{{Short description|Using mathematical models to understand infectious disease transmission}} {{cs1 config|name-list-style=vanc|display-authors=6}} [[Mathematical model]]s can project how [[infectious diseases]] progress to show the likely outcome of an [[epidemic]] (including [[Plant disease forecasting|in plants]]) and help inform [[public health]] and plant health interventions. Models use basic assumptions or collected statistics along with mathematics to find [[parameter]]s for various infectious diseases and use those parameters to calculate the effects of different interventions, like mass [[vaccination]] programs. The modelling can help decide which intervention(s) to avoid and which to trial, or can predict future growth patterns, etc.
==History==
The modelling of infectious diseases is a tool that has been used to study the mechanisms by which diseases spread, to predict the future course of an outbreak and to evaluate strategies to control an epidemic.{{sfn|Daley|Gani|1999|p={{pn|date=January 2025}}}}
The first scientist who systematically tried to quantify [[causes of death]] was [[John Graunt]] in his book ''Natural and Political Observations made upon the Bills of Mortality'', in 1662. The bills he studied were listings of numbers and causes of deaths published weekly. Graunt's analysis of causes of death is considered the beginning of the "theory of competing risks" which according to Daley and Gani{{sfn|Daley|Gani|1999|p={{pn|date=January 2025}}}} is "a theory that is now well established among modern epidemiologists".
The earliest account of [[mathematical modelling]] of spread of disease was carried out in 1760 by [[Daniel Bernoulli]]. Trained as a physician, Bernoulli created a mathematical model to defend the practice of inoculating against [[smallpox]].<ref>{{cite journal | vauthors = Hethcote HW | date = 2000 | title = The mathematics of infectious diseases | journal = SIAM Review | volume = 42 | issue = 4 | pages = 599–653 |doi=10.1137/S0036144500371907| bibcode = 2000SIAMR..42..599H }}</ref> The calculations from this model showed that universal inoculation against smallpox would increase the [[life expectancy]] from 26 years 7 months to 29 years 9 months.<ref name="pmid15334536">{{cite journal | vauthors = Blower S, Bernoulli D | title = An attempt at a new analysis of the mortality caused by smallpox and of the advantages of inoculation to prevent it | journal = Reviews in Medical Virology | volume = 14 | issue = 5 | pages = 275–88 | date = 2004 | pmid = 15334536 | doi = 10.1002/rmv.443 }}</ref> Daniel Bernoulli's work preceded the modern understanding of [[germ theory]].<ref>{{cite book |doi=10.1016/B978-0-12-802260-3.00001-8 |chapter=D. Bernoulli: A pioneer of epidemiologic modeling (1760) |title=A Historical Introduction to Mathematical Modeling of Infectious Diseases |date=2017 |pages=1–20 |isbn=978-0-12-802260-3 | vauthors = Foppa IM }}</ref>
In the early 20th century, William Hamer{{sfn|Hamer|1929|p={{pn|date=January 2025}}}} and [[Ronald Ross]]{{sfn|Ross|1910|p={{pn|date=January 2025}}}} applied the [[law of mass action]] to explain epidemic behaviour.
