Surveillance sensitivity

During the confirmation phase, the probability of absence can be derived from estimates of the surveillance sensitivity (SSe), the probability of detecting the species within a region of interest, given it is present at some predetermined level (i.e., the ‘design prevalence’ – see below) (Martin et al., Reference Martin, Cameron and Greiner2007). The SSe is subtly different from the detection probability that is derived from models fitted to monitoring data (e.g., occupancy models), which only condition on presence in a sampling unit. The SSe for a region is usually constructed from the sensitivities of the various types of surveillance, which can be either structured or unstructured (Martin et al., Reference Martin, Cameron and Greiner2007). Given a series of zero detections, the SSe quantifies the effectiveness of the search effort (the probability of detection given the design prevalence), but it is not, per se, an appropriate indicator of eradication success. The probability of absence given no detections from surveillance can be derived from the SSe using Bayes’ theorem, which also requires consideration of the prior probability of absence (i.e., the probability of absence prior to the confirmation phase). Given an estimate of the SSe and the prior probability of absence (Prior), the probability of species absence (PoA) is given by

(1) $$ PoA\hskip0.35em =\hskip0.35em \frac{Specificity\times Prior}{Specificity\times Prior+\left(1- SSe\right)\left(1- Prior\right)}, $$

where Specificity is the probability of not detecting the species when the species is not present. Equation (1) is analogous to the negative predictive value of a diagnostic test used in disease surveillance (Martin et al., Reference Martin, Cameron and Greiner2007). If we can assume that the Specificity is equal to 1.0 (i.e., no false positive detections), then equation (1) simplifies to

(2) $$ PoA\hskip0.35em =\hskip0.35em \frac{Prior}{1- SSe\left(1- Prior\right)}. $$

The Prior can be obtained in a number of ways, including (i) expert opinion (Ramsey et al., Reference Ramsey, Parkes and Morrison2009), (ii) meta-analysis of eradication programmes from similar species (Dodd et al., Reference Dodd, Ainsworth, Burgman and McCarthy2015), or (iii) use of models to simulate lethal control (Gormley et al., Reference Gormley, Holland, Barron, Anderson and Nugent2016).

The PoA is the metric used to guide decisions, which incorporates the Prior and the SSe. The following hypothetical example illustrates the importance of the Prior and why we bother with Bayesian logic. Consider two identical islands on which toxic baits were used to remove rats (Samaniego-Herrera et al., Reference Samaniego-Herrera, Anderson, Parkes and Aguirre-Muñoz2013). The first island had complete bait coverage, whereas the second had large gaps in bait deployment. The higher operational investment on the first island results in a higher prior probability of success (before the confirmation phase) than on the second island. The subsequent surveillance during the confirmation phase was equal on both islands (i.e., equal SSe), and no rats were detected. Combining the Prior with the SSe demonstrates, intuitively and quantitatively, that confidence in eradication success is higher for the first island than for the second.

The value specified for the Prior has a large influence on the level of surveillance that needs to be conducted to confidently declare absence of the pest (Figure 1A). For example, if we have low confidence that control was sufficient to eradicate the pest (Prior = 0.5), then surveillance efforts need to be extremely high (SSe = 0.9) to achieve a high level of confidence in successful eradication (PoA > 90%). Conversely, if the Prior = 0.8, then surveillance efforts can be reduced (yielding an SSe = 0.6) to achieve the same level of confidence regarding absence of the pest (PoA > 90%).

Figure 1. (A) Contour plot showing the relationship between the starting probability of absence (Prior) (x-axis) and the resulting probability of absence (PoA) (y-axis) for three levels of surveillance sensitivities (SSe) (contour lines). (B) Contour plot showing the relationship between the Prior (x-axis), the PoA (contour lines) and the SSe (y-axis).

