Hostname: page-component-586b7cd67f-gb8f7 Total loading time: 0 Render date: 2024-11-27T20:49:29.022Z Has data issue: false hasContentIssue false

What do we know about the life-history traits of widely hunted tropical mammals?

Published online by Cambridge University Press:  28 February 2018

Nathalie van Vliet*
Affiliation:
Center for International Forestry Research, Bogor Barat, Indonesia
Robert Nasi
Affiliation:
Center for International Forestry Research, Bogor Barat, Indonesia
*
(Corresponding author) E-mail [email protected]
Rights & Permissions [Opens in a new window]

Abstract

We synthesize information on parameters useful for managing the hunting of two common mammal species that are important for local people in the Neotropics and Africa: Cuniculus paca and Philantomba monticola, respectively. We highlight the scarcity of data available on the parameters needed to manage these two species sustainably. As most of the studies were conducted > 40 years ago, we stress the need to supplement the information available using methodological and technical innovations. In particular, we call for new assessments covering the possible variations in parameter values across the species’ distribution ranges, and covering various anthropogenic contexts, to test density-dependent and compensatory processes that may explain the resilience of these species to hunting.

Type
Article
Copyright
Copyright © Fauna & Flora International 2018 

Introduction

Hunting is considered to be a major threat to wildlife populations in tropical forest regions (Fa et al., Reference Fa, Peres and Meeuwig2002; Mallon et al., Reference Mallon, Hoffmann, Grainger, Hibert, van Vliet and McGowan2015; Benítez-Lόpez et al., Reference Benítez-López, Alkemade, Schipper, Ingram, Verweij, Eikelboom and Huijbregts2017), and mammals comprise the greatest portion of hunted species (Fa et al., Reference Fa, Peres and Meeuwig2002; Nasi et al., Reference Nasi, Taber and van Vliet2011). A meta-analysis has demonstrated that there have been significant declines (up to 83%) in mammal abundances in many regions as a result of hunting pressure (Benítez-Lόpez et al., Reference Benítez-López, Alkemade, Schipper, Ingram, Verweij, Eikelboom and Huijbregts2017). The unsustainable use of wild mammals in most tropical forest areas hinders the possibility that impoverished communities will be able to continue to feed on wild mammals in the future (Wilkie et al., Reference Wilkie, Wieland, Boulet, Le Bel, van Vliet and Cornelis2016).

After several decades of a so-called fences and fines approach to hunting there is now a wider recognition that sustainable-use approaches merit more consideration (CBD, 2016; Mayor et al., Reference Mayor, El Bizri, Bodmer and Bowler2017). Managing hunting sustainably must address the multiple needs and desires of societies without jeopardizing the options for future generations to benefit from the full range of goods and services provided by hunted species (van Vliet et al., Reference van Vliet, Fa and Nasi2015).

In ecological terms the ability of prey species to withstand various levels of harvest, without depletion, depends on the life-history traits and biological parameters of the species (Caughley, Reference Caughley1977). Population dynamics depend on intrinsic population growth, mortality and the dynamics of in–out migration based on spatial (e.g. dispersal rate, dispersal distance and territory size) and temporal (e.g. seasonality of reproduction) parameters (Novaro et al., Reference Novaro, Redford and Bodmer2000; Salas & Kim, Reference Salas and Kim2002; van Vliet et al., Reference van Vliet, Milner-Gulland, Bousquet, Saqalli and Nasi2010).

A thorough understanding of the dynamics of prey populations under hunting pressure is needed for robust management decision-making. In tropical forests one of the major impediments to sound estimates of population dynamics is the paucity of available biological and ecological data for hunted species (Milner-Gulland & Akçakaya, Reference Milner-Gulland and Akçakaya2001; van Vliet & Nasi, Reference van Vliet and Nasi2008; Weinbaum et al., Reference Weinbaum, Brashares, Golden and Getz2013; van Vliet et al., Reference van Vliet, Fa and Nasi2015; Mayor et al., Reference Mayor, El Bizri, Bodmer and Bowler2017), and when such data exist they are not available in a synthetic and comprehensive manner.

Here we synthesize all the available information regarding parameters pertinent to the sustainable use of two of the most hunted tropical species: the lowland paca Cuniculus paca (in the Neotropics) and the blue duiker Philantomba monticola (in Africa). These are common and generalist small-sized species, with a widespread geographical range, and are crucial for the livelihoods of many rural communities.

