It's time to visit Florida again - graphically

In May, I showed the following chart that presents a way to understand excess deaths in Florida (link to post):

It was only two months into the pandemic: because actual deaths from death certificates take time to count, it was just a sign of things to come. We start with a projection of expected deaths as by seasonal flu ("pneumonia & influenza") made based on prior flu seasons, expressed as a percentage of total deaths by any cause. In the first two months of the pandemic, the reported deaths by seasonal flu was as much as double the typical percentage of all deaths. On top of that, there were deaths related to Covid-19, which were roughly equal to deaths by seasonal flu during April.

There was no particular reason why seasonal flu deaths should be significantly above normal during the tail end of the 2019-20 flu season so it was suspected that Florida might have been undercounting Covid-19 deaths.

Months later, most of the dust has settled on these earlier months, and many of those deaths appeared to have been reclassified as Covid-19 related. I revisited this analysis below.

***

Let's start with seasonal flu statistics for the past five seasons (from 2015-6 to 2019-2020).

Flu-counting starts in late September/early October each season. According to the CDC, flu season typically reaches a peak in the winter, and lingers on till as late as May. Pneumonia & influenza accounts for 1 to 2 percent of total deaths in any given week of the year, on average in the four seasons prior to 2019-2020. The 2019-20 flu season was a bit late arriving so when Covid-19 cases started getting detected in March, flu deaths were just easing from the seasonal peak.

The above chart - specifically, the thick gray line - establishes what we expect the flu fatalities to be during the pandemic months from March to Oct 2020. The orange lines show the actual deaths attributed to seasonal flu. These counts are definitely smaller than the numbers I found back in May. The revised counts make more sense since the flu is seasonal. (I left out the November data because they are incomplete at the time of writing.)

What happens when we layer on the Covid-19 deaths?

The spike of data ran off the page.

I kept the scale of the lower part the same as before. In March and April, while pneumonia and influenza accounted for 1 to 2 percent of all deaths in Florida, when Covid-19 were lumped with the other two causes, they reached about 8 percent of all deaths, roughly four times as many. In the summer months, over a quarter of the deaths in Florida were linked to Covid-19, pneumonia or influenza.

In a normal flu season, we might see 50 to 100 deaths per week in Florida due to pnuemonia or influenza. Since April, Florida has suffered Covid-19 deaths in the hundreds, and during the peak in the summer, over a thousand per week, roughly 10 times above expectation.

Here's a gif that shows the top of the chart:

 

 

 

The press-release derby has set an unrealistic bar for the coronavirus vaccine

Regarding the Pfizer vaccine trial results, statisticians are tempted to say that the signal (the vaccine's share of cases) was so strong that we can let down our myriad defenses. As I explain today, this is not quite true. It depends on which signal we're talking about.

If the question is whether the Pfizer vaccine is at least 50 percent effective, then we don't have much to worry about. Nevertheless, the press release derby has created extremely high expectations - if the question is whether the Pfizer vaccine is at least 90 percent effective, then the finding is highly sensitive to shifts of just a few cases. I'll show below that we can be secure in making a statement such as that the Pfizer vaccine is at least 80 percent effective.

***

The basic strategy of a Bayesian analysis yields a probability estimate of the efficacy of the vaccine being tested (VE), given the results from the vaccine trial. The outcome is a probability estimate for any value of VE. According to the Pfizer protocol, the U.S. regulators are interested in a specific estimate: the chance that VE is higher than 30 percent.

The result from the vaccine trial is expressed as the vaccine's share of cases (VSC), which is the proportion of detected cases that came from the vaccine arm of the trial (the other arm being the placebo). Intuitively, the better is the vaccine, the lower its share of cases.

Enrollment in the Pfizer trial can be stopped when the trial records 170 cases. The most recent press release from Pfizer reported that out of those 170 cases, only 8 came from the vaccine arm, thus the observed VSC was 8/170 = 5 percent. This translates to 95% VE: in other words, the case rate in the vaccine arm was merely 5% that in the placebo arm.

(Notice that the average case rate is very low: 170/43000 = 0.4% about 2 months since enrollment, therefore it is wrong to say that 95 percent of vaccinated people will be protected - most people in the trial have not yet been exposed to the virus!)

If any of the above is unclear, please review my prior posts about the Pfizer analysis (here and here).

***

I was wondering how sensitive the result is to the observed VSC. If the trial had found 9 or 10 cases, instead of 8, among the vaccine arm, how much would our conclusion change?

I use the chart below to answer this question:

First, look at the red line. This shows the probability that vaccine efficacy (VE) is over 90 percent, given the trial results. The actual trial result is indicated by the down arrow - eight cases in the vaccine arm out of 170 total cases. The corresponding dot above says there is a 98% chance that VE > 90%. That's what the Pfizer press release wants to tell us.