The 1920s saw the emergence of compartmental models. The [[Kermack–McKendrick theory|Kermack–McKendrick epidemic model]] (1927) and the [[Reed–Frost model|Reed–Frost epidemic model]] (1928) both describe the relationship between [[Susceptible individual|susceptible]], infected and [[immunity (medical)|immune]] individuals in a population. The Kermack–McKendrick epidemic model was successful in predicting the behavior of outbreaks very similar to that observed in many recorded epidemics.{{sfn|Brauer|Castillo-Chavez|2012|p={{pn|date=January 2025}}}}
Recently, [[agent-based model]]s (ABMs) have been used in exchange for simpler [[Compartmental models in epidemiology|compartmental models]].<ref>{{cite journal | vauthors = Eisinger D, Thulke HH | title = Spatial pattern formation facilitates eradication of infectious diseases | journal = The Journal of Applied Ecology | volume = 45 | issue = 2 | pages = 415–423 | date = April 2008 | pmid = 18784795 | pmc = 2326892 | doi = 10.1111/j.1365-2664.2007.01439.x | bibcode = 2008JApEc..45..415E }}</ref> For example, epidemiological ABMs have been used to inform public health (nonpharmaceutical) interventions against the spread of [[Severe acute respiratory syndrome coronavirus 2|SARS-CoV-2]].<ref>{{cite journal | vauthors = Adam D | title = Special report: The simulations driving the world's response to COVID-19 | journal = Nature | volume = 580 | issue = 7803 | pages = 316–318 | date = April 2020 | pmid = 32242115 | doi = 10.1038/d41586-020-01003-6 | bibcode = 2020Natur.580..316A | doi-access = free }}</ref> Epidemiological ABMs, in spite of their complexity and requiring high computational power, have been criticized for simplifying and unrealistic assumptions.<ref>{{cite journal |last1=Squazzoni |first1=Flaminio |last2=Polhill |first2=J. Gareth |last3=Edmonds |first3=Bruce |last4=Ahrweiler |first4=Petra |last5=Antosz |first5=Patrycja |last6=Scholz |first6=Geeske |last7=Chappin |first7=Émile |last8=Borit |first8=Melania |last9=Verhagen |first9=Harko |last10=Giardini |first10=Francesca |last11=Gilbert |first11=Nigel |title=Computational Models That Matter During a Global Pandemic Outbreak: A Call to Action |journal=Journal of Artificial Societies and Social Simulation |date=2020 |volume=23 |issue=2 |doi=10.18564/jasss.4298 |doi-access=free |hdl=10037/19057 |hdl-access=free }}</ref><ref>{{cite journal | vauthors = Sridhar D, Majumder MS | title = Modelling the pandemic | journal = BMJ | volume = 369 | article-number = m1567 | date = April 2020 | pmid = 32317328 | doi = 10.1136/bmj.m1567 | doi-access = free }}</ref> Still, they can be useful in informing decisions regarding mitigation and suppression measures in cases when ABMs are accurately calibrated.<ref>{{cite journal | vauthors = Maziarz M, Zach M | title = Agent-based modelling for SARS-CoV-2 epidemic prediction and intervention assessment: A methodological appraisal | journal = Journal of Evaluation in Clinical Practice | volume = 26 | issue = 5 | pages = 1352–1360 | date = October 2020 | pmid = 32820573 | pmc = 7461315 | doi = 10.1111/jep.13459 | url = }}</ref>
==Assumptions== Models are only as good as the assumptions on which they are based. If a model makes predictions that are out of line with observed results and the mathematics is correct, the initial assumptions must change to make the model useful.<ref>{{cite journal | doi=10.1111/1469-0691.12308 | title=Mathematical modelling and prediction in infectious disease epidemiology | year=2013 | last1=Huppert | first1=A. | last2=Katriel | first2=G. | journal=Clinical Microbiology and Infection | volume=19 | issue=11 | pages=999–1005 | pmid=24266045 | doi-access=free }}</ref> * Rectangular and stationary [[Population pyramid|age distribution]], i.e., everybody in the population lives to age ''L'' and then dies, and for each age (up to ''L'') there is the same number of people in the population. This is often well-justified for developed countries where there is a low infant mortality and much of the population lives to the life expectancy. * Homogeneous mixing of the population, i.e., individuals of the population under scrutiny assort and make contact at random and do not mix mostly in a smaller subgroup. This assumption is rarely justified because [[social structure]] is widespread. For example, most people in London only make contact with other Londoners. Further, within London then there are smaller subgroups, such as the Turkish community or teenagers (just to give two examples), who mix with each other more than people outside their group. However, homogeneous mixing is a standard assumption to make the mathematics tractable.