Study species

Cuniculus paca is a large nocturnal rodent that occurs in Mexico, Colombia, Venezuela, the Guianas, Ecuador, Peru, Bolivia, Paraguay and most of Brazil, and has been introduced into Cuba and the Antilles (Patton et al., Reference Patton, Pardiñas and D'Elía2015). The species occurs in a wide range of forest types in moist areas and is an important seed distributor, with scatter-hoarding behaviour (Eisenberg & Redford Reference Eisenberg and Redford1999). It is categorized as Least Concern on the IUCN Red List, based on its wide distribution, presumed large population, and occurrence in a number of protected areas, and because it is unlikely to be declining (Emmons, Reference Emmons2016). However, unsustainable hunting of the paca has been reported from several locations (e.g. Koster, Reference Koster2008; Zapata-Ríos et al., Reference Zapata-Ríos, Urgilés and Suárez2009; Valsecchi et al., Reference Valsecchi, El Bizri and Figueira2014) and has led to local depletion of the species. The paca is sought after for its taste, nutritional value and low fat content (Aguiar, Reference Aguiar1996; Cordón and de Ariza, Reference Cordón and de Ariza1999; Lemire et al., Reference Lemire, Fillion, Barbosa, Guimarães and Mergler2010; Gálvez et al., Reference Gálvez, Arbaiza, Carcelén and Lucas2014), and because of these attributes is one of the most hunted and consumed species in Latin America (Koster, Reference Koster2008; Read et al., Reference Read, Fragoso, Silvius, Luzar, Overman, Cummings and de Oliveira2010; El Bizri et al., Reference El Bizri, Morcatty, Lima and Valsecchi2015; Quiceno-Mesa et al, Reference Quiceno-Mesa, van Vliet, Moreno and Cruz-Antia2015; van Vliet et al., Reference van Vliet, Fa and Nasi2015; Gómez et al., Reference Gómez, Restrepo, Moreno, Daza, Español and van Vliet2016; Vanegas et al., Reference Vanegas, van Vliet, Cruz and Sandrin2016).

Philantomba monticola is an abundant ungulate, widely distributed in central, eastern and southern Africa, from the Cross River in Nigeria to south-west South Sudan and southwards to central Angola, and Zambia, Malawi, eastern Zimbabwe, parts of central Mozambique, and on the islands of Pemba, Zanzibar and Mafia (East, Reference East1999; Wilson, Reference Wilson2001; Hart & Kingdon, Reference Hart and Kingdon2013). It thrives in a wide range of forested and wooded habitats, including primary and secondary forests, gallery forests, dry forest patches, coastal scrub farmland, regenerating forest and degraded forest patches, even near human settlements (Hart & Kingdon, Reference Hart and Kingdon2013). The species is among the most hunted throughout its range and is an important source of meat and income for rural people (de Merode et al., Reference de Merode, Homewood and Cowlishaw2004; Kümpel, Reference Kümpel2006; van Vliet et al., Reference van Vliet, Nasi, Emmons, Feer, Mbazza and Bourgarel2007; van Vliet & Nasi, Reference van Vliet and Nasi2008). It withstands hunting pressure better than most of the larger duikers (van Vliet et al., Reference van Vliet, Nasi, Emmons, Feer, Mbazza and Bourgarel2007; Mockrin, Reference Mockrin2008) and is categorized as Least Concern on the IUCN Red List (IUCN SSC Antelope Specialist Group, 2016).

Methods

During March–April 2017 we carried out a bibliographic search using seven databases: ISI Web of Science, Science Direct, EBSCO, Scielo, Redalyc, Scopus and Google Scholar. The search used a combination of words in English, Spanish, Portuguese and French: (‘species scientific name’ OR ‘common name’) AND (reproducti* OR dispers* OR behaviour OR mortality OR gestati* OR offspring OR longevity OR ‘litter size’ OR ‘biological parameters’ OR ‘life-history traits’). For the blue duiker we used the scientific names Cephalophus monticola and Philantomba monticola, as both are commonly used in the literature.

We screened the references using titles and abstracts according to the following primary inclusion criteria:

  1. (1) Only studies for which we were able to source the full text. We searched for the full online text or the PDF, contacting the authors if necessary. We were able to source full documents from as far back as 1900.

