if
42:31 ever M. T. And Zero. So we figure out a
42:35 of generations, right? And we how much time has elapsed that will
42:40 calculate generation time, right? So . Is almost 12 generations And our
42:49 spans 900 minutes. So divided by and you get 76 minutes.
42:55 So anyway you may might need may may not need to do the set
43:00 kind of a thing, but I if you do that you're less likely
43:03 make mistakes. So but it's up you. Okay but like I said
43:07 more practice problems if you want to through those questions. Uh let me
43:13 . Okay everything questions now. Alright so um of course what do
43:23 do with this stuff? Well if have for example uh you threw at
43:30 time when you're growing the bacteria on certain growth medium and you want to
43:33 can I improve that by including some the nutrients? This will give you
43:38 quantitative answer of that. Uh Maybe testing some kind of antimicrobial and you
43:45 to your culture of control, it's added. Look at generation time.
43:50 there a difference there? So you there's of course practical applications to
43:54 Okay um The okay so speaking of let's go into um growth curve.
44:02 here's a question. Okay so there's parts of this growth curve of course
44:09 different things happen. Each grows Okay so you're looking at that um
44:18 me just explain what batch grows a growth curve is. Okay does anybody
44:23 a water bottle on or other water ? So let's say this is so
44:40 rose just simply you not claim Okay and then the only time I'm
44:47 do anything with this after that point to take samples and measure growth.
44:53 that's what I'm gonna do and then gonna follow it all the way through
44:58 it dies. Okay I'm gonna see kind of growth curve I get and
45:04 all I'm doing. So that's basically one batch right? And we're just
45:08 the cells from birth to death if want to think about it that
45:12 that's what batch growth way there are of that. Uh So uh let's
45:25 what we have here. Okay and like I said we can do manipulations
45:34 just that basic batch growth to get sells. Right? Um And so
45:41 kind of things you know on a scale if you especially biotech majors working
45:49 industry and you're gonna commercialize something maybe micro or some kind of enzyme or
45:55 protein of interest um that you it's practical to work. I mean not
46:03 just to just have tea spoons and . You need buckets and barrels and
46:08 right? Which means you have to these cultures of the high density to
46:12 in the product right? If you're commercialize and make money on it.
46:16 So there's ways to do that as see. Okay so correct answer here
46:30 yes is e. Okay all these true. There's no false ones.
46:40 So you do get cell size changes time. Okay? Um We'll explain
46:48 exponential changes. So certainly there's exponential here. There can also be exponential
46:54 here. There is in death right? So when you're given plentiful
46:59 you can grow like crazy. Okay when you're when nutrients are completely gone
47:07 equally die like crazy going this way it's really this part of the curve
47:15 we focus on in chapter five? looking at control of microbial growth?
47:18 you want to add stuff and kill whether physical or chemical means to make
47:25 die as fast as possible. Um So remember d is about rapid
47:31 , right? When you have rapid is typically when penicillin has better action
47:37 . So it's gonna be in phase . Uh So let's look at the
47:43 of these. Okay so uh so batch growth curve. And um so
47:52 face. Okay which is right here part here now whether um whether how
48:06 this is Right that slag. So begins once you inoculate inoculate needs to
48:13 , it's like planting seeds and adding . Plant growth. Right? You
48:16 cells to a liquid medium. Not . Okay that's what they call it
48:23 . There's a lag before it picks . Okay so that lack many things
48:30 . Is the lag like this? it shorter? Is it maybe gross
48:37 here instead or is it long? . The length of that, like
48:43 of things factoring. Okay so picture bacterium. So what's the nature of
48:52 because that came from something? It be from a plate culture. It
48:57 be from a liquid culture. How was that inoculation growing in liquid culture
49:02 three days? Or the large cells ? Okay. How much did you
49:10 it you had when Miller had 10 did you are the media media in
49:17 one the same. Right. Are , are they completely different?
49:21 Uh so all these factors. So think of kind of the micro
49:27 of the cells. Right. So in an in ocular and that gross
49:31 , whatever it is. And now plop them into something super fresh.
49:35 . Well that's gonna be slight subtle in temperature, ph salinity concentrations before
49:44 to it. So all these factor while the lag place. Okay,
49:51 if you're going from a medium medium its very different. Right? So
49:56 a medium that's very rich. lots of nutrients that can just take
50:01 and I have to make anything and it's going to a million the meeting
50:08 are gonna be put on because I'm be able to start with because it
50:10 to turn on different metabolic pathways to able to grow in this meeting.