==Types of epidemic models== ===Stochastic=== "Stochastic" means being or having a random variable. A stochastic model is a tool for estimating probability distributions of potential outcomes by allowing for random variation in one or more inputs over time. Stochastic models depend on the chance variations in risk of exposure, disease and other illness dynamics. Statistical agent-level disease dissemination in small or large populations can be determined by stochastic methods.<ref>{{cite journal |last1=Tembine |first1=Hamidou |title=COVID-19: Data-Driven Mean-Field-Type Game Perspective |journal=Games |date=3 November 2020 |volume=11 |issue=4 |page=51 |doi=10.3390/g11040051 |doi-access=free |hdl=10419/257469 |hdl-access=free }}</ref><ref>{{cite journal |last1=Nakamura |first1=Gilberto M. |last2=Monteiro |first2=Ana Carolina P. |last3=Cardoso |first3=George C. |last4=Martinez |first4=Alexandre S. |title=Efficient method for comprehensive computation of agent-level epidemic dissemination in networks |journal=Scientific Reports |date=20 January 2017 |volume=7 |issue=1 |article-number=40885 |doi=10.1038/srep40885 |pmc=5247741 |pmid=28106086 |arxiv=1606.07825 |bibcode=2017NatSR...740885N }}</ref><ref>{{cite journal |last1=Nakamura |first1=Gilberto M. |last2=Cardoso |first2=George C. |last3=Martinez |first3=Alexandre S. |title=Improved susceptible–infectious–susceptible epidemic equations based on uncertainties and autocorrelation functions |journal=Royal Society Open Science |date=February 2020 |volume=7 |issue=2 |article-number=191504 |doi=10.1098/rsos.191504 |doi-access=free|pmc=7062106 |pmid=32257317 |bibcode=2020RSOS....791504N }}</ref>
===Deterministic=== When dealing with large populations, as in the case of tuberculosis, deterministic or compartmental mathematical models are often used. In a deterministic model, individuals in the population are assigned to different subgroups or compartments, each representing a specific stage of the epidemic.<ref>{{cite journal |last1=Dietz |first1=Klaus |title=Epidemics and Rumours: A Survey |journal=Journal of the Royal Statistical Society. Series A (General) |date=1967 |volume=130 |issue=4 |pages=505–528 |doi=10.2307/2982521 |jstor=2982521 }}</ref>
The transition rates from one class to another are mathematically expressed as derivatives, hence the model is formulated using differential equations. While building such models, it must be assumed that the population size in a compartment is differentiable with respect to time and that the epidemic process is deterministic. In other words, the changes in population of a compartment can be calculated using only the history that was used to develop the model.{{sfn|Brauer|Castillo-Chavez|2012|p={{pn|date=January 2025}}}}
===Kinetic and mean-field=== Formally, these models belong to the class of deterministic models; however, they incorporate heterogeneous social features into the dynamics, such as individuals' levels of sociality, opinion, wealth, geographic location, which profoundly influence disease propagation. These models are typically represented by partial differential equations, in contrast to classical models described as systems of ordinary differential equations. Following the derivation principles of kinetic theory, they provide a more rigorous description of epidemic dynamics by starting from agent-based interactions.<ref>{{cite book |doi=10.1007/978-3-030-96562-4_3 |chapter=Kinetic Modelling of Epidemic Dynamics: Social Contacts, Control with Uncertain Data, and Multiscale Spatial Dynamics |title=Predicting Pandemics in a Globally Connected World, Volume 1 |series=Modeling and Simulation in Science, Engineering and Technology |date=2022 |pages=43–108 |isbn=978-3-030-96561-7 | vauthors = Albi G, Bertaglia G, Boscheri W, Dimarco G, Pareschi L, Toscani G, Zanella M |author5-link=Lorenzo Pareschi}}</ref>
==Sub-exponential growth==
A common explanation for the growth of epidemics holds that 1 person infects 2, those 2 infect 4 and so on and so on with the number of infected doubling every generation. It is analogous to a game of [[Tag (game)|tag]] where 1 person tags 2, those 2 tag 4 others who've never been tagged and so on. As this game progresses it becomes increasing frenetic as the tagged run past the previously tagged to hunt down those who have never been tagged. Thus this model of an epidemic leads to a curve that [[exponential growth|grows exponentially]] until it crashes to zero as all the population have been infected. i.e. no [[herd immunity]] and no peak and gradual decline as seen in reality.<ref>{{cite journal | pmid=32269067 | year=2020 | last1=Maier | first1=B. F. | last2=Brockmann | first2=D. | title=Effective containment explains subexponential growth in recent confirmed COVID-19 cases in China | journal=Science | volume=368 | issue=6492 | pages=742–746 | doi=10.1126/science.abb4557 | pmc=7164388 | bibcode=2020Sci...368..742M }}</ref>
