AWA: Academic Writing at Auckland
An Essay requires independent thinking and the development of an argument supported by clear and logical ideas (Nesi and Gardner, 2012, p. 91). The essay can be developed in different ways, including analysis, evaluation and synthesis of perspectives, theories and research, application of definitions, theories and frameworks to examples and vice versa, arguing against opposing views, explaining cause and effect, comparing and contrasting, classifying, and other ways of building and supporting a position. 3 types of essay are found in AWA: Analysis Essay, Argument Essay and Discussion Essay.
Title: 1080: evidence surrounding New Zealand's most contentious poison
|
Copyright: Pepijn Luiten
|
Description: Use the scientific literature to evaluate the recent scientific evidence supporting and opposing the use of 1080 for conservation management. Use the PCE 2011 as a starting point.
Warning: This paper cannot be copied and used in your own assignment; this is plagiarism. Copied sections will be identified by Turnitin and penalties will apply. Please refer to the University's Academic Integrity resource and policies on Academic Integrity and Copyright.
1080: evidence surrounding New Zealand's most contentious poison
Sodium fluoroacetate: considering the evidence surrounding New Zealand’s most contentious Poison Abstract In the last 800 years, the introduction of mammals into New Zealand has played a critical role in the destruction of native biodiversity, shaping the ecosystems we see today (Craig et al. 2016; Russell et al. 2015). Loss of biodiversity is accompanied by impacts to primary production and human health in the wake of mammalian pests, invasive species costing around NZ$3.3 billion annually from control and losses (Byrom et al. 2016). Native flora and fauna show few adaptations to deal with this threat, compounded by the explosive nature of alien mammals and their capacity to spread disease (Byrom et al. 2016; ERMA 2007). Aside from humans, the mammals that pose the most significant threat to native biodiversity include Possums (Trichosurus Vulpecula), ship rats (Rattus rattus) and stoats (Mustela erminea) (Wright 2011). The varied and intricate impacts of these species on native ecosystems and primary industry is beyond the scope of this report. However important points include they all detrimentally impact native species populations, ecosystem functions, human health and are widespread and difficult to control. Moreover, Possums are major vectors of Bovine Tuberculosis (TB), one of the greatest threats faced by the agriculture industry (Nugent et al. 2001; Byrom et al. 2016). The use of poison in pest control is the topic of long-standing debate (ERMA 2007). Despite a growing body of evidence concerning the effectiveness of aerially based operations for pest control and its relative safety, public opinion regarding poisons such as sodium fluoroacetate (henceforth referred to as 1080) have only gotten worse (Russell 2014). By investigating the evidence surrounding 1080, regarding both its use as a ‘tool’ to significantly control mammalian pests and the risks/adverse impacts of its use, we can gain a clear understanding of the practicality of 1080 and justification for further treatment.
Evidence of significant conservation gains through 1080 As New Zealand’s most applied pest control method, 1080 causes mortality by interfering with energy metabolism in animal. Application is administered through laced cereal bait pellets both in ground based and aerially based operations. The largest sectors involved in mammalian pest control are the Department of Conservation (DOC), OSPRI (under the TBfree programme, previously known as the Animal Health Board) and local governments. On average, 635,000ha of New Zealand’s 27M ha is aerially treated with 1080 every year, with a further 4-5M ha being applied in ground control programmes (Wright 2013). However, these figures vary annually, with a trend showing an increase in the use of aerially applied 1080 over larger areas in smaller quantities (Elliott & Kemp 2016).
Reports published in 2011 and 2013 by the Parliamentary Commissioner for the Environment (PCE) presented and compelling case for the continued use of 1080, heavily promoting the increased usage of the poison as New Zealand’s only viable option. These reports assessed both the effectiveness and concerns regarding 1080, constructing a framework of questions used to compare 1080 to an ‘optimum pest control tool’ (Wright 2011).
This framework is an effective way to assess the research concerning the pros and cons of 1080, providing evidence-based answers to fundamental questions regarding the its impacts, and whether it has significant conservation benefits. Since a large amount of literature was critically evaluated in the 2011/2013 PCE report, this report will use the PCE’s framework to evaluate the impacts of 1080, only using research conducted after the release of the 2011 report.
Can 1080 decrease populations of pests, do natives increase afterwards? A 2018 study using BACI sampling design and paired treatments sites over the course of four years, showed possums decreased to negligible levels in one-off 1080 treatment sites, whereas non-treatment sites had substantial increases. Rats and Stoats also showed significant reductions but rebounded in following years. This study also showed that the longer-term effects on nine bird species were all neutral or positive post-1080, showing negative effects on non-treatment sites (Burge et al. 2018).
