Category: rats

  • PredatorFreeNZ 2050: fantasy into reality

    High in the treetops of a lush forest, a group of native birds gathered together, their vibrant feathers glinting in the dappled sunlight. Excited chirps and melodic trills filled the air as they engaged in a lively conversation. Their voices carried the hopes and dreams of a restored ecosystem.

    Koru, a charismatic Tūī with iridescent feathers, fluttered his wings and cleared his throat. “Have you all heard the latest? The Humans are determined to make New Zealand predator-free by 2050!”

    The cheeky Kākāriki, a lively parakeet, interjected. “Can we truly reclaim our forests from the claws and jaws of those invaders?” A wise and observant Morepork owl, Ruru blinked his large, round eyes. “Is that so? Quite a lofty goal, but can they really do it?”

    Photo credit: CC BY-NC-ND 2.0 Simeon W Flickr
    Red-crowned Kakariki, Photo credit: CC BY-NC-ND 2.0 Simeon W, Flickr

    With its unique biodiversity, New Zealand is home to a huge array of species found nowhere else on Earth. However, many of these treasures face an existential threat from invasive predatory mammals, such as rats, stoats, and possums, introduced by human settlers centuries ago. These voracious predators ravage the native bird populations. Many species are now extinct, and more are now on the brink of extinction.

    Predator-Free New Zealand 2050 (PFNZ2050) was initiated in 2016 with an audacious aim of eradicating the most destructive trio of predators: possums, stoats, and rats; from New Zealand. This call for action echoed through the mountains and valleys, inspiring conservationists to make New Zealand, once again, a land of breathtaking beauty and thriving unique biodiversity. The ambitious aim of Predator Free 2050 is not without precedent. To date, New Zealand has successfully eradicated invasive mammals from 105 (admittedly much smaller) islands.

    In 2020, a journal article was published that assesses the feasibility and steps needed to achieve Predator Free 2050. it was written by James Ross, from the Centre for Wildlife Management and Conservation (CWMC) at Lincoln University, Grant Ryan from The Cacophony Project, Merel Jansen from the Department of Applied Biology, HAS University of Applied Sciences, Hertogenbosch, The Netherlands, and Tim Sjoberg, from the Taranaki Mounga Project. Together, these researchers have decades of experience controlling and monitoring pest mammals in New Zealand.

    The first step, removing predators with aerial 1080 poisoning and ground-based resetting traps, will help remove the majority of predators. A modified aerial 1080 approach, developed by Zero Invasive Predators (ZIP), can result in localised eradication. This was first tried in a 400-ha area at Mt. Taranaki in 2016, then at a 2,300-ha site in South Westland, using ground-based resetting traps. Regular servicing of resetting traps also gives better ground-based control results.

    Once pests have been eradicated from an area, the next big challenge is to defend the area from invasion. ZIP demonstrated how to defend predators from re-invasion in two sites using a “virtual barrier” of traps. A 2 km wide barrier of traps protected a 400-ha peninsula at Bottle Rock in the Marlborough Sounds. Using this virtual barrier of traps, ZIP prevented predators from re-invading at two sites, in the short term.

    Australian brushtail possums, initially introduced into New Zealand for the fur trade, and now one of the major pest mammals in New Zealand.
    Photo credit: CC BY-SA 2.0, Gnu Chris, Flickr

    Detecting the survivors is the next crucial phase for eradication, as any survivors can build a new population. The CWMC and Cacophony Project found that thermal cameras are 3.6 times more sensitive than trial cameras in detecting possums. Whilst trail cameras appear to improve detection rates, they do not always trigger when a small, fast-moving animal moves in front of them. These cameras also use infrared illumination at night, which may deter some animals.

    Thermal cameras are a new advanced technology that shows high sensitivity in detecting both small and large pest mammals. Because the motion detection is done using software, the sensitivity can easily be adjusted. Unlike trail cameras, thermal cameras do not require infrared illumination to operate at night.

    Videos collected by the thermal cameras are classified using AI technology (machine learning) trained on a library with more than 50,000 tagged videos. The AI can identify the animal species and only keep recordings for the target pests, which can be stored on-board the device or sent out using the cellular network.