== Epidemic Models on Networks == Epidemics can be modeled as diseases spreading over [[Complex network|networks]] of contact between people. Such a network can be represented mathematically with a [[Graph theory|graph]] and is called the contact network.{{sfn|Barabási|2016|p={{pn|date=January 2025}}}} Every node in a contact network is a representation of an individual and each link (edge) between a pair of nodes represents the contact between them. Links in the contact networks may be used to transmit the disease between the individuals and each disease has its own [[Mathematical modelling of infectious disease|dynamics]] on top of its contact network. The combination of disease dynamics under the influence of interventions, if any, on a contact network may be modeled with another network, known as a transmission network. In a transmission network, all the links are responsible for transmitting the disease. If such a network is a locally tree-like network, meaning that any local neighborhood in such a network takes the form of a [[Tree (graph theory)|tree]], then the basic reproduction can be written in terms of the [[Degree distribution|average excess degree]] of the transmission network such that:
<math display="block">R_0 = \frac{{\langle k^2 \rangle}}{{\langle k \rangle}} - 1,</math>
where <math> {\langle k \rangle} </math> is the mean-degree (average degree) of the network and <math> {\langle k^2 \rangle} </math> is the second [[Moment (mathematics)|moment]] of the transmission network [[degree distribution]]. It is, however, not always straightforward to find the transmission network out of the contact network and the disease dynamics.<ref>{{Cite journal |last1=Kenah |first1=Eben |last2=Robins |first2=James M. |date=September 2007 |title=Second look at the spread of epidemics on networks |journal=Physical Review E|volume=76 |issue=3 Pt 2 |article-number=036113 |doi=10.1103/PhysRevE.76.036113 |pmc=2215389 |pmid=17930312 |arxiv=q-bio/0610057 |bibcode=2007PhRvE..76c6113K }}</ref> For example, if a contact network can be approximated with an [[Erdős–Rényi model|Erdős–Rényi graph]] with a [[Poisson distribution|Poissonian degree distribution]], and the disease spreading parameters are as defined in the example above, such that <math>\beta</math> is the transmission rate per person and the disease has a mean infectious period of <math>\dfrac{1}{\gamma}</math>, then the basic reproduction number is <math>R_0 = \dfrac{\beta}{\gamma}{\langle k \rangle}</math><ref>{{Cite journal |last1=Pastor-Satorras |first1=Romualdo |last2=Castellano |first2=Claudio |last3=Van Mieghem |first3=Piet |last4=Vespignani |first4=Alessandro |date=2015-08-31 |title=Epidemic processes in complex networks |journal=Reviews of Modern Physics |volume=87 |issue=3 |pages=925–979 |doi=10.1103/RevModPhys.87.925 |arxiv=1408.2701 |bibcode=2015RvMP...87..925P |doi-access=free }}</ref><ref>{{cite journal |last1=Rizi |first1=Abbas K. |last2=Faqeeh |first2=Ali |last3=Badie-Modiri |first3=Arash |last4=Kivelä |first4=Mikko |title=Epidemic spreading and digital contact tracing: Effects of heterogeneous mixing and quarantine failures |journal=Physical Review E |date=20 April 2022 |volume=105 |issue=4 |article-number=044313 |doi=10.1103/PhysRevE.105.044313 |pmid=35590624 |arxiv=2103.12634 |bibcode=2022PhRvE.105d4313R |doi-access=free }}</ref> since <math> {\langle k^2 \rangle} -{\langle k \rangle}^2 = {\langle k \rangle} </math> for a Poisson distribution.
== Reproduction number == {{main|Basic reproduction number}}The ''basic reproduction number'' (denoted by ''R''<sub>0</sub>) is a measure of how transferable a disease is. It is the average number of people that a single infectious person will infect over the course of their infection. This quantity determines whether the infection will increase [[sub-exponential]]ly, die out, or remain constant: if ''R''<sub>0</sub> > 1, then each person on average infects more than one other person so the disease will spread; if ''R''<sub>0</sub> < 1, then each person infects fewer than one person on average so the disease will die out; and if ''R''<sub>0</sub> = 1, then each person will infect on average exactly one other person, so the disease will become ''endemic:'' it will move throughout the population but not increase or decrease.<ref>{{cite book |doi=10.1016/B978-012107258-2/50005-6 |chapter=Global Burden of Disease |title=The Vaccine Book |date=2003 |pages=37–50 |isbn=978-0-12-107258-2 | vauthors = Miller E }}</ref>
==Endemic steady state== An infectious disease is said to be [[endemic (epidemiology)|endemic]] when it can be sustained in a population without the need for external inputs. This means that, on average, each infected person is infecting ''exactly'' one other person (any more and the number of people infected will [[exponential growth|grow sub-exponentially]] and there will be an [[epidemic]], any less and the disease will die out). In mathematical terms, that is:
