Epidemiological modelling: Difference between revisions

Revision as of 20:00, 24 June 2014

This page is a knowledge crystal of subtype method. The page identifier is Op_en6353
Moderator:Nobody (see all) Click here to sign up.

Upload data {{#opasnet_base_link:Op_en6353}}

**Progression class**
In Opasnet many pages being worked on and are in different classes of progression. Thus the information on those pages should be regarded with consideration. The progression class of this page has been assessed: This page is a draft The relevat content and structure of the page is already present, but there still is a lot of missing content.	This page needs a curator. Learn more about curating Opasnet pages.

Question

How to predict the net effectiveness of a pneumococcal conjugate vaccination with a given set of serotypes when the vaccine is included in the national immunisation programme?

Focus is on the number of invasive pneumococcal disease (IPD) cases in different age groups.
The model is assumed to be valid in a population in which an infant pneumococcal conjugate vaccination has been in use for several years s.t. a new steady-state after vaccination has been reached. Coverage of vaccination and vaccine efficacy against carriage are assumed to be high enough to justify the assumtion of full elimination of vaccine type carriage among both the vaccinated and also, due to substancial herd effects, among the unvaccinated members of the population.
Vaccine type carriage is fully replaced by carriage of the non-vaccine types and the disease causing potential of different serotypes is not altered by vaccination.

Answer

Predicted number of invasive pneumococcal disease (IPD) cases in different age groups are obtained from the serotype replacement model (Nurhonen and Auranen, 2014).

Rationale

The epidemiological model for pneumococcal carriage and disease is based on the assumption that vaccination completely eliminates the vaccine type carriage in a vaccinated population and this carriage is replaced by non-vaccine type carriage. The implications of this replacement on the decrease or increse in pneumococcal disease then depend on the disease causing potential of the replacing types compared to that of the replaced types. To predict post vaccination disease only pre vaccination data on serotype specific carriage and disease is used.

The consequences of serotype replacement in the model depend on two key assumptions regarding the new steady-state after vaccination:

the relative serotype proportions among the non-vaccine types are not affected by vaccination (proportionality assumption);
the case-to-carrier ratios (the disease causing potentials) of individual serotypes remain at their pre-vaccination levels.

The implications of vaccination on disease incidence are assumed to be solely due to the elimination of vaccine type carriage and its replacement by non vaccine type carriage. An exception to this is when a possibility of efficacy against disease without any efficacy against carriage is assumed for certain serotypes.

Computation

The following program (modified from File S1 in Nurhonen and Auranen, 2014) illustrates the working of the replacement model. In its current implementation the code asks the user to choose a vaccine composition (labelled "New") and then displays the predicted IPD cases in Finland per year corresponding to this vaccine. The results are shown by serotype and by age category (<5 and 5+ year olds) and the corresponding results for PCV10 (labelled "Current") are displayed for comparison.

Instructions for user: Choose the desired vaccine composition from the list below and then press "Run code". The results will be displayed on the right side of the page. The default choice is PCV10 and this should be changed either by adding or removing serotypes as PCv10 is the vaccine to which the new vaccine is compared. For PCV13, add serotypes 6A, 19A and 3.

Initializing the functions

+ Show code - Hide code


library(OpasnetUtils)

#S1.4. The R-functions
###############################################################################
##
## R code for the core methods introduced in
## Markku Nurhonen and Kari Auranen:
## "Optimal serotype compositions for pneumococcal conjugate
## vaccination under serotype replacement",
## PLoS Computational Biology, 2014.
##
###############################################################################
## List of arguments common to most functions:
##
## IPD = matrix of IPD incidences by age class (columns) and serotype (rows)
## Car = corresponding matrix of carriage incidences
## VT_rows = vector of the row numbers in matrices IPD and Car
## corresponding to vaccine types (VT_rows=0 for no vaccination)
## p = proportion of lost VT carriage which is replaced by NVT carriage
## q = proportion of VT carriage lost either due to elimination or replacement
##
## This code includes 4 functions:
## Vaccination, NextVT, OptimalSequence and OptimalVacc.
##