    To achieve the PFNZ 2050 goal, detecting the last few individual pest mammals is complex and expensive. As a technical improvement in detection, ZIP has made an AI network of over 500 cameras across the Predator-free South Westland project area. The AI cameras use LoRa (low-powered radio technology) to send the information to solar-powered mini-satellites. The information is transferred to a web server that checks the information the next day. The AI cameras only need to be serviced twice a year to change the batteries. The AI cameras have reduced the time to detect one predator from around six weeks to just one day and have reduced the cost significantly.

    PFNZ2050 will require more innovative strategies, control tools, and wider public support to be successful in its ambitious challenge. Future control work will increasingly take place in and around urban areas. As such, the next most important advancement needs to be construct control tools that community groups can use. There should be a bottom-up-driven approach to community engagement in conservation so that as new technologies become available, the number and size of invasive mammal-free publicly and privately managed reserves can increase. In a recent study, people showed high support for species-specific toxins, but there is a shortage of funding for registration of these toxins.

    NZ has a 60-year history of eradicating pest mammals, from tiny 1-ha Maria Island to more than 11,000 ha Campbell Island, with suitable techniques and public support. This is an example of how the impossible becomes possible when passion, science, and community unite.

    With a final chorus of their harmonious calls, the native birds took flight, their wings carrying their hopes and aspirations to the corners of the land. From forests to cities, their songs echoed, touching the hearts of all who listened.


    This article was prepared by postgraduate student Mohamed Safeer as part of the ECOL 608 Research Methods in Ecology course for his Master of Pest Management degree.

  • Testing new bait coatings for conservation

    Mickey Mouse and Scabbers the Rat, are causing biodiversity loss in Aotearoa, New Zealand. They are committing crimes against some of our most endangered wildlife and arriving uninvited to the party. Protecting our taonga falls into the hands of conservationists and wildlife managers. New research plays a vital role in protecting our precious taonga.

    Menacing mouse – a little creature creating a big problem. Photo by Nils Fleischeuer (CC BY-NC)

    Would you be surprised to read that mice (Mus musculus) have been recorded eating live albatross (300 times their size)? I sure was! How could a little mouse possibly kill a bird known for having the largest wingspan in the world? Sadly, lots of albatross die from mouse predation every year. When mice aren’t eating albatross, they dine on many species of insects, chicks, eggs and lizards.

    If mice are so terrible, what about rats? There are three species of rat in Aotearoa, the Norway rat Rattus norvegicus, Black rat Rattus rattus and the Polynesian rat Rattus exulans. They are all bad news – they kill adult birds, chicks, snails and insects. They also compete for food that should be there for our native fauna.

    Due to the negative impacts of these rodents, and other introduced predators, many of New Zealand’s most critically endangered fauna are whisked away to predator-free off-shore islands. Some are protected behind expensive predator-resistant fences. PHEW, job completed, right? Not so fast!

    Despite eviction notices, Micky and Scabbers can wriggle their way back into our protected areas. Maybe it’s a quick hop along a fallen tree that bridges the now not so “predator-resistant” fence or a long swim to an off-shore island. When they do appear, we need to have proven tools in the toolbox to deal with them. One of the tools to control them is cereal poison bait.

    These baits are like your breakfast cereal in that they are made from similar ingredients – apart from the poison! Picture this: you reach for your new box of breakfast cereal in the morning and notice an open, very much neglected, box of cereal sitting at the back of your pantry. It’s been there for so long you can’t remember opening it (or you’ve just been ignoring it for many months). It smells stale and has gone slightly soggy, so you bin it, knowing full well that it will taste nasty.

    A good rat is a dead rat! Photo by Jacqui Geux, iNaturalist NZ, (CC-BY)

    Bait stations are used to protect the bait from the rain. However, just like you with your open box of stale cereal, mice and rats also have preferences when it comes to eating their cereal. The longer that bait is stored inside bait stations, the less palatable it is to rodents, the less they eat and the longer it continues to sit and weather.

    To make things worse, the bait stations are often irregularly serviced, so wildlife managers need a bait that stays palatable to mice and rats for as long as possible. This is an issue on remote predator-free islands and fenced predator-resistant sanctuaries that have difficult access and limited funds. Stale or mouldy bait in particular will not control rodents if they aren’t even going to eat it.