50:14 . And all that takes time. . So again, what factors into
50:21 ? How long a lag faces are things growth media type? Physical
50:27 there's probably some slight differences in 02 media. Okay, the age of
50:33 size etc. So all these things in to that lag face. And
50:38 um but once it is out of it goes right, so once it
50:44 acclimated then it takes off. And that can be quite rapid depending
50:50 the growth medium and these other Okay. So of course log represents
50:59 most active metabolically speaking. And so not uncommon that uh in we refer
51:07 what's called mid log phase. Call that mid log if it's producing
51:16 of interest enzyme or whatever that you will like the sample during that time
51:21 figure out to get a good measure the activity. Okay. Now it
51:27 vary depending on what the product is the microbe. Um that's why you
51:34 in the early stages of you are to commercial process a biological process.
51:40 figure out all these parameters called bench which is like small flats and small
51:47 . Right? You can take a of measurements very easily. Right?
51:52 simple experiments very easily with smaller maps stuff. But the ending wrap it
51:59 scaling up. Okay. And so the bench scale you figure out,
52:04 , what is the basic growth curve this meeting? What do I see
52:09 take samples all along the way to , Okay, what is the activity
52:13 my product at different points? Where I measure it at? Where is
52:17 optimal? These are all things you out when you know at this
52:22 Okay, then it becomes Okay, here's the baseline. Now, how
52:28 I enhance things. Right. That's that's now where you manipulate growth
52:33 Right? You have different things To enhance the product formation.
52:39 And so that's a whole other So ultimately you get to a stage
52:45 this is the one that works and scale that up. Okay and scallop
52:50 be anything from 500 Uh 20 gallons two 1000 leaders to um 10,000 or
53:05 seen 100,000 liter tanks. So it depends. Okay but it's all these
53:11 things we're talking about that you do the early stages. Okay so log
53:16 aside from fast growth and lots of , his cell size changes. So
53:23 actually growing lots of cells and that of any kind of this uh if
53:27 drawing out a rod shaped cell and of this kind of state of
53:32 right? Not to sell her in form right? As they split and
53:38 two cells. Right? So the of the cell itself, right?
53:43 get they can elongate and then they big enough and they split and form
53:49 selves. Right? So their biggest log phase. Okay whether a rod
53:54 a caucus, they're gonna be at biggest size and likely in this mid
53:59 phase. Okay. Um So but course you're gonna get to a point
54:07 , sorry up here, Lake Right, and so now that tipping
54:16 where you get so many cells we have enough nutrients to sustain everybody.
54:20 ? So the road is gonna rapidly and death growth rate. Death rate
54:25 much equal. And I'm getting the phase. Okay so uh so now
54:30 kind of becomes survival mode. Okay we're not out of nutrients yet,
54:38 we're certainly limits getting more limited. now these kind of like a stress
54:43 . So as it as the cells kind of limited nutrients, they tend
54:49 then shut off or minimize metabolic pathways don't need. Okay especially those that
54:58 energy. Okay, so like protein is limited to only only critical type
55:06 or four critical type of functions. So size, it's small,
55:11 Um smaller cells just to keep up the right, better able to survive
55:17 being a big one. Big cell it was in the log face.
55:22 And so you know of course as has become limited, you know,
55:27 more cells are dying, right? Dead cells are actually food sources
55:33 right? The celeb diet, they their full of carbohydrates and protein.
55:38 that could be used as a food . So the cells can live off
55:40 for a while. But ultimately when get to hear right, then you're
55:47 . Zero, right? Nothing to . Right? And that's why death
55:52 exponentially right? There's there's nothing no brooks and curves, they're gonna start
55:57 dying very rapidly. Okay, So but there are we mentioned I mentioned
56:05 these types that are per sisters or types. Uh They can prolong they
56:16 stationary phase. I'm not gonna say forever but for a good while they
56:23 rely on a member they can maintain member of potential. So we can
56:29 about the proton pump. So they maintain kind of something like that to
56:35 them for a while. Not enough really gross but remain viable at this
56:41 about remaining viable. Not so much . Okay so but that can sustain
56:47 for a while. Another example of will talk about next time it's forming
56:53 industry. And those sports are kind normal forms of itself. Okay so
56:58 that can be an option depending on cell type. Okay so some things
57:02 can happen when so it's getting these limited states. Some can form a
57:08 some control what's called a cyst which kind of spore like. So there
57:12 be some forms that can allow them survive for a period of time in
57:17 kind of stress states. Okay now not not all not all bacterial or
57:23 types can do this but there are that can. Okay um Okay so
57:31 any questions? So let's look at question here. Okay yeah so this
57:44 let me just get this here. so this one I kind of mentioned
57:51 already but let's do this anyway so bacterial inoculate um Has grown nutrient broth
57:58 sample of his column is transferred to . That's basically. So we're going
58:05 here to hear. Okay so this our kill him this is our batch
58:16 medium. Okay so we're not playing with the culture growing nutrient broth.