Now, notice how steeply the line drops as we move from 8 to 10 to 12 cases: 98% -> 93% -> 81%. To achieve the typical standard of 95% confidence, this probability has to clear 97.5%. This means that the 8 reported cases were sitting on the edge. One more case, and the claim of over 90% VE is shaken.

This might sound like bad news for Pfizer. If it does, it's Pfizer's own doing. Because of the press release derby, it feels like VE needs to be above 90%. Remember those days when we hoped VE is at least 50 percent?

So I did the same analysis for the probability that VE is over 50 percent, as the number of cases in the vaccine arm increases. This is shown as blue dots. Notice that these dots hug the 100% line for dear life. Even if the vaccine arm found 25 cases (out of 170), we can still say with complete confidence that the VE of Pfizer's vaccine is over 50 percent.

Let's double the number of cases coming from vaccinated participants to 16. If you draw a vertical line at 16, it will hit the light pink dots at 99 percent. Those dots represent VE greater than 80 percent. We are highly confident that VE is over 80 percent, even if the vaccinated participants suffered twice as many cases as observed in the vaccine trial.

***

When discussing these vaccine trial data, please bear in mind the following:

1) Recall that the 40,000 or so participants are not monitored every day. The cases are self-reported, and the participants who report symptoms are then tested. At most one mandatory follow-up of the entire set of participants has occurred so far.

2) The claim of 90% or above efficacy is delicate. Shifts of one or a few cases matter. Bear in mind that a small number of participants may be excluded from the analysis. These can have completely legitimate reasons; notstanding, such exclusions can swing the outcome. That said, claiming about 80% efficacy shuold be very solid.

Pfizer modeling in Python

Here is code for those who want to play around with the Bayesian analysis used in the Pfizer vaccine trial study (Related blog post here). I got a request for Python code so here it is. The charts I published the other day were made in R.

# Python code for Pfizer vaccine trial analysis

import pandas as pd
import numpy as np
from scipy.stats import beta
import matplotlib.pyplot as plt


# functions

def ve2vsc (ve):
	if isinstance(ve, pd.Series) is False:
		ve = pd.Series(ve)
	return ((1-ve)/(2-ve)).round(3)

def vsc2ve (vsc):
        if isinstance(vsc, pd.Series) is False:
                vsc = pd.Series(vsc)
	return ((1-2*vsc)/(1-vsc)).round(3)

ve = pd.Series(np.linspace(0,1,11))
vsc = ve2vsc(ve)


# line chart showing VSC and VE relationship

plt.plot(ve, vsc, color="darkgray", lw=3)
plt.title("Relationship between Vaccine Efficacy and Vaccine's Share of Cases")
plt.xlabel("ve")
plt.ylabel("vsc")

ax = plt.gca()
ax.spines['right'].set_color("none")
ax.spines['top'].set_color("none")
ax.spines['bottom'].set_position(('data',0))
ax.spines['left'].set_position(('data',0))

xlabels = (ve*100).astype('int').astype('str')+"%"
xlabels[list(range(1,11,2))] = ""
plt.xticks(ve, xlabels) 
plt.yticks(pd.Series(np.linspace(0,0.5,6)), (pd.Series(np.linspace(0,50,6))).astype('int').astype("str")+"%")

ax.hlines(ve2vsc(0.5), 0, 0.5, color="brown", ls="dotted")
ax.vlines(0.5, 0, ve2vsc(0.5), color="brown", ls="dotted")
ax.hlines(ve2vsc(0.9), 0, 0.9, color="brown", ls="dotted")
ax.vlines(0.9, 0, ve2vsc(0.9), color="brown", ls="dotted")

plt.text(0.02,ve2vsc(0.5)[0]+0.02,(ve2vsc(0.5)[0]*100).astype("int").astype("str")+"%", color="brown", fontsize=8)
plt.text(0.02,ve2vsc(0.9)[0]+0.02,(ve2vsc(0.9)[0]*100).astype("int").astype("str")+"%", color="brown", fontsize=8)

plt.show()

# plotting the posterior

a1 = 0.700102	        # From protocol
b1 = 1			# From protocol
data_x = 8		# Number of cases in vaccine arm
data_n = 94		# Total number of cases

def a2 (a1, x):
	return a1 + x

def b2 (b1, n, x):
	return b1 + n - x

def vsc_posterior(samp, data_x):
	return pd.Series(beta.pdf(samp, a2(a1,data_x), b2(b1,data_n, data_x)))

vsc_sample = pd.Series(np.linspace(0,0.5,72))