Quantitative planning increases the chances that a cost-effective surveillance strategy will be deployed (Gormley et al., Reference Gormley, Anderson and Nugent2018). We can rearrange equation (2) to determine the level of surveillance required ( $ {SSe}_{req} $ ) to improve our level of confidence in eradication from the Prior to the target PoA (PoA _Target):

(3) $$ {SSe}_{\mathrm{req}}\hskip0.35em =\hskip0.35em \frac{PoA_{\mathrm{Target}}- Prior}{PoA_{\mathrm{Target}}\;\left(1- Prior\right)}. $$

For example, if the Prior = 0.9 (i.e., we are 90% sure of eradication after control) and $ {PoA}_{\mathrm{Target}} $  = 0.95 (i.e., we want to be 95% sure of success), then $ {SSe}_{\mathrm{req}} $  = 0.53; this means that we need to do enough surveillance to have a 53% chance of detecting any remaining individuals at the design prevalence (Figure 1B). If, however, we wanted to be 99% sure of success, then for the same Prior, a much higher level of surveillance would be needed (i.e., $ {SSe}_{\mathrm{req}} $  = 0.91).

Spatial PoA model

Methods have been developed to estimate SSe by incorporating information on the spatial deployment of monitoring devices across the area of interest, and on attributes of the target species (Anderson et al., Reference Anderson, Ramsey, Nugent, Bosson, Livingstone, Martin, Sergeant, Gormley and Warburton2013; Kim et al., Reference Kim, Corson, Mulgan and Russell2020). The surveillance model is based on a simple spatial model for the detection of individuals based on a function of the distance between an individual and a detection device. Individuals are assumed to occupy a symmetric home range, and detection declines with increasing distance between the home range centre and the device location. This spatial detection process is governed by two parameters: $ {g}_0 $ – the probability of detection over a single time interval by a device placed at the home range centre (i.e., the maximum probability of detection); and $ \sigma $ – the rate of decay in the probability of detection with increasing distance between the home range centre and the device (Efford, Reference Efford2004). For simplicity, a half-normal function is usually used to model the decay in detection probability, with $ \sigma $ being equivalent to the standard deviation of the circular normal kernel. This parameter is proportional to the home range size of an individual. This simple model was first used to model detection in spatially explicit capture–recapture models (Efford, Reference Efford2004; Borchers and Efford, Reference Borchers and Efford2008). However, this spatial detection function has also proved to be useful in simulation models for designing efficient surveillance for achieving management objectives (Ramsey et al., Reference Ramsey, Efford, Ball and Nugent2005; Gormley and Warburton, Reference Gormley and Warburton2020; Anderson et al., Reference Anderson, Pepper, Travers, Michaels, Sullivan and Ramsey2022a).

The spatial surveillance approach is constructed by superimposing a spatially referenced grid-cell system on the area of interest (i.e., a raster layer). Each grid cell corresponds to a sampling unit, and the model quantifies the probability of detecting an individual in each grid cell, given a surviving individual’s home range centre is located in the grid cell. Detection devices or search effort in or around a grid cell have a chance of detecting an individual. Each device type has its own maximum detection probability ( $ {g}_0 $ ), with $ \sigma $ derived from home range estimates for the species. A spatially explicit detection surface is quantified by adding detection kernels for each device location. The height (or intensity) of the kernel is equivalent to the amount of sampling effort undertaken by that device (e.g., number of trap nights). The number of grid cells covered by all kernels determines the proportion of the total area covered by surveillance. Alternatively, grid cells can be searched directly with the probability of detection related to the amount of search effort in a cell. Methods based on search effort by observers are most often employed during surveillance for weeds (e.g., Garrard et al., Reference Garrard, Bekessy, McCarthy and Wintle2008; Hauser et al., Reference Hauser, Giljohann, McCarthy, Garrard, Robinson, Williams and Moore2022). The grid-cell approach allows the accommodation of diverse combinations of surveillance information, which might vary by detection method, location, sampling effort, and deployment period. The use of multiple detection methods, including those not requiring an interaction by the animal (such as a camera or eDNA), can improve the chances of detecting device-shy individuals.

