Toward Targeted Invasive Predator Control: Developing pH-Responsive Subcutaneous Implants for Native Mammals

Abstract

Introduced predators are a significant threat to global biodiversity and are responsible for most of all modern bird, reptile, and mammal extinctions. In Australia, the introduced feral cat (Felis catus) kills 459 million mammals annually and leaves many species facing extinction. Attempted reintroductions of threatened mammal species often fail due to the persistence of intractable feral cats─termed “problem individuals”─and the swift depredation of the reintroduced population. Biomaterial implants could hold the key to targeting problem individuals. Herein, we report the development of the population-protecting implant, a subcutaneous implant for native mammals. The implant is intended to be inert within the subcutaneous environment for the life of the native mammal and to release a toxic payload in the gastric environment of a feral cat when ingested during a predation event. By toxifying and causing the death of the feral cat, the problem individual is eliminated, and the remaining population of native mammals is protected from further predation. To achieve this, an innovative reverse enteric coating was developed for use as a biomaterial, which exhibited a previously unreported level of pH selectivity for solubility at gastric pH. Large batches of implants were manufactured via fluidized-bed spray coating with a uniform reverse enteric coating and low intrabatch variability. Implants with a 300 μm coating afforded significant stability and retention of the payload at subcutaneous pH in vitro, with rapid release of the payload observed at gastric pH. In addition, implants exhibited favorable stability in vivo in rats, with no observed difference in biocompatibility compared to conventional radio-frequency identification microchips. This work demonstrates a proof of concept of an innovative type of implant and serves as the basis for its future development and translation into the field.