# single posterior curve vs vsc

plt.plot(vsc_sample, vsc_posterior(vsc_sample, 8), lw=3)
plt.title("Predicted Prob. of Vaccine's Share of Cases")
plt.xlabel("VSC")
plt.ylabel("Probability")

ax = plt.gca()
ax.spines['right'].set_color("none")
ax.spines['top'].set_color("none")
ax.spines['bottom'].set_position(('data',0))
ax.spines['left'].set_position(('data',0))

plt.xticks(pd.Series(np.linspace(0,0.5,6)), (pd.Series(np.linspace(0,50,6))).astype('int').astype('str')+"%") 
plt.yticks(pd.Series(range(0,21,4)), [""]*6)

plt.show()

# posterior vs ve

plt.plot(vsc2ve(vsc_sample), vsc_posterior(vsc_sample, 8), lw=3)

xlabels = (pd.Series(range(0,110,10))).astype("str")+"%"
xlabels[list(range(1,11,2))] = ""
xlabels

plt.xticks(pd.Series(np.linspace(0,1.0,11)), xlabels) 
plt.yticks(pd.Series(range(0,21,4)), [""]*6)
plt.title("Predicted Prob. of Vaccine Efficacy")
plt.xlabel("ve")
plt.ylabel("probability")

plt.show()


# three posterior curves vs ve

plt.plot(vsc2ve(vsc_sample), vsc_posterior(vsc_sample, 3), color="blue", lw=1.5, linestyle="dashed", alpha=0.4)
plt.plot(vsc2ve(vsc_sample), vsc_posterior(vsc_sample, 47), color="purple", lw=1.5, linestyle="dashed", alpha=0.4)
plt.plot(vsc2ve(vsc_sample), vsc_posterior(vsc_sample, 8), 
	color="darkgray", lw=3)

ax = plt.gca()
ax.spines['right'].set_color("none")
ax.spines['top'].set_color("none")
ax.spines['bottom'].set_position(('data',0))
ax.spines['left'].set_position(('data',0))

xlabels = (pd.Series(np.linspace(0,100,11))).astype("int").astype("str")+"%"
xlabels[list(range(1,10,2))] = ""
xlabels

plt.xticks(pd.Series(np.linspace(0,1.0,11)), xlabels) 
plt.yticks(pd.Series(range(0,21,4)), [""]*6)
plt.title("Predicted Prob. of Vaccine Efficacy")
plt.xlabel("ve")
plt.ylabel("probability")

plt.text(0.02,vsc_posterior(vsc_sample, 47).max().round(2)+0.2,"47-47", color="purple", fontsize=8)
plt.text(0.02,vsc_posterior(vsc_sample, 47).max().round(2)+1,"No Effect", color="purple", fontsize=8)
plt.text(0.88,vsc_posterior(vsc_sample, 3).max().round(2)-0.2,"3-91", color="blue", fontsize=8)
plt.text(0.88,vsc_posterior(vsc_sample, 3).max().round(2)+0.5,"BEST", color="blue", fontsize=8)
plt.text(0.82,vsc_posterior(vsc_sample, 8).max().round(2)+0.2,"8-86", color="darkgray", fontsize=8)
plt.text(0.82,vsc_posterior(vsc_sample, 8).max().round(2)+1,"DATA", color="darkgray", fontsize=8, weight="bold")

plt.show()


# prior and posterior vs ve

vsc_prior = pd.Series(beta.pdf(vsc_sample, a1, b1))

plt.plot(vsc2ve(vsc_sample), vsc_prior, color="magenta", lw=1.5, ls="dashed", alpha=0.5)
plt.plot(vsc2ve(vsc_sample), vsc_posterior(vsc_sample, 8), 
	color="darkgray", lw=3)

ax = plt.gca()
ax.spines['right'].set_color("none")
ax.spines['top'].set_color("none")
ax.spines['bottom'].set_position(('data',0))
ax.spines['left'].set_position(('data',0))

xlabels = (pd.Series(np.linspace(0,100,11))).astype("int").astype("str")+"%"
xlabels[list(range(1,10,2))] = ""
xlabels

plt.xticks(pd.Series(np.linspace(0,1.0,11)), xlabels) 
plt.yticks(pd.Series(range(0,21,4)), [""]*6)
plt.title("Prior and Posterior Prob. of Vaccine Efficacy")
plt.xlabel("ve")
plt.ylabel("probability")

plt.text(0.15, 2,"prior", color="magenta", fontsize=8)
plt.text(0.76,12,"posterior", color="darkgray", fontsize=8)

plt.show()


# compute probability VE > 30%, 70% and 90% given 8-86 split of cases

beta.cdf(ve2vsc(0.3), a2(a1,8), b2(b1,data_n, 8))[0].round(3)
beta.cdf(ve2vsc(0.7), a2(a1,8), b2(b1,data_n, 8))[0].round(3)
beta.cdf(ve2vsc(0.9), a2(a1,8), b2(b1,data_n, 8))[0].round(3)

Good vaccine news without glorifying faux precision

The vaccine trials are slipping into parody with the way the scientific results are being dangled over a hungry press. It's clear that the news is great but let's not pump irrational exuberance over magical precision.