: <math> \ R_0 S \ = 1. </math>
The [[basic reproduction number]] (''R''<sub>0</sub>) of the disease, assuming everyone is susceptible, multiplied by the proportion of the population that is actually susceptible (''S'') must be one (since those who are not susceptible do not feature in our calculations as they cannot contract the disease). Notice that this relation means that for a disease to be in the [[endemic (epidemiology)|endemic]] [[steady state]], the higher the basic reproduction number, the lower the proportion of the population susceptible must be, and vice versa. This expression has limitations concerning the susceptibility proportion, e.g. the ''R''<sub>0</sub> equals 0.5 implicates S has to be 2, however this proportion exceeds the population size.{{cn|date=March 2022}}
Assume the rectangular stationary age distribution and let also the ages of infection have the same distribution for each birth year. Let the average age of infection be ''A'', for instance when individuals younger than ''A'' are susceptible and those older than ''A'' are immune (or infectious). Then it can be shown by an easy argument that the proportion of the population that is susceptible is given by:
: <math> S = \frac{A}{L}. </math>
We reiterate that ''L'' is the age at which in this model every individual is assumed to die. But the mathematical definition of the endemic steady state can be rearranged to give:
: <math> S = \frac {1} {R_0}. </math>
Therefore, due to the [[transitive property]]:
: <math> \frac {1} {R_0} = \frac {A} {L} \Rightarrow R_0 = \frac {L} {A}. </math>
This provides a simple way to estimate the parameter ''R''<sub>0</sub> using easily available data.
For a population with an [[population pyramid|exponential age distribution]],
: <math> R_0 = 1 + \frac {L} {A}. </math>
This allows for the basic reproduction number of a disease given ''A'' and ''L'' in either type of population distribution.
== Compartmental models in epidemiology == {{Main|Compartmental models in epidemiology}} Compartmental models are formulated as [[Markov chains]].<ref name="Shalizi ">{{cite web |url= http://www.stat.cmu.edu/~cshalizi/dst/18/lectures/21/lecture-21.pdf|title= Data over Space and Time; Lecture 21: Compartment Models|author=Cosma Shalizi |website= Carnegie Mellon University | date = 15 November 2018 |access-date = September 19, 2020}}</ref> A classic compartmental model in epidemiology is the SIR model, which may be used as a simple model for modelling epidemics. Multiple other types of compartmental models are also employed.
=== The SIR model === [[File:SIR-Modell.svg|thumb|right|250px|Diagram of the SIR model with initial values <math display="inline">S(0)=997, I(0)=3, R(0)=0</math>, and rates for infection <math display="inline">\beta=0.4</math> and for recovery <math display="inline">\gamma=0.04</math>]] [[File:SIR model anim.gif|thumb|right|250px|Animation of the SIR model with initial values <math display="inline">S(0)=997, I(0)=3, R(0)=0</math>, and rate of recovery <math display="inline">\gamma=0.04</math>. The animation shows the effect of reducing the rate of infection from <math display="inline">\beta=0.5</math> to <math display="inline">\beta=0.12</math>. If there is no medicine or vaccination available, it is only possible to reduce the infection rate (often referred to as "[[flattening the curve]]") by appropriate measures such as social distancing.]] In 1927, W. O. Kermack and A. G. McKendrick created a model in which they considered a fixed population with only three compartments: susceptible, <math>S(t)</math>; infected, <math>I(t)</math>; and recovered, <math>R(t)</math>. The compartments used for this model consist of three classes:<ref name="pmid2059741">{{cite journal | vauthors = Kermack WO, McKendrick AG | title = Contributions to the mathematical theory of epidemics--I. 1927 | journal = Bulletin of Mathematical Biology | volume = 53 | issue = 1–2 | pages = 33–55 | date = 1991 | pmid = 2059741 | doi = 10.1007/BF02464423 |bibcode=1927RSPSA.115..700K |jstor=94815 |doi-access=free }}</ref> * <math>S(t)</math> , or those susceptible to the disease of the population. * <math>I(t)</math> denotes the individuals of the population who have been infected with the disease and are capable of spreading the disease to those in the susceptible category. * <math>R(t)</math> is the compartment used for the individuals of the population who have been infected and then removed from the disease, either due to immunization or due to death. Those in this category are not able to be infected again or to transmit the infection to others.
