I'm trying to calculate the doubling time of cells using a scatterplot. This is my dataframe

df = data.frame("x" = 1:5, "y" = c(246, 667, 1715, 4867, 11694))

and I've graphed this dataframe using this code

plot(df$x, df$y, xlab = "days", ylab = "cells mL -1")

Does anyone know how to calculate the doubling time of these cells using the graph? the equation for doubling time is (ln(2)/rate constant)

  • i'm not sure what your question is, are you asking how to get the rate constant value? ln(2) would be log(2) – rawr Feb 2 '20 at 17:38
  • I'm trying to find the amount of time it takes for the cells to double in concentration – Kristen Cyr Feb 2 '20 at 17:42
  • Your code does not work. Try editing it so that you actually get a plot. If the number of cells on Day 1 is 246, how many days does it take to get to 492? You can't get that answer very precisely by looking at the plot. – dcarlson Feb 2 '20 at 17:42
  • is there no way to get a line of best fit and from there calculate the slope of the line? – Kristen Cyr Feb 2 '20 at 17:46

Plot log2(y) vs. x suppressing the Y axis so that we can build a nicer one. We also improved the Y axis label slightly. Then use axis to build a pretty axis and calculate the doubling time. Note that the formula for doubling time in the question works if the rate constant is the slope of the log(y) ~ x regression line but if we use the regression log2(y) ~ x, i.e. log2 instead of log, then the correct formula is just 1/slope. We show both below.

plot(df$x, log2(df$y), xlab = "days", ylab = "cells/mL", yaxt = "n")
s <- 1:round(log2(max(df$y)))
axis(2, s, parse(text = sprintf("2^%d", s)))

fm <- lm(log2(y) ~ x, df)

doubling.time <- 1/coef(fm)[[2]]
## [1] 0.7138163

log(2)/coef(lm(log(y) ~ x, df))[[2]] # same
## [1] 0.7138163

legend("topleft", paste("doubling time:", round(doubling.time, 3), "days"), bty = "n")



You can plot the points to show the exponential rise and then linearize the function by applying log2 to the y values. With that you can plot and do a linear fit:

 df = data.frame("x" = 1:5, "y" = c(246, 667, 1715, 4867, 11694))
 plot(df)  # plot not displayed
 plot(df$x, log2(df$y))

enter image description here

lm(formula = log2(y) ~ x, data = df)

(Intercept)            x  
      6.563        1.401    #the x-coefficient is the slope of the line


#[1] 0.4951051

Checking with the original (not-displayed plot that does look like a sensible estimate of doubling time. Be sure to cite this posting if this happens to be a homework problem.

If I were tasked with using the original graph, first draw an exponential curve by hand. I would then draw two horizontal lines at y= 2000 and y=4000 and then drop perpendicular lines from their intersections with the curve and read off the difference in x values on the horizontal axis.That is what I meant by my comment above that I "checked" the log2/x-coef value for sensibility.


You can visualize the constant rate of change with ggplot2 by scaling the y-axis accordingly:


df = data.frame("x" = 1:5, "y" = c(246, 667, 1715, 4867, 11694))

fit <- lm(data = df, log2(y) ~ x)
tidy_fit <- tidy(fit) %>% 
  mutate(x = 3, y = 2048)

ggplot(df, aes(x = x, y = y)) +
  geom_point() +
  scale_y_continuous(name = "log2(y)", 
                     trans = 'log2', 
                     breaks = trans_breaks("log2", function(x) 2^x),
                     labels = trans_format("log2", math_format(2^.x))) +
  geom_smooth(method = "lm", se = FALSE) +
            mapping = aes(
              x = x,
              y = y,
              label = paste0("log2(y) = ", round(estimate[1], 2), " + ", round(estimate[2], 2), "x",
                             "\n", "Doubling Time: ", round(1 / tidy_fit$estimate[2], 2), " Days")
            nudge_x = -1,
            nudge_y = 0.5,
            hjust = 0)

Created on 2020-02-03 by the reprex package (v0.3.0)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.