Attempts to use anti-fertile vaccines to stop breeding in wildlife animals date back to late 1980. Initial studies showed that pregnancies could be prevented by multiple-shot vaccines [34] containing PZP and Freund’s adjuvants. These were followed by studies showing that these vaccines could be remotely delivered effectively to free-ranging animals (horses, deer and elephants), but the requirement for repeated initial shots and annual boosters limited management application. During the following years the formulation of vaccines was improved steadily. Now vaccines are effective for several years with a single treatment [84–87].

Multiple booster treatment were replaced by microsphere particles or polymer-based controlled-released pellets [30, 88, 89] containing the antigen and the adjuvant. Immunogenicity of antigens was increased by tagging them to another protein, and implementation of different adjuvants [30, 90, 91]. The replacement of Freund’s adjuvant was aimed to prevent local and systemic side effects described in several wildlife animals [92].

Beside the progress made in delivery procedure, the parenteral immunization requires an individual approach to the animal and is therefore limited to captive or small populations of free-ranging wild animals. In this respect, an individual-based rotational vaccination was suggested in long-lived, social species (e.g. wild elephant) to stretch the inter-calving interval for each individual, preventing exposing females to unlimited long-term immune contraception use [93]. It is also discussed to combine parenteral vaccination campaigns (e.g. for elimination of canine rabies) with immune contraception [94, 95] for population control.

Alternative contraceptive vaccines are actively being developed to enable large numbers of wild animals to be targeted by oral delivery of baits, when single animal’s treatment will be not effective or possible (pest or alien species). The distribution of baits and collecting remaining bait could be handled similarly to rodendicide baits [7]. It is proposed that vaccines which will be delivered orally by baits will stimulate a mucosal immune response to the foreign antigen(s). Such a vaccine requires a detailed understanding of reproductive-tract mucosal immunity in target species. Oral contraceptive vaccines under consideration include viral or bacterial vectors and microencapsulated antigens [18]. Although baits are increasingly used in wildlife management to deliver vaccines for disease control, a contraceptive oral vaccine is not available yet. In addition, safety requirements concern the transmissibility of the antigen in case of viral or bacterial vectors, the reversibility of the intervention within an individual animal and in animal populations, as well as the species specificity of the antigen used [96].

In particular for wild boar, bait-delivered contraceptive vaccines are increasingly advocated to assist the population management [97]. Ferretti et al. evaluated a Boar-Operated-System to deliver baits to wild boar in areas with a large community of potential non-target species [98].

Vaccination based nasal inoculation resulted in a high antibody response in mucosal tissues, including genital tracts [99], and were suggested to avoid a pathogenic T cell activation [100], a side effect causing autoimmune destruction of gonads. Thus, the intranasal co-delivery may present a safe strategy for the development of contraceptive vaccine. Vehicles for potential nasal delivery of vaccines include bacterial ghost, virus-like-particles [101, 102] or nanoparticles [103].

An alternative approach to protein production using bacteria or virus presents the plant-based immune contraception especially for herbivore animals. Female possums vaccinated with immunocontraceptive antigens showed reduced fertility, and possums fed with potato-expressed heat labile toxin-B (LT-B) expressed mucosal and systemic immune responses to the antigen. This demonstrated that immune contraception was effective in possums and that oral delivery in edible plant material might be possible. Prior to attempts at large scale production, more effective antigen-adjuvant formulations are probably required before plant-based immunocontraception can become a major tool for population control of overabundant vertebrate pests [104].

One approach to deliver immunocontraceptive vaccines are self-disseminating agents as a viruses. This approach employs live genetically modified viruses to deliver immunocontraceptives and has proved successful under laboratory conditions. Under field condition, a virus may have the advantage of self-regulating depending on density of the target species [12] and can be species specific if the viral vector is species specific [66, 105]. However, despite a large number of studies on VVIC [14, 66], so far no product has been developed for field testing. The ability of an immunocontraceptive virus to control populations is not only compromised by several factors like sufficient transmission rate, competition with field strains of virus or its ability to induce infertility in the presence of field strains [106], there are also safety and regulatory concerns about maintaining the species specificity of the viral vector and other potential unexpected changes in such genetically modified virus. Once released, a vector cannot be recalled and may spread to regions where the original target species is not a pest [13]. These constraints indicate that it is very unlikely that VVIC will be applied in near future [105].