    If only there was a way to prevent baits from absorbing moisture and going mouldy – keeping the bait fresh for longer so that mice and rats were more likely to eat it when they come across it …

    This is where researchers at Lincoln University (NZ), James Ross and colleagues, had an idea to coat the baits in a material that will do just these things. Also the material will not reduce the palatability of the baits to mice and rats. To test this idea, they created an experiment using two coatings, Polyvinyl butyral (PVB) and Shellac. Shellac is already used as a food glaze and as a coating to mask the bitter taste of Paracetamol/Acetaminophen. Shellac is also fully biodegradable, which makes it environmentally friendly.

    The coatings were tested using four combinations of the aforementioned substances. First, they had to ensure the new coatings didn’t reduce the palatability compared to uncoated baits. If mice and rats do not eat the new bait coatings, it would be a waste of time to test them further. If Whitakers coated your favourite chocolate bar in something strange, you might take one bite and decide that the new “sardines & whipped cream” coated chocolate bar was not your vibe.

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    An easy pill to swallow – A Panadol tablet, commonly coated in Shellac. (CC BY-NC-SA 2.0) Photo by venana, Flickr. 

    The researchers also had to measure whether coated pellets remained palatable after extended environmental exposure because this is highly likely how mice and rats will find the baits in the real world. In the experiment the coatings were placed on the food the captive rats and mice were fed on. Mice, and more so rats, are neophobic (afraid of new things). So placing new food in their cages might affect the results in such a way that the researchers are measuring the wrong thing. Putting the coatings on their food means their wary responses will be minimised, since they eat rodent pellets every day. After the mice and rats had munched their way through their favourite snacks, the bowls were weighed, and the results were in – Shellac for the win.

    There were differences between the bait coating combinations; Shellac was the most palatable, it performed the best for both mice and rats. Shellac out preformed the PVB coating and the mix of PVB/Shellac. This experiment demonstrated that mice and rats are picky eaters and highlights the importance of testing the different coating types. Coatings, although no thicker than 500 micrometers (really thin), will affect how much mice and rats will eat. Ironic given that mice and rats will eat out of a trash can – now we know they are fussily searching for the “best rubbish”.

    This research is a step in the right direction for conservation in Aotearoa. I call it a small win for the native fauna. With Shellac showing promising signs, researchers and wildlife managers can test the new bait coatings in the field. Wild Mickey and Scabbers can try out some of the mould free, ‘fresh as can be’ Shellac bait. So next time Mickey and Scabbers arrive uninvited to the party, it may be the last thing they do.

    This article was prepared by Master of Pest Management student Nils Fleischeuer as part of the ECOL608 Research Methods in Ecology course.

  • The spitfire: a sure-fire way to eradicate stoats?

    Stoat! Look out, the RAF (Really Awesome Field-research) is coming! Photo CC BY-NC 2.0 Stuart Smith, Flickr

    Stoats, weasels and ferrets: the terrifying trio. If New Zealand’s native birds could speak, I’m sure that’s how they would refer to them as they swap stories of escape and near misses. Widespread, wily and lethal, the stoat is considered the greatest threat to the survival of many endangered and threatened native birds on the mainland, such as the takahe, orange-fronted parakeet, and Leonardo DiCaprio’s favourite, the kakī (black stilt).

    Here are the cold, hard facts. Humans introduced stoats from Europe to control rabbits in the 1880’s, against the advice of ecologists at the time. They have since run rampant over our native bird species, throwing many populations into a drastic decline. Like clever little kleptomaniacs, they sleep on beds of feathers stolen from our most treasured and rare birds.

    We must eradicate stoats from areas of New Zealand if we are to have an extant bird as our national icon. The prevailing question is, how?

    Photo CC BY-NC-ND 2.0 Shellie Evans, Flickr

    Never fear, the Spitfire is here! Unless you are a stoat then, yes, be afraid. The Spitfire is a re-setting toxin delivery device which was trialled in the Blue Mountains of Otago in 2013. 65 Spitfire devices were set up for approximately six weeks. Each device was capable of delivering 100 lethal doses of the stoat killing toxin PAPP (para-aminopropiophenone).

