logarithmic growth phase

Examples of logarithmic growth phase in the following topics:

• Preserving Bacterial Cultures

  • While it is possible to make a long term stock from cells in the stationary phase, ideally your culture should be in logarithmic growth phase.

• Generation Time

  • In autecological studies, bacterial growth in batch culture can be modeled with four different phases: lag phase, exponential or log phase, stationary phase, and death phase .
  • The exponential phase (sometimes called the log phase or the logarithmic phase) is a period characterized by cell doubling.
  • For this type of exponential growth, plotting the natural logarithm of cell number against time produces a straight line.
  • This chart shows the logarithmic growth of bacteria.
  • The phases of growth are labelled on top.

• Units of Measurement for Microbes

  • Microbial growth is an important measure in understanding microbes.
  • Since there are limits on space, food, and other factors, actual growth never matches actual measured growth.
  • This chart shows the logarithmic growth of bacteria.
  • Note the Y-axis scale is logarithmic meaning that the number represents doubling.
  • The phases of growth are labelled on top.

• Enrichment and Isolation

  • During lag phase, bacteria adapt themselves to growth conditions.
  • Exponential phase (sometimes called the log or logarithmic phase) is a period characterized by cell doubling.
  • In comparison to batch culture, bacteria are maintained in exponential growth phase, and the growth rate of the bacteria is known.
  • Bacterial growth in batch culture can be modeled with four different phases: lag phase (A), exponential or log phase (B), stationary phase (C), and death phase (D).
  • List the growth phases of microrganisms and the different types of growth media available to culture them

• Solving General Problems with Logarithms and Exponents

  • Logarithms are useful for solving equations that require an exponential term, like population growth.
  • Logarithms have several applications in general math problems.
  • We can rewrite logarithm equations in a similar way.
  • If you are asked to rewrite that logarithm equation as an exponent equation, think about it this way.
  • This population growth graph shows that it grows exponentially with time.

• Natural Logarithms

  • The natural logarithm is the logarithm to the base e, where e is an irrational and transcendental constant approximately equal to 2.718281828.
  • The natural logarithm is the logarithm with base equal to e.
  • For example, the doubling time for a population which is growing exponentially is usually given as ${\ln 2 \over k}$ where $k$ is the growth rate, and the half-life of a radioactive substance is usually given as ${\ln 2 \over \lambda}$ where $\lambda$ is the decay constant.
  • Using the power rule of logarithms it can then be written as:
  • The graph of the natural logarithm lies between the base 2 and the base 3 logarithms.

• Biofilms

  • When a cell switches to the biofilm mode of growth, it undergoes a phenotypic shift in behavior in which large suites of genes are differentially regulated.
  • Recent evidence has shown that one fatty acid messenger, cis-2-decenoic acid, is capable of inducing dispersion and inhibiting growth of biofilm colonies.
  • For instance, the biofilm form of Pseudomonas aeruginosa has no greater resistance to antimicrobials than do stationary-phase planktonic cells, although when the biofilm is compared to logarithmic-phase planktonic cells, the biofilm does show greater resistance to antimicrobials.
  • This resistance to antibiotics in both stationary phase cells and biofilms may be due to the presence of persister cells.

• Interphase

  • During interphase, the cell undergoes normal growth processes while also preparing for cell division.
  • The centrosome is duplicated during the S phase.
  • There may be additional cell growth during G2.
  • The cell cycle consists of interphase and the mitotic phase.
  • Interphase is followed by the mitotic phase.

• Growth models

  • Kazanjian and Drazin (1980), for example, developed a four-phase growth model, and identified the typical growth problems of fast-growing firms in each phase.
  • Phase 3, Growth: The fast-growth phase is characterized by its focus on the market.
  • Phase 4, Stability: In this phase the focus lies on consolidating the market position with the initial product, and developing further products.
  • Firm growth does not always develop through the phases of such models in a straightforward, linear way, for example.
  • A period of experimentation is followed by a stabilization phase.

• Growth Rate and Temperature

  • Bacterial growth is the division of one bacterium into two daughter cells in a process called binary fission.
  • When Escherichia coli is exposed to a temperature drop from 37 to 10 degrees Celsius, a four to five hour lag phase occurs and then growth is resumed at a reduced rate.
  • During the lag phase, the expression of around 13 proteins, which contain cold shock domains is increased two- to ten-fold.
  • Bacterial growth in batch culture can be modeled with four different phases: (A) the lag phase, when the population stays roughly the same; (B) the exponential, or log, phase, when the population grows at an increasing rate; (C) the stationary phase, when population growth stagnates; and (D) the death phase, when bacteria begin to die off and the population decreases in size.
  • Describe how the growth of bacteria is affected by temperature and how bacterial growth can be measured