The most responsible thing to say at this point is that we have multiple highly promising vaccine candidates that have self-reported short-term efficiacy up to about 90 percent; if a vast majority of the world gets vaccinated, the world may successfully defeat the coronavirus.

***

When reading vaccine trial results, bear in mind the following:

• No clinical trial can yield an efficacy estimate as precise as 90% or 95% or 94.5%. When a statistician say 90%, we mean 90% around a margin of error. To have highly precise estimates, we must have tiny margins of error. (See also end note.)
  
  
• The precision of a statistical estimate depends on the sample size. The larger the sample size, the more precise is the estimate. In accelerated vaccine trials, decisions are being made based on only 100-150 cases, so the margins of error are not tiny.
  
  
• The difference between 90% and 95% is meaningless. The difference between 94.5% and 95% is especially pointless; it may win PR points but it suggests lack of seriousness to statisticians.
  
  
• Participants in any clinical trial do not constitute a random selection from the entire population - there are self-selection bias and exclusion criteria. The trial results are extrapolated to the entire population, and that's another reason the efficacy estimates are imprecise.
  
  
• Subgroup analysis is shaky at this stage. When filtered to subgroups, the sample sizes get even smaller, and the error bars are wider around the reported number. For example, Pfizer  stated efficacy for people over 65 was 94%. This number is essentially the same as the average efficacy for all age groups. But the error bar for the over-65 people is much wider than the error bar for the average participant.
  
  
• Press releases may highlight particular effectiveness for some subgroup; remember that this also means it is less effective for some other subgroup. AstraZeneca, for example, disclosed 90% efficacy for the 1.5-dose treatment. SInce the average efficacy was 70%, we know that the efficacy for the 2-dose treatment must be lower than 70%.

All three vaccines - Pfizer, Moderna, AstraZeneca - look promising from the short-term efficacy angle (even 60% isn't a bad result). It's hard to say more until the scientific reports are published. Efficacy or other health metrics are not the only consideration; cost, ease of transportation and storage, the schedules of availability, quantities, etc. - very practical matters - also must be evaluated.

 

***

The AstraZeneca result that just came out contains a mystery. In the design protocol, there isn't a 1.5-dose treatment so where did that come from? What the researchers appear to be saying is that an execution error - affecting a quarter of participants receiving the vaccine shots - resulted in a lower-than-expected first dose so the vaccine arm were split into two subgroups for analysis.

Most reporters have not noticed this abberation, or if they did, they didn't think it is material. This accident is immaterial only if the execution error affected a random subset of participants. In a clinical trial, we use randomization to ensure the two arms differ only by whether participants receive the vaccine or the placebo. If a third arm is added, it too must be randomly assigned. In the AstraZeneca/Oxford trial, we know the vaccine vs. placebo assignment is explicitly randomized but not so the split between 1.5 and 2 doses within the vaccine arm.

Execution errors sometimes have systematic causes, and may not be random. It's always risky to assume random, as I explained in this post.

What will happen is the researchers will give a story explaining the execution error in the scientific report, and argue why they can assume the errors were randomly scattered among the vaccine arm. This will be hard to prove. One common analysis is to show that the demographic and prior health characteristics of the group that received 1.5 doses are statistically identical to those of the group that received 2 doses. This is necessary but not sufficient; nevertheless, it will be considered good enough.

For those of us who run lots of testing, our worst nightmare is to have execution errors. What happens now is you have to trust the people, instead of trusting the (pre-registered) process. You have to trust our explanations about the errors, and the analyses justifying the assumption of random error.

I'm also curious how cutting the sample size by 75% has not affected the statistical significance of the result. That will come out in the scientific report.

That said, the average efficacy of about 70 percent is still a good result. I don't want you to think AstraZeneca's vaccine is bad. In fact, it has several advantages in terms of cost, storage, and so on.

 

P.S. The relationship between uncertainty and precision may not feel intuitive. The following probability curve is reproduced from my prior post. This curve shows the probability of vaccine efficacy ("posterior", in the sense of after looking at the data from the clinical trial).

The peak of this curve shows that the most likely value of vaccine efficacy is about 91% based on 8 cases in the vaccine group among a total of 94 cases.

The curve also shows we believe the vaccine efficacy to have a value between (roughly) 70% and 100%. Since the total probability of all possible values is 1, the total area under the curve between 70% and 100% should be exactly 1.

If you draw a vertical line under the peak of 91%, the area of that line is zero (height x 0 = 0). In other words, the probability of a precise estimate is zero. A statement such as efficacy is 91% has zero probability. But we can make other statements, e.g. efficacy is between 90% and 92%: the probability of this is the area under the curve between the values of 90% and 92%. This has positive probability.

The wider the margin of error, the larger the area under the curve, the higher the probability.