  2. (2) Only studies with scientific merit. To ensure the scientific quality of the information reported, we selected only peer-reviewed documents such as scientific journal articles, published records of zoological data produced by zoos, book chapters or theses for Master's or PhD degrees.

  3. (3) Only focused on the species of interest to this study. We selected only papers that provided information on C. paca or P. monticola.

We screened the resulting references based on the full text and used the following secondary criteria:

  1. (1) Only studies that contained information on the following biological and demographic parameters useful for prey population management (Sutherland, Reference Sutherland2008): (i) Variables used in one-off intrinsic population growth models (Robinson & Redford, Reference Robinson, Redford, Robinson and Redford1991): age at first and last reproduction, gestation period, litter size, interval between births, sex ratio at birth (female/male), longevity, mortality rate. (ii) Variables used in spatially explicit demographic models (Novaro et al., Reference Novaro, Redford and Bodmer2000; Salas & Kim, Reference Salas and Kim2002; van Vliet et al., Reference van Vliet, Milner-Gulland, Bousquet, Saqalli and Nasi2010): mean territory size; dispersal distance, dispersal rate, dispersal age. (iii) Variables influencing temporal variations: seasonality in reproduction, dispersal and mortality.

  2. (2) Only studies providing primary data. We selected studies only if they provided primary information on the biological and demographic characteristics described above. If no primary data were provided but the primary source was cited (e.g. in the AnAge database (Tacutu et al., Reference Tacutu, Craig, Budovsky, Wuttke, Lehmann and Taranukha2013) or in Weigl, Reference Weigl2005), then the primary source was searched and, if available, screened based on the same primary and secondary criteria described above.

For each of the studies that passed our filters (16 for P. monticola and 18 for C. paca) we extracted the information on each of the 15 variables (Tables 1 and 2), and recorded whether the information came from wild or captive populations, and the size of the sample studied, if available.

Table 1 Primary data available on basic biological and ecological parameters (reproduction, mortality, dispersal and seasonality) for the blue duiker Philantomba monticola. No data were available on age at last reproduction, mortality rate, seasonality of mortality and seasonality of dispersal. Blank cells indicate data were not provided in the source document.

Table 2 Primary data available on basic biological and ecological parameters (reproduction, mortality, dispersal and seasonality) for the lowland paca Cuniculus paca. No data were available on dispersal (age, rate, distance, seasonality). Blank cells indicate data were not provided in the source document.

Results

Philantomba monticola

A total of 16 studies published during 1900–2010 were found to have generated primary data on biological and demographic parameters for P. monticola, of which eight were based on individuals in captivity, five on wild individuals from South Africa, two on wild individuals in Gabon and one on wild individuals in Republic of Congo. Most of the information for each variable was gleaned from 1–6 studies, mostly from individuals in captivity or from a limited number of wild individuals (1–16). No information was found on age at last reproduction, mortality rate, seasonality of mortality or seasonality of dispersal. The results are synthesized in Table 1.

Cuniculus paca

A total of 18 studies published during 1979–2016 were found to have generated primary data on the biological and demographic parameters of C. paca, of which 13 were based on individuals in captivity and five on wild individuals (in Peru, Colombia, French Guiana, Costa Rica). Reproduction variables were derived from sample sizes of 45–212 for individuals in the wild and 2–49 for individuals in captivity. For longevity, a sample of 40 individuals was used. For seasonality in reproduction, data were derived from samples of 2–49 individuals. We found no information on dispersal (age, rate, distance, seasonality). The results are synthesized in Table 2.

Discussion

We summarize the available published data on the main variables needed to assess productivity and management for the sustainable use of two common and non-threatened species used as a source of food in African and Neotropical forests. Researchers and managers may refer to the synthetic tables produced, in which we cite the primary sources of data, with information they provide on sample size, geographical origin of the assessment and whether the data originated from captive or wild individuals.

In general terms, our review suggests that both species reach maturity after c. 1 year following birth, reproduce twice per year all year round, for the whole duration of their mature life (c. 10 years) and give birth to one offspring per year. In addition, the available data suggest that P. monticola has the capacity to disperse and occupy available empty areas through a small-scale source–sink process (Mockrin, Reference Mockrin2010). This behavioural characteristic probably contributes to the resilience of the species to hunting (van Vliet et al., Reference van Vliet, Milner-Gulland, Bousquet, Saqalli and Nasi2010). No information on dispersal is available for C. paca. The resilience to hunting observed for this species may be linked to its generalist behaviour and capacity to exist in high population densities (83–96 individuals per km2; Eisenberg & Redford, Reference Eisenberg and Redford1999).