The spatially explicit surveillance model also incorporates habitat selection by the target species because the likely location of a limited number of survivors is not expected to be equal across the landscape but concentrated in preferred areas. Resource selection studies (Manly et al., Reference Manly, McDonald, Thomas, McDonald and Erickson2002) and the results from species distribution models (Elith et al., Reference Elith, Graham, Anderson, Dudík, Ferrier, Guisan, Hijmans, Huettmann, Leathwick, Lehmann, Li, Lohmann, Loiselle, Manion, Moritz, Nakamura, Nakazawa, Overton, Peterson, Phillips, Richardson, Scachetti-Pereira, Schapire, Soberón, Williams, Wisz and Zimmermann2006) can inform the relative probabilities of survivors in different locations and assist in the creation of a relative-risk map (Anderson et al., Reference Anderson, Ramsey, Nugent, Bosson, Livingstone, Martin, Sergeant, Gormley and Warburton2013, Reference Anderson, Pepper, Travers, Michaels, Sullivan and Ramsey2022a). The resolution of the grid-cell system superimposed on the eradication area should be finer than the home range size and should also accommodate spatial heterogeneity of the relative-risk map. The estimated SSe will be maximised when search effort is spatially distributed proportionate to the relative risk of survivor presence (Martin et al., Reference Martin, Cameron and Greiner2007).

The SSe for the eradication area is calculated by combining the spatial surveillance surface (grid-cell-level probabilities of detection), the relative-risk map of habitat use, and a statistical parameter representing the minimum number of occupied grid cells $ ({P}_u $ ) that are available to be detected. The latter element is referred to as ‘design prevalence’ in disease surveillance (Cameron and Baldock, Reference Cameron and Baldock1998) and determines the definition of the SSe. For example, if the minimum number of occupied grid cells is set to 1, the SSe is defined as ‘the probability of detecting an individual given that only one grid cell is occupied in the area of interest’. Intuitively, it is easier to detect one of many occupied grid cells than a single occupied grid cell. When aiming to confirm eradication success, we are trying to find the last survivor, or one of a few remaining survivors. Therefore, the minimum number of occupied grid cells is generally set to 1 (however, see ‘Extensions to the PoA model’ below). If we obtain a high SSe assuming only one occupied cell, and do not detect anything, we can increase our confidence that less than one cell remains occupied, that is, zero are present.

Values for the spatially explicit detection parameters ( $ {g}_0 $ and $ \sigma $ ) of animals in monitoring devices can be obtained from published reports, experimental or field studies (Efford, Reference Efford2004; Ball et al., Reference Ball, Ramsey, Nugent, Warburton and Efford2005; Ramsey et al., Reference Ramsey, Caley and Robley2015; Anderson et al., Reference Anderson, Rouco, Latham and Warburton2022b) or expert opinion (Anderson et al., Reference Anderson, Pepper, Travers, Michaels, Sullivan and Ramsey2022a). Similarly, detection experiments have typically been used to estimate the probability of weed detection given a certain amount of search effort (Garrard et al., Reference Garrard, Bekessy, McCarthy and Wintle2008; Hauser et al., Reference Hauser, Giljohann, McCarthy, Garrard, Robinson, Williams and Moore2022). These parameters are input into the model as distributions in order to account for uncertainty. High variances should be used where there is high parameter uncertainty, which is propagated through to estimates of SSe (Anderson et al., Reference Anderson, Pepper, Travers, Michaels, Sullivan and Ramsey2022a). Given high parameter uncertainty, increasing sample size, through increased surveillance effort, will increase the mean and decrease the variance of the SSe.

Once an estimate of SSe and its uncertainty is obtained, the PoA (and associated variance) can be calculated, initially by updating the Prior (equation (2)). The resulting PoA then becomes the prior probability for the next round of surveillance data, and so forth. This updating of the PoA continues as new surveillance data are added (Anderson et al., Reference Anderson, Ramsey, Nugent, Bosson, Livingstone, Martin, Sergeant, Gormley and Warburton2013; Ramsey et al., Reference Ramsey, Campbell, Lavoie, Macdonald and Morrison2022), until the mean PoA exceeds a target threshold, which is set by stopping rules (see below).

Stopping rules

No matter how much surveillance is undertaken, managers can never be certain about eradication success, due to uncertainty in the detection process. Decisions on when to declare success must consider the risk of being wrong. As stated above, this risk can be encapsulated by the Type I and Type II error rates and the consequences of making a wrong decision. A stopping rule is a statement about the criteria for ceasing an eradication programme, which may or may not consider these error rates.