Vaccination<-function(IPD,Car,VT_rows,p,q) {
	##
	## Result:
	## A list of 2 matrices: IPD and carriage incidences
	## after vaccination (corresponding to matrices IPD and Car).
	## [Markku Nurhonen 2013]
	##
	if (VT_rows[1]>0) {
		IPD<-as.matrix(IPD); Car<-as.matrix(Car)
		# Post vaccination carriage incidences
		Car_Total<-t(matrix(apply(Car,2,sum),dim(Car)[2],dim(Car)[1]))
		Car2<-Car; Car2[VT_rows,]<-0
		Car_NVT<-t(matrix(apply(Car2,2,sum),dim(Car2)[2],dim(Car2)[1]))
		Car_VT<-Car_Total-Car_NVT
		CarNew<-q*(1+p*Car_VT/Car_NVT)*Car2+(1-q)*Car
		# Post vaccination IPD incidences
		NVT_rows<-seq(dim(IPD)[1])[-1*VT_rows]
		# CCR=Case-to-carrier ratios
		CCR<-IPD/Car ; IPDNew<-0*IPD
		# Apply the equation appearing above
		# equation (1) in text for each serotype.
		# First term applies to NVTs.
		IPDNew[VT_rows,]<-(1-q)*IPD[VT_rows,]
		# Second term applies to NVTs.
		IPDNew[NVT_rows,]<-((Car_NVT+p*q*Car_VT)*(Car/Car_NVT)*CCR)[NVT_rows,]
		}
	else {
		IPDNew<-IPD; CarNew<-Car
	}
	list(IPDNew,CarNew) 
}

NextVT<-function(IPD,Car,VT_rows,p) {
	##
	## Result:
	## A vector of decreases in IPD due to adding a serotype
	## to the vaccine. If VT_rows=0, initially no vaccination.
	## For row indexes incuded in VT_rows, the result is 0.
	## [Markku Nurhonen 2013]
	##
	IPD<-as.matrix(IPD); Car<-as.matrix(Car)
	
	## VaccMat = IPD and Car matrices after vaccination
	VaccMat<-Vaccination(IPD,Car,VT_rows,p,1)
	IPD<-VaccMat[[1]]; Car<-VaccMat[[2]]
	
	## Total_IPD,Total_Car = Matrices corresponding to
	## overall IPD and carriage in each age class.
	Total_IPD<-t(matrix(apply(IPD,2,sum),dim(IPD)[2],dim(IPD)[1]))
	Total_Car<-t(matrix(apply(Car,2,sum),dim(Car)[2],dim(Car)[1]))
	
	## Effect = decrease in IPD when one serotype is added to the vaccine.
	## See equation (3) in text.
	Effect<-(Total_IPD-IPD)*((IPD/(Total_IPD-IPD))-(p*Car/(Total_Car-Car)))
	
	## Special case when only one NVT remains.
	IPD_nonzero<-which(apply(IPD,1,sum)!=0)
	if (length(IPD_nonzero)==1) {Effect[IPD_nonzero,]<-IPD[IPD_nonzero,]}