=== Other compartmental models === There are many modifications of the SIR model, including those that include births and deaths, where upon recovery there is no immunity (SIS model), where immunity lasts only for a short period of time (SIRS), where there is a latent period of the disease where the person is not infectious ([[Compartmental models in epidemiology|SEIS and SEIR]]), and where infants can be born with immunity (MSIR).{{cn|date=January 2024}}
==Infectious disease dynamics==
Mathematical models need to integrate the increasing volume of [[Numerical data|data]] being generated on [[Host (biology)|host]]-[[pathogen]] interactions. Many theoretical studies of the [[population dynamics]], structure and evolution of [[infectious disease]]s of [[plants]] and animals, including humans, are concerned with this problem.<ref>{{cite journal | doi=10.1016/j.idm.2017.02.001 | title=Mathematical epidemiology: Past, present, and future | year=2017 | last1=Brauer | first1=Fred | journal=Infectious Disease Modelling | volume=2 | issue=2 | pages=113–127 | pmid=29928732 | pmc=6001967 }}</ref>
Research topics include: * [[antigenic shift]] * [[epidemiological]] networks * [[evolution]] and spread of [[drug resistance|resistance]] * [[immune system|immuno]]-epidemiology * intra-host dynamics * [[Pandemic]] * pathogen [[population genetics]] * persistence of pathogens within hosts * [[phylodynamics]] * role and identification of [[infection reservoir]]s * role of host genetic factors * [[spatial epidemiology]] * statistical and mathematical tools and innovations * [[Strain (biology)]] structure and interactions * [[transmission (medicine)|transmission]], spread and control of infection * [[virulence]]
==Mathematics of mass vaccination== If the proportion of the population that is immune exceeds the [[herd immunity]] level for the disease, then the disease can no longer persist in the population and its transmission dies out.<ref>{{cite journal | doi=10.1126/science.abc6810 | title=A mathematical model reveals the influence of population heterogeneity on herd immunity to SARS-CoV-2 | year=2020 | last1=Britton | first1=Tom | last2=Ball | first2=Frank | last3=Trapman | first3=Pieter | journal=Science | volume=369 | issue=6505 | pages=846–849 | pmid=32576668 | pmc=7331793 | bibcode=2020Sci...369..846B }}</ref> Thus, a disease can be eliminated from a population if enough individuals are immune due to either vaccination or recovery from prior exposure to disease. For example, [[smallpox eradication]], with the last wild case in 1977, and certification of the eradication of indigenous transmission of 2 of the 3 types of wild [[poliovirus]] (type 2 in 2015, after the last reported case in 1999, and type 3 in 2019, after the last reported case in 2012).<ref>{{cite journal | doi=10.1038/s41577-020-00479-7 | title=A guide to vaccinology: From basic principles to new developments | year=2021 | last1=Pollard | first1=Andrew J. | last2=Bijker | first2=Else M. | journal=Nature Reviews Immunology | volume=21 | issue=2 | pages=83–100 | pmid=33353987 | pmc=7754704 }}</ref>
The herd immunity level will be denoted ''q''. Recall that, for a stable state:{{cn|date=January 2024}}
:<math>R_0 \cdot S = 1.</math>
In turn,
:<math>R_0=\frac{N}{S} = \frac{\mu N \operatorname E(T_L)}{\mu N \operatorname E[\min(T_L,T_S)]} = \frac{\operatorname E(T_L)}{\operatorname E[\min(T_L, T_S)]},</math>
which is approximately:{{cn|date=January 2024}}
:<math>\frac{\operatorname \operatorname E(T_L)}{\operatorname \operatorname E(T_S)} = 1+\frac{\lambda}{\mu} = \frac{\beta N }{v}.</math>
{{herd_immunity_threshold_vs_r0.svg}}
''S'' will be (1 − ''q''), since ''q'' is the proportion of the population that is immune and ''q'' + ''S'' must equal one (since in this simplified model, everyone is either susceptible or immune). Then:
:<math> \begin{align} & R_0 \cdot (1-q) = 1, \\[6pt] & 1-q = \frac {1} {R_0}, \\[6pt] & q = 1 - \frac {1} {R_0}. \end{align} </math>
Remember that this is the threshold level. Die out of transmission will only occur if the proportion of immune individuals ''exceeds'' this level due to a mass vaccination programme.
We have just calculated the '''critical immunization threshold''' (denoted ''q<sub>c</sub>''). It is the minimum proportion of the population that must be immunized at birth (or close to birth) in order for the infection to die out in the population.