Intuitively, successful eradication can be declared when there is a high probability that the residual population is zero. This is equivalent to minimising the Type I error rate, the probability that eradication is wrongly declared. A logical stopping rule would involve a threshold for the PoA that, when exceeded, triggers declaration of eradication success. Typically, thresholds are set such that eradication success is declared once the PoA exceeds some value, such as 95% or 99% (e.g., Ramsey et al., Reference Ramsey, Parkes and Morrison2009, Reference Ramsey, Parkes, Will, Hanson and Campbell2011; Anderson et al., Reference Anderson, Gormley, Ramsey, Nugent, Martin, Bosson, Livingstone and Byrom2017). A stopping rule using a 95% threshold for the probability of absence is equivalent to saying that one out of 20 similar eradication attempts with equivalent effort would fail to detect survivors. The advantage of this type of stopping rule is its relative transparency; the level of certainty is clear to managers. The disadvantage of this type of stopping rule is that picking a threshold for the Type I error rate is arbitrary.

A second type of stopping rule considers both the Type I and Type II error rates, by examining the joint costs associated with these errors. These costs can be summarised as the cost of surveillance plus the expected cost that would be incurred if eradication were to be wrongly declared. The optimal time for declaring eradication successful is when the NEC is minimised (Regan et al., Reference Regan, McCarthy, Baxter, Dane Panetta and Possingham2006). A stopping rule based on minimising the NEC avoids the issue of setting a threshold for the PoA. While theoretically sound, implementing this stopping rule has practical difficulties. The main difficulty is that the expected cost of wrongly declaring successful eradication is not easily quantified. This is because these costs include both tangible costs (e.g., the cost of repeating the eradication attempt) and intangible costs (e.g., reputational costs or biodiversity loss associated with the failure to eradicate). In many eradication attempts, the intangible costs are deemed to be high, but they are difficult or even impossible to quantify (e.g., costs due to biodiversity loss). Many managers are primarily concerned with the intangible costs and thus try to minimise the Type I error. Recently, attempts have been made to address this through a utility function that considers both the cost variance and the expected costs, incorporating a parameter indicating the degree of ‘risk aversion’. This is then used to optimise the most cost-effective threshold for the PoA (Gormley et al., Reference Gormley, Anderson and Nugent2018).

Extensions to the PoA model

Extensions to the spatial PoA model have been developed, principally to allow the model to be applied to large eradication programmes (Anderson et al., Reference Anderson, Gormley, Ramsey, Nugent, Martin, Bosson, Livingstone and Byrom2017). Large (or broadscale) eradication programmes are defined as ones in which management of the species cannot occur concurrently over the entire area of interest. The eradications of Bovine Tb (Mycobacterium bovis) from wildlife in New Zealand (Livingstone et al., Reference Livingstone, Hancox, Nugent, Mackereth and Hutchings2015), fire ants (Solenopsis invicta) from south-east Queensland, Australia (Spring and Cacho, Reference Spring and Cacho2015) and nutria (Myocastor coypus) from the Delmarva Peninsula, USA (Anderson et al., Reference Anderson, Pepper, Travers, Michaels, Sullivan and Ramsey2022a) are all attempting eradications over 0.5–2.0 M ha. By necessity, these large areas are often subdivided into smaller management zones, in each of which, eradication actions operate as a single unit and are large enough to minimise the risk of reinvasion from neighbouring zones. Eradication then proceeds in two stages. Stage I involves the removal of the species, followed by confirmation phase surveillance to declare absence within each zone. Once a management zone is declared free of the species in Stage I, it then passes to Stage II and the operational resources are reallocated to the next zone. In this way, eradication proceeds progressively over the entire extent until all zones are declared free of the species (Figure 2). Importantly, once a zone progresses to Stage II, surveillance in that zone should continue, so that any residual survivors or incursions are detected. Since the majority of resources are committed to zones undergoing Stage I, Stage II surveillance data sources will usually be low-cost/low-intensity sources, such as reports from the public or other passive surveillance sources.