Several other recent studies have demonstrated the susceptibility of pest mammals to 1080, with an increase in average kill rates for possums (75-100% in 2011 to 90-100% now), with less 1080/ha than previous studies (Byrom et al. 2016). Associated with greater pest control, evidence has demonstrated a significant, positive response in previously understudied species to 1080 treatments, such as common forest birds (i.e. Zosterops lateralis, Gerygone igata, Fringilla coelebs, etc.), and native bats (Mystacina tuberculata) (Schadewinkel et al. 2014; Veltman et al. 2014). Can 1080 stop Irrupting pest populations? The need for fast, effective pest control has become increasing apparently as we learn more about how introduced pests interact with native ecosystems, with special regards to ‘mast’ events. Rats are identified as particularly problematic, with populations returning to viable densities 16 months following a successful 1080 treatment (Griffiths et al. 2015). Recent studies have shown quick, tactical control is effective, especially when coupled with recently advanced field methodologies. These include pre-feeding non-toxic bait, modern survey technologies, multispecies approach, land-bridges, pre/post-detection methods such as chew-cards and tracking tunnels (Griffiths et al. 2015). Can 1080 be used on a large scale/cost effective? In 2014 DOC treated more than 600,000ha, with a following 900,00ha treated in 2016. Much of the treatment area being difficult, inaccessible terrain and the average cost per hectare for this operation reported at $17. Costs are often less in routine OSPRI treatments. The average cost for ground-based treatment can be as low $5/ha in lowland but often exceed $80/ha in rugged terrain, alongside ongoing monitoring costs (Burge et al. 2018).
Considered risks and adverse impacts of using 1080 Like all pest control methods, 1080 presents drawbacks. Whilst being the tightest regulated pest toxin in New Zealand, and deemed by the EPA ‘comparatively safe’, these adverse impacts continue to contribute to negative public opinions regarding 1080 (ERMA 2007; Farnworth et al. 2014). Ongoing research since its 2011 review have helped minimise these impacts as well as identify new potential risks. All pest control methods exhibit by-kill. 1080’s non-specific versatility has lead to concerns regarding the potential damage to native fauna. Since greater management regulations and advances in bait techniques since 2011, studies have either found no effect, or reduced effects of non-target mortality, with the small numbers of affected individuals offset by the subsequent increase in survivorship with removed pests (Katzenberger & Ross 2016; Schadewinkel et al. 2014). The PCE’s report justifiably raised the issue 1080’s humaneness in comparison to the ‘ideal tool’. However, 1080 causes considerably less stress/pain compared to the majority of the other fifteen poisons sanctioned for pest management in New Zealand (Wright 2011). ‘Competitive release’ release is one recently considered risk, post-1080 treatment. Demonstrated in several studies where population eradication has targeted single species objectives, ‘meso-predator release’ has shown to be a real threat to conservation goals (Ruscoe et al. 2011). Another indirect effect of pest control is prey switching. While becoming less threatening due to multi-species approaches, the consequences of prey switching are presented in various recent studies (Burge et al. 2018).
Gaps in knowledge and future research Increasing interest in the idea of a ‘Predator Free New Zealand’ demands greater research into continuous large-scale pest management. Several areas in this field exist where knowledge is lacking, or systems could be optimised (Nugent et al. 2001; Russell et al. 2015). Recent social surveys/studies have evaluated ongoing attitudes towards 1080 and overall pest management and have highlighted the need for more representative future studies. Social data is crucial in estimating public response to pest management, helping inform governments, policymakers, conservation estates, Iwi, economists and more (Farnworth et al. 2014; Russel 2014). Further Research is necessary regarding the indirect effects resulting from 1080. These effects include both positive and negative, with special interest in historically unexplored systems. Reviewing the literature shows an ecosystem and taxonomical bias, with majority of focus on Broad-leaf forests and Native, rare birds respectively (Byrom et al. 2016; Elliot & Kemp 206). From a design stand point, future studies would benefit from the coordination surrounding the undertaking of 1080 research (Craig et al. 2016). Standardisation of biodiversity indices and experimental design would allow the contribution of data to greater pest control meta-analyses and would present a better picture of native success (as opposed to immediate population response) (Byrom et al. 2016). Furthermore, studies accessing long-term effects on biodiversity would focus goals surrounding desired ecosystem outcomes.
Recommendation of 1080 in future conservation efforts Despite compelling evidence for 1080’s effectiveness and safety, its implementation by DOC and OSPRI continues to be a contentious issue (Russell 2014). Since the PCE’s report in 2011, further evidence has been accrued that 1080 and aerial treatments can result in substantial positive effects to a variety of non-pest species (Burge et al. 2018; Nugent et al. 2012). I strongly advocate for the continued use of 1080, and without these tools, New Zealand’s biodiversity would be under far greater threat. Continued efforts to find new pest control tools, bridge gaps in knowledge, inform the public and enhance treatment design are still necessary if New Zealand is to become pest-free by 2050.