This review highlights the paucity of data available for the parameters needed to manage these species sustainably. There is little information available on parameters that influence demographic patterns, such as reproduction, dispersal, home range characteristics, mortality, longevity and seasonal variations. Most of the available data are from captive individuals, and most, particularly for P. monticola, are from studies conducted during the 1980s and 1990s or earlier.

The lack of robust data on life-history traits hinders efforts to propose sustainable management practices for these two species, which are both important nutritional assets for forest people. Nevertheless, scientists and decision makers continue to make decisions based on erroneous estimates of maximum sustainable yields. Without a significant investment in estimations of life-history traits under varying contexts, quota setting efforts are prone to failure as they will be based on best guesses rather than on sound scientific evidence.

We call for new assessments covering the possible variations in parameter values across the distribution range of these two species, and covering various anthropogenic contexts; for example, to address hypotheses on forms of density-dependent mortality and reproduction, and compensatory vs additive mortality effects in tropical harvested species (Weinbaum et al., Reference Weinbaum, Brashares, Golden and Getz2013). Life-history trait data are also needed for many other species, particularly those of conservation concern, as the use of mean values from a few studies is insufficient to assess intra-specific variations and adaptations of different populations in relation to environmental and anthropogenic gradients.

Methodological and technical innovations already developed could help produce new assessments; for example, participatory sampling involving hunters (e.g. to collect reproductive organs or monitor pregnant females) is an underestimated and under-used approach that could be an efficient means of gathering information about reproduction patterns (Mayor et al., Reference Mayor, El Bizri, Bodmer and Bowler2017; van Vliet et al., Reference van Vliet, Sandrin, Vanegas, L'haridon, Fa and Nasi2017). Technologies such as camera traps (Jędrzejewski et al., Reference Jędrzejewski, Puerto, Goldberg, Hebblewhite, Abarca and Gamarra2017), non-invasive DNA methods (Fusaro et al., Reference Fusaro, Conner, Conover, Taylor, Kenyon, Sherman and Ernest2017; Granjon et al., Reference Granjon, Rowney, Vigilant and Langergraber2017), injectable sensors or electronic tags (Bozkurt, Reference Bozkurt2017), passive integrated transponder tags (Ousterhoudt & Burkhart, Reference Ousterhout and Burkhart2017), micro-chip implants, vaginal implant transmitters (Newbolt et al., Reference Newbolt, Acker, Neuman, Hoffman, Ditchkoff and Steury2017), modern recording systems for acoustic monitoring (Crossin et al., Reference Crossin, Heupel, Holbrook, Hussey and Lowerre-Barbieri2017), and advanced telemetry systems using ultra-light global positioning systems (Alippi et al., Reference Alippi, Ambrosini, Longoni, Cogliati and Roveri2017) could be applied to forest mammals and contribute to a better understanding of their demographic parameters (Mathur et al., Reference Mathur, Habib and Mathur2017).

Acknowledgements

We acknowledge the contributions from Daniel Cruz, Jessica Moreno and Federico García in supporting the bibliographic search. This work was funded by the U.S. Agency for International Development through the Bushmeat Research Initiative of the Center for International Forestry Research and the Forest, Trees and Agroforestry Program of CGIAR.

Author contributions

NvV conceived the study, carried out the bibliographic search and wrote a first draft of the article. RN contributed extensively to revisions of the article.

Biographical sketches

Nathalie van Vliet’s research focuses on the links between wildlife and livelihoods. For the last 15 years she has worked on bushmeat and its contribution to food security and local economies in Central Africa. She has also developed research projects in the Amazon, where her team is analysing bushmeat market chains and consumption patterns. Working at local, national and international levels, her research aims to provide more visibility to current bushmeat use and provide objective data for innovative management policies that include ecological, cultural and socio-economic sustainability. Robert Nasi has been living and travelling extensively in Africa, Asia and the Pacific since 1982, undertaking research in the fields of ecology and management of tropical forests. He is interested in the various issues related to the sustainable use of forest resources, blending conservation and development.