Figure 2. The spatiotemporal progression of a hypothetical broadscale eradication operation over a square-shaped region, which begins in the north-west of the region in 2022 and finishes in the south-east in 2035 (modified from Anderson et al., Reference Anderson, Gormley, Ramsey, Nugent, Martin, Bosson, Livingstone and Byrom2017). Each square represents a management zone for control purposes, and the number in each represents the year in which control is to be undertaken in the zone. Surveillance devices or search efforts are allocated to the surveillance unit (smallest squares, top of figure). Stage I is the period in which control is being undertaken, and ‘freedom’ is the criterion required for an operational decision at the management-zone level to allow reallocation of resources to other management zones, that is, progression of the operation across the landscape. Stage II entails ongoing surveillance in management zones declared ‘free’ at the end of Stage I. The purpose of Stage II is to identify erroneous freedom declarations, and to eventually declare the species eradicated from the entire broadscale area. Confirmation of eradication in Stage II may extend well beyond 2035.

An important point is that all zones being declared free of the species at Stage I does not necessarily equate to a high level of confidence in eradication over the entire extent. Consider 10 management zones declared free using a 95% threshold for the PoA. Hence, each zone has a Type I error rate of 5% of being incorrectly declared free, and therefore the probability that at least one of the 10 zones has been incorrectly declared free is $ 1-{\left(1-0.05\right)}^{10} $  = 0.4, giving a PoA over the entire extent of 0.6. To achieve high confidence in eradication over the entire extent, Stage II surveillance must be used. Since the management zones have been undergoing Stage II surveillance for various periods of time (i.e., since declaration of absence of the species at the end of Stage I), calculation of the SSe for each zone needs to incorporate this variable time under surveillance. This is achieved by assuming that the residual population (if present) should increase within the zone with the passage of time. Under positive population growth, detection of a species should become more likely over time due to population increase and spread. This is reflected in the calculations of the SSe for each management zone by allowing the minimum number of occupied cells ( $ {P}_u $ ) to increase over the period of Stage II surveillance. This can be achieved, for example, by assuming that $ {P}_u $ increases according to the logistic growth function

(4) $$ {P}_{u(t)}\hskip0.35em =\hskip0.35em {P}_{u\left(t-1\right)}+r\;{P}_{u\left(t-1\right)}\;\left[1-{P}_{u\left(t-1\right)}/K\right], $$

where $ r $ equals the intrinsic growth rate and $ K $ is the carrying capacity. Assuming $ K $ is large relative to population size (as is expected in a population of residual survivors), equation (4) can be approximated by

(5) $$ {P}_{u(t)}\hskip0.35em =\hskip0.35em {P}_{u\left(t-1\right)}\;\left(1+r\right). $$

Allowing $ {P}_u $ to increase due to equation (5) means that, even if the SSe is initially low, it will increase over time because undetected survivors would be expected to increase, making them easier to detect (Caley et al., Reference Caley, Ramsey and Barry2015; Anderson et al., Reference Anderson, Gormley, Ramsey, Nugent, Martin, Bosson, Livingstone and Byrom2017).

Approximations to the spatial PoA model

The spatial PoA model outlined above represents a flexible and powerful tool for quantifying eradication success. However, there are several limitations. Calculations of the uncertainty in the estimates of the SSe and the PoA are derived from Monte Carlo simulations based on the underlying probability distributions of the component parts (e.g., $ {g}_0 $ , $ \sigma $ , and Prior). Usually, many draws are required to reduce Monte Carlo errors, so processing models utilising data from large extents over many years is computationally expensive. Recently, analytical Bayesian solutions to the PoA model have been developed (Barnes et al., Reference Barnes, Giannini, Parsa and Ramsey2021, Reference Barnes, Parsa, Giannini and Ramsey2022). The analytical solutions are based on probability-generating functions, which fully define discrete distributions (Feller, Reference Feller1958). Using standard statistical theory, the stochastic processes in the PoA model can be expressed as compound distributions from which analytical solutions can be determined. These solutions can then provide a straightforward means of deriving posterior distributions and statistics (Barnes et al., Reference Barnes, Giannini, Parsa and Ramsey2021, Reference Barnes, Parsa, Giannini and Ramsey2022). One advantage of these analytical formulations is that they allow a more tractable analysis of surveillance design, making exploration of the cost of alternative strategies, the impacts of stochasticity and parameter uncertainty much more computationally efficient.