: <math> q_c = 1 - \frac {1} {R_0}. </math>
Because the fraction of the final size of the population ''p'' that is never infected can be defined as:
:<math> \lim_{t\to\infty} S(t) = e^{-\int_0^\infty \lambda(t) \, dt} = 1-p.</math>
Hence,
:<math> p = 1- e^{-\int_0^\infty \beta I(t) \, dt} = 1-e^{-R_0 p}.</math>
Solving for <math>R_0</math>, we obtain:
:<math> R_0 = \frac{-\ln(1-p)}{p}.</math>
===When mass vaccination cannot exceed the herd immunity=== If the vaccine used is insufficiently effective or the required coverage cannot be reached, the program may fail to exceed ''q<sub>c</sub>''. Such a program will protect vaccinated individuals from disease, but may change the dynamics of transmission.{{cn|date=July 2023}}
Suppose that a proportion of the population ''q'' (where ''q'' < ''q<sub>c</sub>'') is immunised at birth against an infection with ''R''<sub>0</sub> > 1. The [[vaccination]] programme changes ''R''<sub>0</sub> to ''R<sub>q</sub>'' where
: <math>R_q = R_0(1-q)</math>
This change occurs simply because there are now fewer susceptibles in the population who can be infected. ''R<sub>q</sub>'' is simply ''R''<sub>0</sub> minus those that would normally be infected but that cannot be now since they are immune.
As a consequence of this lower [[basic reproduction number]], the average age of infection ''A'' will also change to some new value ''A<sub>q</sub>'' in those who have been left unvaccinated.
Recall the relation that linked ''R''<sub>0</sub>, ''A'' and ''L''. Assuming that life expectancy has not changed, now:{{cn|date=January 2024}}
: <math>R_q = \frac{L}{A_q},</math> : <math>A_q = \frac{L}{R_q} = \frac{L}{R_0(1-q)}.</math>
But ''R''<sub>0</sub> = ''L''/''A'' so:
: <math>A_q = \frac{L}{(L/A)(1-q)} = \frac{AL}{L(1-q)} = \frac {A} {1-q}.</math>
Thus, the vaccination program may raise the average age of infection, and unvaccinated individuals will experience a reduced [[force of infection]] due to the presence of the vaccinated group. For a disease that leads to greater clinical severity in older populations, the unvaccinated proportion of the population may experience the disease relatively later in life than would occur in the absence of vaccine.
===When mass vaccination exceeds the herd immunity=== If a vaccination program causes the proportion of immune individuals in a population to exceed the critical threshold for a significant length of time, transmission of the infectious disease in that population will stop. If elimination occurs everywhere at the same time, then this can lead to [[Disease eradication|eradication]].{{cn|date=July 2023}}
; Elimination : Interruption of endemic transmission of an infectious disease, which occurs if each infected individual infects less than one other, is achieved by maintaining vaccination coverage to keep the proportion of immune individuals above the critical immunization threshold.{{cn|date=July 2023}} ; Eradication : Elimination everywhere at the same time such that the infectious agent dies out (for example, [[smallpox]] and [[rinderpest]]).{{cn|date=July 2023}}
== Reliability ==
Models have the advantage of examining multiple outcomes simultaneously, rather than making a single forecast. Models have shown broad degrees of reliability in past pandemics, such as [[SARS]], [[SARS-CoV-2]],<ref name="Renz2020b">{{cite journal |last1=Renz |first1=Alina |last2=Widerspick |first2=Lina |last3=Dräger |first3=Andreas |title=FBA reveals guanylate kinase as a potential target for antiviral therapies against SARS-CoV-2 |journal=Bioinformatics |date=30 December 2020 |volume=36 |issue=Supplement_2 |pages=i813–i821 |doi=10.1093/bioinformatics/btaa813 |pmid=33381848 |pmc=7773487 }}</ref> [[Swine flu]], [[MERS]] and [[Ebola]].<ref>{{cite journal | vauthors = Costris-Vas C, Schwartz EJ, ((Smith? RJ)) | title = Predicting COVID-19 using past pandemics as a guide: how reliable were mathematical models then, and how reliable will they be now? | journal = Mathematical Biosciences and Engineering | volume = 17 | issue = 6 | pages = 7502–7518 | date = November 2020 | doi = 10.3934/mbe.2020383 | doi-broken-date = 12 July 2025 | pmid = 33378907 | doi-access = free |url=https://www.aimspress.com/article/10.3934/mbe.2020383 }}</ref>