    The stoat population was monitored in the area during this time using trail cameras and tracking tunnels in order to measure the Spitfire’s effects.

    The project was carried out by Elaine Murphy, Tim Sjoberg and James Ross from Lincoln University, along with researchers from Wildlands, the Department of Conservation and Connovation. They found that the Spitfire knocked down 62% of the stoat population in the trial area.

    The Spitfire is a very picky individual, only delivering the lethal dose of poison to a suitor of the right body size and shape. The device is able to do this due to its dual sensors. Cameras trained on the Spitfire devices during the trial in Otago recorded no instances of non-target species, such as rifleman, receiving any of the poison. PAPP has been registered for use in stoat control since 2011, but is mostly available for use in fresh meat lures, which are labour intensive to produce and expire quickly.

    The 2013 trial was a success for the Spitfire and PAPP, but it was not without it’s issues. It was a trial after all! Many of the devices malfunctioned before the end of the six week trial due to design faults in weather proofing and circuitry. The conclusion was that the Spitfire showed promise, but lacked in stamina and sturdiness.

    Kereru in Kawakawa, Photo CC BY 2.0 Geoff McKay, Flickr

    All was not lost! In 2016 the New Zealand Government announced its goal to become predator (rats, mustelids and possums) free by 2050, which led to a funding initiative called ‘Products to Purchase‘ from PF2050 Ltd. Five products were selected, based on their expected contribution to the cause, to receive funding to fast track their development to a marketable level.

    In 2019, the first five successful applicants were named, and who should be among them but our voracious Spitfire. A Tauranga based start-up called Envico Technologies Ltd (ECT) went back to the drawing board with the device. They re-engineered and re-invigorated the design and produced a prototype they could now commercialise, all with the help of the funding from PF2050 Ltd.

    The Spitfire was back in the game, with the new design finalised in 2020. The latest model promises a longer lifespan of one year, during which no maintenance or refills are required. It’s widely known that the main cost in stoat control is in the field hours with bait station and trap operations, so this hands-free option is looking like an economical as well as an effective choice.

    Also on the toolbelt of the new Spitfire model is a bluetooth data logger, which records the date and time of trigger events. ECT envisions this feature being highly beneficial for monitoring pest populations and assisting with re-invasion events in eradicated areas. Because of it’s long field life, the Spitfire becomes an attractive option for use in more remote areas where previously the only viable option has been aerial 1080 drops. If you have a ‘Ban 1080’ bumper sticker, this product may be for you.

    Brushtail possum and her joey at Tārerekautuku Yarrs Lagoon, Photo Katherine Turton.

    Just when you think it can’t get any better, a distinct advantage of the Spitfire is that there are few issues with alternative food sources or bait shyness. Stoats don’t have to bite, pull, stand on a treadle, or count backwards from 100 to receive a lethal dose. They are simply drawn in by an automatic lure dispenser that keeps a delicious mayonnaise paste coming all year-round.

    The Spitfire is an intellectual. It has smart capacitive sensors that can detect and measure anything that is conductive. It can tell the difference between the long sausage body of a stoat and a little compact rifleman, preventing our inquisitive native species from receiving the toxin. When the Spitfire senses a stoat it launches a lethal splurge of toxin onto the abdomen, after which the animals are instinctually driven to groom off the mess.

    ECT joined forces with the Department of Conservation and Boffa Miskell to conduct field trials from 2020-2022. Alongside the stoat design, a model specifically for our Australian foes, the brushtail possum, was also trialled using a Diphacinone and Cholicalciferol toxin instead of PAPP.

    Field trials are about to conclude for the Spitfire and ECT are expecting to roll out the finished product at $200 a piece. There is also talk that a rat specific Spitfire is now in the works! This innovative technology is paving the way for more effective pest control not just here in New Zealand but worldwide. Conservation groups get your wallets ready and watch this space!

    For more information, see the article on the Sptifire trial in Otago and follow ECT to keep up with their latest technological solutions for conservation!

    This article was prepared by postgraduate student Katherine Turton as part of the ECOL 608 Research Methods in Ecology course in her Master of Pest Management degree.