58:24 so we have these patterns A. . And C. So note right
58:32 the in Oculus um is grown in broth. Right? It looks like
58:37 . Right so we go from that that we get that. Okay just
58:46 a comparison. So again not like put it in M9. What's it
58:57 look like? Is it gonna look a as well look like be like
59:02 okay time around. Okay. Yeah predicted that. Yeah focus on
60:10 Right. It's all about changing the phase. Right? So um they're
60:17 to a middle meat. So now got a nutrient broth it can get
60:24 nutrients from these components. Give me acid etcetera. You're going to go
60:30 M. Nine. It's gonna it's only got the basics here right?
60:34 so it's gonna have to make these track so to speak. And so
60:40 gonna take time and turning on genes cetera and that means more time.
60:46 lag face. Uh So alright so from that one so let's think about
60:52 in terms of a different example here say that this is N.
61:01 And this is N. B. broth. Okay both those RNB.
61:07 And so the cells the same cell say just say it's equal equal.
61:12 hear an equal here. So number . So the curve, you know
61:21 inflection and whatnot. Right? All kind of looks the same. More
61:27 less. Okay. But of course number of cells. Right. So
61:30 have here and then up here. , so there's a difference there and
61:40 yield. Right? Both grown and but B has more cells.
61:45 So they're both grown on this on nutrient broth. But yet he
61:53 more cells. So that that's that's to what we call batch back
62:02 Okay, So you have batch growth then you can feed that batch,
62:07 can add stuff, right? And growth. Okay, so uh exactly
62:15 we're doing. So we can get a point. So maybe like right
62:20 , right here, we would there at that point we'd add at what
62:33 gonna be the biggest influence in So you another worker glucose would be
62:41 . Right? So added carbon. ? And you can take a trip
62:46 even though it doesn't have broth, can add just add carbon. Doesn't
62:51 . But for me it matters that has to be heated but um he
62:56 lots of things. So and add glucose to your broth that will increase
63:02 . Okay, and uh that's what do. And these kind of biotech
63:11 settings, right? When you're trying get lots of cell yield the way
63:16 get maximum yield is to control everything temperature and ph control oxygen levels control
63:25 source, right? If you do that they'll grow insane. Okay.
63:32 high yields. Okay. You just to figure out what it is that
63:36 like and need makes them happy. . So what you see here on
63:40 left, okay, is a computer controlled, computer controlled setup by
63:48 . Okay. Where you control all parameters? Right over here, our
63:54 again, all programmed for maintaining ph of them are being nutrients. So
64:01 source, likely timed intervals um and all the stuff up here uh tubing
64:10 whatnot coming out the top of the . These are different other controls.
64:16 ? So if you grow uh let's we can do this batch growth.
64:28 ? And we get um that and get a lot of growth. The
64:35 batch thing, right? And we we do it multiple times. Do
64:41 maybe two or three more times. ? And we get up to say
64:45 get up to up to here Let's say we get I don't know
64:50 make up a number. We get 100 od 100 0. D.
64:56 . Optical density, super thick Right? And it takes us let's
65:02 let's say it takes us I don't um you have to add make up
65:08 crazy number 1000 g of glucose and get that high density super high.