== See also == {{col div|colwidth=40em}} * [[Basic reproduction number]] * [[Compartmental models in epidemiology]] * [[Contact tracing]] * [[Critical community size]] * [[Disease surveillance]] * [[Ecosystem model]] * [[Force of infection]] * [[Landscape epidemiology]] * [[Next-generation matrix]] * [[Pandemic]] * [[Risk factor]] * [[Sexual network]] * [[WAIFW matrix]] {{colend}}
== References == {{Reflist}}
==Sources== * {{cite book |last1=Barabási |first1=Albert-László |title=Network Science |date=2016 |publisher=Cambridge University Press |isbn=978-1-107-07626-6 }} * {{cite book |last1=Brauer |first1=Fred |last2=Castillo-Chavez |first2=Carlos |date=2012 |title=Mathematical Models in Population Biology and Epidemiology |series=Texts in Applied Mathematics |volume=40 |isbn=978-1-4614-1685-2 |doi=10.1007/978-1-4614-1686-9 }} * {{cite book |last1=Daley |first1=Daryl J. |last2=Gani |first2=Joseph Mark |title=Epidemic Modelling: An Introduction |date=1999 |publisher=Cambridge University Press |isbn=978-0-521-01467-0 }} * {{cite book |last1=Hamer |first1=William Heaton |title=Epidemiology, Old and New |date=1929 |publisher=Macmillan |oclc=609575950 |hdl=2027/mdp.39015006657475 |hdl-access=free }} * {{cite book |last1=Ross |first1=Ronald |title=The Prevention of Malaria |date=1910 |publisher=Dutton |oclc=610268760 |hdl=2027/uc2.ark:/13960/t02z1ds0q |hdl-access=free }}
== Further reading == {{Refbegin}} * {{cite book |title=Modeling Infectious Diseases: In Humans and Animals |first1=Matt |last1=Keeling |first2=Pej |last2=Rohani |publisher=Princeton University Press |location=Princeton }} * {{cite book |url=https://chrisvoncsefalvay.github.io/computational-infectious-disease/ |title=Computational Modeling of Infectious Disease |first1=Chris |last1=von Csefalvay |access-date=2023-02-27 |publisher=Elsevier/Academic Press |location=Cambridge, MA }} * {{cite book |url=http://anintroductiontoinfectiousdiseasemodelling.com/ |title=An Introduction to Infectious Disease Modelling |first1=Emilia |last1=Vynnycky |first2=Richard G. |last2=White |access-date=2016-02-15 |archive-date=2016-02-22 |archive-url=https://web.archive.org/web/20160222150833/http://anintroductiontoinfectiousdiseasemodelling.com/ |url-status=dead }} An introductory book on infectious disease modelling and its applications. * {{cite journal | vauthors = Grassly NC, Fraser C | title = Mathematical models of infectious disease transmission | journal = Nature Reviews. Microbiology | volume = 6 | issue = 6 | pages = 477–87 | date = June 2008 | pmid = 18533288 | pmc = 7097581 | doi = 10.1038/nrmicro1845 }} * {{cite journal | vauthors = Boily MC, Mâsse B | title = Mathematical models of disease transmission: a precious tool for the study of sexually transmitted diseases | journal = Canadian Journal of Public Health | volume = 88 | issue = 4 | pages = 255–65 | date = Jul–Aug 1997 | pmid = 9336095 | pmc = 6990198 | doi = 10.1007/BF03404793 }} * {{cite book |doi=10.1007/978-3-540-70514-7 |title=Mathematical Structures of Epidemic Systems |series=Lecture Notes in Biomathematics |date=1993 |volume=97 |isbn=978-3-540-56526-0 }} {{Refend}}
==External links== ;Software * [https://model-builder.sourceforge.net/ Model-Builder]: Interactive (GUI-based) software to build, simulate, and analyze ODE models. * [http://www.gleamviz.org/ GLEaMviz Simulator]: Enables simulation of emerging infectious diseases spreading across the world. * [http://www.eclipse.org/stem/ STEM]: Open source framework for Epidemiological Modeling available through the Eclipse Foundation. * [[R (programming language)|R]] package [https://CRAN.R-project.org/package=surveillance surveillance]: Temporal and Spatio-Temporal Modeling and Monitoring of Epidemic Phenomena
{{Concepts in infectious disease}} {{Vaccines}} {{Computer modeling}}
[[Category:Epidemiology]] [[Category:Mathematical and theoretical biology]] [[Category:Vaccination]] [[Category:Medical statistics]]