	## Result is obtained after summation over age classes.
	apply(Effect,1,sum) 
}

OptimalSequence<-function(IPD,Car,VT_rows,Excluded_rows,p,HowmanyAdded) {
	##
	## Starting from VTs indicated by the vector VT_rows
	## (VT_rows=0, for no vaccination) sequentially add new VTs
	## to the vaccine composition s.t. at each step the optimal
	## serotype (corresponding to largest decrease in IPD) is added.
	##
	## Excluded_rows = Vector of indexes of the rows in matrices
	## IPD and Car corresponding to serotypes that are not to
	## be included in a vaccine composition, e.g. a row
	## corresponding to a group of serotypes labelled "Other".
	## Enter Excluded_rows=0 for no excluded serotypes.
	## HowmanyAdded = number of VTs to be added.
	##
	## Result:
	## Matrix of dimension 2*HowmanyAdded with 1st row indicating
	## the row numbers of added serotypes in the order they appear
	## in the sequence. The 2nd row lists the decreases in IPD
	## due to addition of each type. [Markku Nurhonen 2013]
	##
	IPD<-as.matrix(IPD); Car<-as.matrix(Car)
	## First check the maximum possible number of added VTs.
	VT_howmany<-length(VT_rows)
	if (VT_rows[1]==0) {VT_howmany<-0}
	Excluded_howmany<-length(Excluded_rows)
	if (Excluded_rows[1]==0) {Excluded_howmany<-0}
	HowmanyAdded<-min(HowmanyAdded,dim(IPD)[1]-(VT_howmany+Excluded_howmany))
	BestVTs<-BestEffects<-rep(0,HowmanyAdded)
	## Sequential procedure: at each step find the best additional VT.
	for (i in 1:HowmanyAdded) {
		## Effects = Decrease in IPD after addition of each serotype
		Effects<-NextVT(IPD,Car,VT_rows,p)
		## Set Effects for VTs and excluded types equal to small values
		## so that none of these will be selected as the next VT.
		minvalue<- -2*max(abs(Effects))
		if (Excluded_howmany>0) {Effects[Excluded_rows]<-minvalue}
		if (VT_rows[1]>0) {Effects[VT_rows]<-minvalue}
		## BestVTs[i] = Index of serotype with maximum decrease in IPD.
		BestVTs[i]<-order(-1*Effects)[1]
		## BestEffects[i] = Decrese in IPD due to addition of BestVTs[i]
		## to the vaccine.
		BestEffects[i]<-Effects[BestVTs[i]]
		VT_rows<-c(VT_rows,BestVTs[i])
		if (VT_rows[1]==0) {VT_rows<-VT_rows[-1]}
		VaccMat<-Vaccination(IPD,Car,VT_rows,p,1)
		IPD<-VaccMat[[1]]; Car<-VaccMat[[2]] 
	}
	t(matrix(c(BestVTs,BestEffects),HowmanyAdded,2)) 
}

OptimalVacc<-function(IPD,Car,VT_rows,p,q,HowmanyAdded) {
	##
	## Result:
	## A list of 3 elements: (1) Row numbers of serotypes in the optimal
	## vaccine composition (2)-(3) IPD and carriage incidences
	## by serotype and age class corresponding to the optimal
	## vaccine formed using the sequential procedure in the
	## function OptimalSequence. [Markku Nurhonen 2013]
	##
	Additional_VTs<-OptimalSequence(IPD,Car,VT_rows,p,HowmanyAdded)[1,]
	All_VTs<-c(VT_rows,Additional_VTs)
	if (All_VTs[1]==0) All_VTs<-All_VTs[-1]
	VaccMat<-Vaccination(IPD,Car,All_VTs,p,q)
	list(All_VTs,VaccMat[[1]],VaccMat[[2]]) 
}

VacCar <- Ovariable("VacCar",
	dependencies = data.frame(Name = c(
		"IPD", # incidence of pneumococcus disease
		"Car", # number of carriers of pneumococcus
		"servac", # ovariable of serotypes in vaccine (1 for serotypes in a vaccine, otherwise result is 0)
		"p", # proportion of eliminated VT carriage that is replaced by NVT carriage
		"q" # proportion of of VT carriage eliminated by vaccine
	)), 
	formula = function(...) {
		## Result:
		## An ovariable of carriage incidences
		## after vaccination (corresponding to Car).
		## [Markku Nurhonen 2013, Jouni Tuomisto 2014]
		# Post vaccination carriage incidences
		