References

Aguiar, J.P.L. (1996) Notas e comunicações. Tabela de Composição de Alimentos da Amazônia. Acta Amazonica, 26, 121126.Google Scholar
Alippi, C., Ambrosini, R., Longoni, V., Cogliati, D. & Roveri, M. (2017) A lightweight and energy-efficient Internet-of-birds tracking system. In 2017 IEEE International Conference on Pervasive Computing and Communications (PerCom), pp. 160–169. IEEE, Kona, Hawaii, USA.Google Scholar
Beck–King, H., Helversen, O.V. & Beck–King, R. (1999) Home range, population density, and food resources of Agouti paca (Rodentia: Agoutidae) in Costa Rica: a study using alternative methods. Biotropica, 31, 675685.Google Scholar
Benítez-López, A., Alkemade, R., Schipper, A.M., Ingram, D.J., Verweij, P.A., Eikelboom, J.A.J. & Huijbregts, M.A.J. (2017) The impact of hunting on tropical mammal and bird populations. Science, 356, 180183.Google Scholar
Boehner, J., Volger, K. & Hendrichs, H. (1984) Breeding dates of blue duikers (Cephalophus monticola). Zeitschrift fuer Saeugetierkunde, 49, 306314.Google Scholar
Bowland, A.E. (1990) The ecology and conservation of the blue duiker and red duiker in Natal. PhD thesis. University of KwaZulu Natal, Durban, South Africa.Google Scholar
Bowland, A.E. & Perrin, M.R. (1995) Temporal and spatial patterns in blue duikers Philatomba monticola and red duikers Cephalophus natalensis. Journal of Zoology, 237(3), 487498.Google Scholar
Bowman, V. & Plowman, A. (2002) Captive duiker management at the duiker and mini-antelope breeding and research institute (Dambari), Bulawayo, Zimbabwe. Zoo Biology, 21, 161170.Google Scholar
Bozkurt, A. (2017) U.S. Patent No. 20,170,127,975. U.S. Patent and Trademark Office, Washington, DC, USA.Google Scholar
Brand, D.J. (1963) Records of mammals bred in the National Zoological Gardens of South Africa during the period 1908 to 1960. Journal of Zoology, 140, 617659.Google Scholar
Caughley, G. (1977) Analysis of Vertebrate Populations. John Wiley & Sons, London, UK.Google Scholar
Collett, S.F. (1981) Population characteristics of Agouti paca (Rodentia) in Colombia. PhD thesis. Michigan State University, East Lansing, USA.Google Scholar
Contrera Perez, H. & Zetina Hernandez, F. (1977) Comportamiento reproductivo y datos de la alimentación de Agouti paca nelsoni Goldman. In Congreso Latinoamericano de Zoología. Volume 7, Tucumán-Argentina, 15–21 May 1977.Google Scholar
CBD (Convention on Biological Diversity) (2016) XIII/8. Sustainable use of biodiversity: bushmeat and sustainable wildlife management. CBD/COP/DEC/XIII/8, Mexico, 8 December 2016. Https://www.cbd.int/doc/decisions/cop-13/cop-13-dec-08-en.pdf [accessed 9 October 2017].Google Scholar
Cordón, K. & de Ariza, J.S. (1999) Composición química de carnes de animales silvestres de consumo humano en la aldea Uaxactun, Peten. Revista Científica de la Facultad de Ciencias Químicas y Farmacia, 11, 2628.Google Scholar
Crandall (1965) The Monticola. West Virginia University, A.L. Swift & Co, Chicago, USA.Google Scholar
Crossin, G.T., Heupel, M.R., Holbrook, C.M., Hussey, N.E., Lowerre-Barbieri, S.K. et al. (2017) Acoustic telemetry and fisheries management. Ecological Applications. 27, 10311049.Google Scholar
de Merode, E., Homewood, K. & Cowlishaw, G. (2004) The value of bushmeat and other wild foods to rural households living in extreme poverty in Democratic Republic of Congo. Biological Conservation, 118, 573581.Google Scholar
Dittrich, L. (1972) Gestation periods and age of sexual maturity of some African antelopes. International Zoo Yearbook, 12, 184187.Google Scholar
