1. Number of events averted by vaccination (NAE)
The number of events averted by vaccination at time \(t\) is calculated as:
\[NAE_t = e_{A(t)} \frac{VC_t VE_t}{(1 -
VC_t VE_t)}\]
with:
- \(e_{A(t)}\): Number of events at
time \(t\)
- \(VC_t\): Vaccine coverage at time
\(t\)
- \(VE_t\): Vaccine effectiveness at
time \(t\)
2. Number of avertable events considering an increase in final
coverage (NAbE)
The number of averted events with alpha parameter at time \(t\):
\[NAbE_t(\alpha) = e_{A(t)}
\frac{VC(\alpha)_t VE_t}{(1 - VC(\alpha)_t VE_t)}\]
with:
- \(e_{A(t)}\): Number of events at
time \(t\)
- \(VC(\alpha)_t\): Hypothetical
vaccine coverage during time \(t\) if
the vaccine coverage was increased by a factor of alpha parameter
- \(VE_t\): Vaccine effectiveness at
time \(t\)
\(VC(\alpha)_t\) is computed as:
\[VC_t(\alpha) = \sum_{i=1}^{t} (VC_t -
VC_{t-1}) \left(1 + \frac{\alpha}{VC_T}\right)\]
with:
- \(VC_t\): Vaccine coverage at time
\(t\) (\(VC_0
= 0\))
- \(VC_{t-1}\): Vaccine coverage at
time \(t-1\)
- \(\alpha\): Alpha parameter
- \(VC_T\): Maximum vaccine
coverage
3. Number Needed to Vaccinate (NNV)
The number needed to vaccinate at time \(t\) is calculated as:
\[NNV_t = \frac{1}{R_{B(t)}
VE_t}\]
where \[R_{B(t)} = \frac{e_{A(t)} +
NAE_t}{N_e}\]
with:
- \(VE_t\): Vaccine effectiveness at
time \(t\)
- \(e_{A(t)}\): Number of events at
time \(t\)
- \(NAE_t\): Number of events averted
by vaccination at time \(t\)
- \(N_t\): Population at risk at time
\(t\)