		# Sum over serotypes and drop extra columns
		Car_Total<- unkeep(oapply(Car, cols = "Serotype", FUN = sum) * 1, prevresults = TRUE)
		# Car2 is a temporary ovariable with NVT carriers only
		Car2 <- unkeep(Car * (1 - servac), prevresults = TRUE) # Take only NVT carriers
			
		Car_NVT <- oapply(Car2, cols = "Serotype", FUN = sum) # Carriers of serotypes not in vaccine (NVT)
		Car_VT <- Car_Total - Car_NVT # Carriers of vaccine serotypes

		CarNew <- q * (1 + p * Car_VT / Car_NVT) * Car2 + (1 - q) * Car

		return(CarNew)
	}
)
		
VacIPD <- Ovariable("VacIPD",
	dependencies = data.frame(Name = c(
		"IPD", # incidence of pneumococcus disease
		"Car", # number of carriers of pneumococcus
		"servac", # ovariable of serotypes in vaccine (1 for serotypes in a vaccine, otherwise result is 0)
		"p", # proportion of eliminated VT carriage that is replaced by NVT carriage
		"q" # proportion of of VT carriage eliminated by vaccine
	)), 
	formula = function(...) {
		## Result:
		## An ovariable of IPD incidence
		## after vaccination (corresponding to ovariable IPD).
		## [Markku Nurhonen 2013, Jouni Tuomisto 2014]
		
		# Post vaccination carriage incidences (same code as in VacCar)
			
		Car_Total <- unkeep(oapply(Car, cols = "Serotype", FUN = sum) * 1, prevresults = TRUE) # Sums over serotypes
		Car2 <- unkeep(Car * (1 - servac), prevresults = TRUE)
			
		Car_NVT <- oapply(Car2, cols = "Serotype", FUN = sum) # Carriers of serotypes not in vaccine (NVT)
		Car_VT <- Car_Total - Car_NVT # Carriers of vaccine serotypes
		CarNew <- q * (1 + p * Car_VT / Car_NVT) * Car2 + (1 - q) * Car
			
		# Post vaccination IPD incidences
		# CCR=Case-to-carrier ratios
		CCR <- IPD / Car

		# Apply the equation appearing above
		# equation (1) in text for each serotype.
		# First term applies to VTs.
		IPDNewVT <- (1 - q) * IPD * servac

		# Second term applies to NVTs.
		IPDNewNVT <- (Car_NVT + p * q * Car_VT) * (Car / Car_NVT) * CCR * (1 - servac)

		IPDNew <- IPDNewVT + IPDNewNVT

		return(IPDNew) 
	}
)

objects.store(Vaccination, NextVT, OptimalSequence, OptimalVacc, VacCar, VacIPD)

cat("the functions Vaccination, NextVT, OptimalSequence, OptimalVacc and the ovariables VacCar, VacIPD are now saved. \n")

References

Nurhonen M, Auranen K (2014) Optimal Serotype Compositions for Pneumococcal Conjugate Vaccination under Serotype Replacement. PLoS Comput Biol 10(2): e1003477. doi:10.1371/journal.pcbi.1003477

@@ Line 1: / Line 1: @@
+[[op_fi:Epidemiologinen_malli]]
 {{method}}
+{{progression class|progression=Draft}}
-[[op_fi:Epidemiologinen_malli]]
 ==Question==

Parts of the assessment	Comparison criteria for vaccine · Epidemiological modelling · Economic evaluation
Background information	Sensitivity analysis · Replacement · Pneumococcal vaccine products · Finnish vaccination schedule · Selected recent publications Help for discussion and wiki editing
Pages in Finnish	Pneumokokkirokotteen hankinta · Rokotteen vertailuperusteet · Epidemiologinen malli · Taloudellinen arviointi · Pneumokokkirokotteen turvallisuus Work scheduling · Monitoring the effectiveness of the pneumococcal conjugate vaccine · Glossary of vaccine terminology