Dubost, G. (1980) L ‘écologie et la vie sociale du Céphalophe bleu (Cephalophus monticola Thunberg), petit ruminant forestier africain. Ethology, 54, 205266.Google Scholar
Dubost, G. & Feer, F. (1992) Saisons de reproduction des petits Ruminants dans le nord-est du Gabon, en fonction des variations des ressources alimentaires. Mammalia, 56, 2543.Google Scholar
East, R. (1999) African Antelope Database 1998. IUCN/SSC Antelope Specialist Group, IUCN, Gland, Switzerland, and Cambridge, UK.Google Scholar
Eisenberg, J.F. & Redford, K.H. (eds) (1999) Mammals of the Neotropics, Volume 3: The Central Neotropics: Ecuador, Peru, Bolivia, Brazil. The University of Chicago Press, Chicago, USA.Google Scholar
El Bizri, H.R., Morcatty, T.Q., Lima, J.J.S. & Valsecchi, J. (2015) The thrill of the chase: uncovering illegal sport hunting in Brazil through YouTube™ posts. Ecology and Society, 20(3), 30.Google Scholar
Emmons, L. (2016) Cuniculus paca. In The IUCN Red List of Threatened Species 2016: e.T699A22197347. Http://dx.doi.org/10.2305/IUCN.UK.2016-2.RLTS.T699A22197347.en [accessed 27 May 2017].Google Scholar
Fa, J.E., Peres, C.A. & Meeuwig, J. (2002) Bushmeat exploitation in tropical forests: an intercontinental comparison. Conservation Biology, 16, 232237.Google Scholar
Fusaro, J.L., Conner, M.M., Conover, M.R., Taylor, T.J., Kenyon, M.W. Jr, Sherman, J.R. & Ernest, H.B. (2017) Comparing urban and wildland bear densities with a DNA-based capture–mark–recapture approach. Human–Wildlife Interactions, 11, 9.Google Scholar
Gálvez, H., Arbaiza, T., Carcelén, F. & Lucas, O. (2014) Valor nutritive de las carnes de sajino (Tayassu tajacu), venado Colorado (Mazama americana), majaz (Agouti paca) y motelo (Geochelone denticulata). Revista de Investigaciones Veterinarias del Perú, 10, 8286.Google Scholar
Gómez, J., Restrepo, S., Moreno, J., Daza, E., Español, L.M. & van Vliet, N. (2016) Carne de monte y medios de vida: Un recorrido por las diferentes regiones de Colombia. Https://cifor.exposure.co/ad27836d9fe48deb9a531120033cca39 [accessed 9 October 2017].Google Scholar
Granjon, A.C., Rowney, C., Vigilant, L. & Langergraber, K.E. (2017) Evaluating genetic capture–recapture using a chimpanzee population of known size. The Journal of Wildlife Management, 81, 279288.Google Scholar
Grzimek, B. (1990) Grzimek's Encyclopedia of Mammals. McGraw-Hill, New York, USA.Google Scholar
Hart, J.A. & Kingdon, J. (2013) Philantomba monticola blue duiker. Mammals of Africa, 6, 228234.Google Scholar
IUCN SSC Antelope Specialist Group (2016) Philantomba monticola. In The IUCN Red List of Threatened Species 2016: e.T4143A50183103. Http://dx.doi.org/10.2305/IUCN.UK.2016-1.RLTS.T4143A50183103.en [accessed 9 October 2017].Google Scholar
Jarvis, C. & Morris, D. (1961) Longevity survey. Length of life of mammals in captivity at the London Zoo and Whipsnade Park. International Zoo Yearbook, 2, 288299.Google Scholar
Jędrzejewski, W., Puerto, M.F., Goldberg, J.F., Hebblewhite, M., Abarca, M., Gamarra, G. et al. (2017) Density and population structure of the jaguar (Panthera onca) in a protected area of Los Llanos, Venezuela, from 1 year of camera trap monitoring. Mammal Research, 62, 919.Google Scholar
Koster, J. (2008) The impact of hunting with dogs on wildlife harvests in the Bosawas Reserve, Nicaragua. Environmental Conservation, 35, 211220.Google Scholar
Kümpel, N.F. (2006) Incentives for sustainable hunting of bushmeat in Río Muni, Equatorial Guinea. PhD thesis. University of London, London, UK.Google Scholar
Lawes, M.J., Mealin, P.E. & Piper, S.E. (2000) Patch occupancy and potential metapopulation dynamics of three forest mammals in fragmented afromontane forest in South Africa. Conservation Biology, 14, 10881098.Google Scholar