65:20 have to do it over three or feedings or more. Okay. But
65:25 get that high. Now the question why Why can't we all be at
65:30 beginning? We have to have it a pain in the butt come in
65:33 add stuff every three or four hours front. You have to worry about
65:41 you do that. It turns out they don't grow. Why was
65:46 The property is something we talked about you three. What might be the
65:55 that they wouldn't uh all this stuff . 1000 g of glucose poured in
66:02 the beginning plus the other stuff. actually high amount of what in that
66:12 ? Yes, maybe uh osmosis So be super hyper tonic. If
66:22 do that. Okay. And that or inhibit growth. So I just
66:27 water. It's fighting water coming out the cell into the surrounding. So
66:32 focused on that and not focused on . Right? So that's why you
66:37 do that. Okay. You have do it, get the meter it
66:42 right over time. Uh If the bank chairman culture is medically fit.
66:48 if you do all this stuff right reactor very quickly become oxygen.
66:55 So heroes in this case and that's what you're growing is ending its
67:00 cell densities and error because that's going give you the most cell density.
67:05 so you control that as well. we can control all these things.
67:09 ? So here's an example of a and a different control. Right?
67:14 we have nutrients oxygen. There's a that measures oxygen concentration, ph and
67:21 probe. So I'm measuring all these . Okay, acid base edition.
67:28 ? Um So um so you measure things, right? And particularly
67:34 you wouldn't think temperature but if you have temperature control, so the water
67:40 , cold water helps to maintain If you didn't have that e coli
67:45 growing up to like 100 ods, glass would be super hot. In
67:51 , itself would die. It gets hot. Remember bio energetic giving out
67:56 as as a part of the And so it can get super hot
68:00 quick when they're growing like crazy. you have to water water control the
68:05 . Um And then of course uh ph is relatively simple. Use ad
68:11 bases needed uh at nutrients um as . And typically these tie together nutrient
68:21 and D. O. Can kind tell you resolve options to kind of
68:24 you when you add more nutrients But then you need to um uh
68:30 auction you can add air, And so it comes in and then
68:37 thing here called the Spar Jer this so that's sort of the area isn't
68:43 bubbled in, right? It's forced through a Spar Jer. Right?
68:48 that does is creates tiny bubbles. ? Gasses makes better into a quick
68:55 if they're tiny bubbles, big So spark. There's always a part
69:01 the process to make it gas more in the liquid. Right? So
69:05 greatly increases absorption. And then the these things here are the whole thing
69:14 called an impeller blades and the terms right, rotate, creating turbulence,
69:21 ? To help mix those gas bubbles the medium as well as other stuff
69:26 . So so typically when D. . Dissolved the auction goes down,
69:31 increase it a combination of things to the turbulence and get mixing, you
69:39 compressed air into the system to get in there. So a combination of
69:43 those things will help you get enough itself will grow very quickly.
69:50 high cell density. Now, if don't have all the sophisticated equipment,
69:56 . And I've been there you can a lot of stuff with just this
70:02 surprisingly okay with just that okay, can control ph now you're doing all
70:11 this. You're doing manually, It's not computer controlled. It's it's
70:16 controlled. Okay. That can be pain in the butt, okay because
70:20 have to constantly monitor it. You to go in at all hours of
70:24 night and whatnot. But nonetheless you have a ph indicator so it turns
70:30 when it's acid ready when it's So you just add the original and
70:35 the red color range. Pop right if it's um uh the the
70:41 . O. Part of the Right we don't have a D.
70:43 . Probe in here but so we can't monitor that. But what we
70:49 do is maximize the amount of air into it. Okay so you notice
70:54 have these little indentations here in the bottom. Right? And so that
71:02 helps create more turbulence, more Okay surprisingly it makes a difference if
71:07 look at a just a flat bottom glass where there's one like this there's
71:11 significant difference in terms of how Okay that plus you can these things
71:16 always in a incubator course and help temperature so you can do that and
71:24 you shake them. It's a platform shakes so you can increase rpm and
71:34 can increase rpm. Have these little they call those baffles baffled flask.
71:41 that that combination can help you get of errands. So you're never gonna
71:46 the equivalent of what you get in thing but I was shocked myself how
71:52 growth you can get with just controlling that way and my manual addition and
71:57 these other things. So again I'm gonna get what you get in a
72:01 . Plus the bioreactors. All computer . Right? But nonetheless you know
72:06 can you can do some things depending the resources you've got. Okay um
72:14 a lot of the stuff I've just talking about this for you, biotech
72:17 . I'm not gonna give you an questions on what esparza is.
72:22 but hopefully you can apply this knowledge . Okay? Um Any questions?
72:32 . So I'm gonna keep. Perfect. Alright, so almost quarter
72:38 , so thanks folks, we'll see on better
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