References Burge B, Kelly D, MacFarlane AT, Van Vianen J 2018. The effects of single aerial 1080 possum-control operations on common forest birds in the South Island, New Zealand. New Zealand Journal of Ecology 42: 12–21. Byrom A, Choquenot D, Forsyth DM, Nugent G, Parkes JP, Pech RP, Warburton B 2016. Past, present and two potential futures for managing New Zealand’s mammalian pests. New Zealand Journal of Ecology 41: 151-161. Byrom A, Innes J, Binny R 2016. A review of biodiversity outcomes from possum-focused pest control in New Zealand. Wildlife Research 43: 228–253. Craig J, Anderson S, Clout M, Creese B, Mitchell N, Ogden J, Roberts M, Ussher G 2000. Conservation issues in New Zealand. Annual Review of Ecology and Systematics 31: 61–78. Craig E, Gardiner C, Graham PJ, Robertson HA 2016. Short pulse of 1080 improves the survival of brown kiwi chicks in an area subjected to long-term stoat trapping, New Zealand Journal of Zoology, 43: 351–362. Edmonds H, O’Donnell CFJ, Pryde M 2017. Survival of PIT-tagged lesser short-tailed bats (Mystacina tuberculata) through an aerial 1080 pest control operation. New Zealand Journal of Ecology 41: 186–192. Elliott G, Kemp J 2016. Large-scale pest control in New Zealand beech forests. Ecological Management & Restoration 17: 200–209. ERMA 2007. Animal Health Board (AHB) and Department of Conservation (DoC) - reassessment of sodium fluoroacetate (1080) and formulated substances containing 1080 (a vertebrate toxin) by a committee of the Environmental Risk Management Authority. HRE05002. Farnworth MJ, Watson H, Adams NJ 2014. Understanding attitudes toward the control of non-native wild and feral mammals: similarities and differences in the opinions of the general public, animal protectionists, and conservationists in New Zealand (Aotearoa). Journal of Applied Animal Welfare Science 17: 1–17. Gibbs GW 2009. The end of an 80-million year experiment: a review of evidence describing the impact of introduced rodents on New Zealand’s ‘mammal-free’ invertebrate fauna. Biological Invasions 11: 1587–1593. Gillies CA, Pierce RJ 1999. Secondary poisoning of mammalian predators during possum and rodent control operations at Trounson Kauri Park, Northland, New Zealand. New Zealand Journal of Ecology 23: 183–192. Griffiths R, Buchanan F, Broome K, Neilsen J, Brown D, Weakley M 2015. Successful eradication of invasive vertebrates on Rangitoto and Motutapu Islands, New Zealand. Biological Invasions 17: 1355–1369. Katzenberger JK, Ross JG 2016. Mohoua ochrocephala abundance in the Catlins following aerial 1080 control. New Zealand Natural Sciences 42: 1–8. Murphy EC, Robbins L, Young JB, Dowding JE 1999. Secondary poisoning of stoats after an aerial 1080 poison operation in Pureora Forest, New Zealand. New Zealand Journal of Ecology 23: 175–182. Nugent G, Fraser W, Sweetapple P 2001. Top down or bottom up? Comparing the impacts of introduced arboreal possums and ‘terrestrial’ ruminants on native forests in New Zealand. Biological Conservation 99: 65–79. Nugent G, Warburton B, Thomson C, Sweetapple P, Ruscoe WA 2011. Effect of prefeeding, sowing rate and sowing pattern on efficacy of aerial 1080 poisoning of small-mammal pests in New Zealand. Wildlife Research 38: 249–259. Ruscoe WA, Ramsey DSL, Pech RP, Sweetapple PJ, Yockney I, Barron MC, Perry M, Nugent G, Carran R, Warne R, Brausch C, Duncan RP 2011. Unexpected consequences of control: competitive vs. predator release in a four-species assemblage of invasive mammals. Ecology Letters 14: 1035–1042. Russell JC 2014. A comparison of attitudes towards introduced wildlife in New Zealand in 1994 and 2012. Journal of the Royal Society of New Zealand 44: 136–151. Russell JC, Innes JG, Brown PH, Byrom AE 2015. Predator-free New Zealand: conservation country. Bioscience 65: 520–525. Schadewinkel RB, Senior AM, Wilson DJ, Jamieson IG 2014. Effects on South Island robins (Petroica australis) from pest control using aerially applied 1080 poison. New Zealand Journal of Ecology 38: 315–321. Veltman CJ, Westbrooke IM, Powlesland RG, Greene TC 2014. A principles-based decision tree for future investigations of native New Zealand birds during aerial 1080 operations. New Zealand Journal of Ecology 38: 103–109. Westbrooke IM, Etheridge ND, Powlesland RG 2003. Comparing methods for assessing mortality impacts of an aerial 1080 pest control operation on tomtits (Petroica macrocephala toitoi) in Tongariro Forest. New Zealand Journal of Ecology 27: 115–123. Wright J 2011. Evaluating the use of 1080: predators, poisons and silent forests. Wellington, New Zealand, New Zealand Parliamentary Commissioner for the Environment. 85 p. |