Lemire, M., Fillion, M., Barbosa, F. JrGuimarães, J.R.D. & Mergler, D. (2010) Elevated levels of selenium in the typical diet of Amazonian riverside populations. Science of the Total Environment, 408, 40764084.Google Scholar
Mallon, D.P, Hoffmann, M., Grainger, M.J., Hibert, F., van Vliet, N. & McGowan, P.J.K. (2015) An IUCN Situation Analysis of Terrestrial and Freshwater Fauna in West and Central Africa. Occasional Paper of the IUCN Species Survival Commission No. 54. IUCN, Gland, Switzerland.Google Scholar
Matamoros-Hidalgo, Y. (1982) Notas sobre la biología del tepezcuintle Cuniculus paca Brisson (Rodentia: Dasyproctidae) en cautiverio. Brenesia., 19–20, 7182.Google Scholar
Matamoros-Hidalgo, Y. & Pashov-Nicheva, B. (1984) Ciclo estral del tepezcuintle (Cuniculus paca Brisson), en cautiverio. Brenesia, 22, 249260.Google Scholar
Mathur, P.K., Habib, B. & Mathur, P. (2017) Technology advancement and integration in the context of wildlife conservation. In Human Bond Communication: The Holy Grail of Holistic Communication and Immersive Experience, pp. 115130. John Wiley & Sons, Hoboken, USA.Google Scholar
Mayor, P., El Bizri, H., Bodmer, R.E. & Bowler, M. (2017) Assessment of mammal reproduction for hunting sustainability through community-based sampling of species in the wild. Conservation Biology, 31, 912923.Google Scholar
Merritt, D. (1989) The husbandry and management of the paca Cuniculus paca at Lincoln Park Zoo, Chicago. International Zoo Yearbook, 28, 264267.Google Scholar
Milner-Gulland, E.J. & Akçakaya, H.R. (2001) Sustainability indices for exploited populations. Trends in Ecology & Evolution, 16, 686692.Google Scholar
Mockrin, M.H. (2008) The spatial structure and sustainability of subsistence wildlife harvesting in Kabo, Congo. PhD thesis. Columbia University, New York, USA.Google Scholar
Mockrin, M.H. (2010) Duiker demography and dispersal under hunting in Northern Congo. African Journal of Ecology, 48, 239247.Google Scholar
Nasi, R., Taber, A. & van Vliet, N. (2011) Empty forests, empty stomachs? Bushmeat and livelihoods in the Congo and Amazon Basins. International Forestry Review, 13, 355368.Google Scholar
Newbolt, C.H., Acker, P.K., Neuman, T.J., Hoffman, S.I., Ditchkoff, S.S. & Steury, T.D. (2017) Factors influencing reproductive success in male white-tailed deer. The Journal of Wildlife Management, 81, 206217.Google Scholar
Novaro, A.J., Redford, K.H. & Bodmer, R.E. (2000) Effect of hunting in source–sink systems in the Neotropics. Conservation Biology, 14, 713721.Google Scholar
Oliveira, F.S., Machado, M.R.F., Canola, J.C. & Camargo, M.H.B. (2007) Uniparidade em pacas criadas em cativeiro (Agouti paca, Linnaeus, 1766). Arquivo Brasileiro de Medicina Veterinária e Zootecnia, 59, 387389.Google Scholar
Oliveira, F.S., Toniollo, G.H., Machado, M.R.F. & Paura, D. (2003) Hemi-ovariossalpingohisterectomia em pacas prenhes e posterior ocorrência de prenhez (Agouti paca, Linnaeus, 1766). Ciência Rural, 33, 547551.Google Scholar
Ousterhout, B.H. & Burkhart, J.J. (2017) Moving beyond the plane: measuring 3D home ranges of juvenile salamanders with passive integrated transponder (PIT) tags. Behavioral Ecology and Sociobiology, 71, 59.Google Scholar
Patton, J.L., Pardiñas, U.F. & D'Elía, G. (2015) Mammals of South America, Volume 2: Rodents. The University of Chicago Press, Chicago, USA.Google Scholar
Quiceno-Mesa, M.P., van Vliet, N., Moreno, J. & Cruz-Antia, D. (2015) Diagnóstico sobre el comercio de carne de monte en las ciudades de Colombia. CIFOR Occasional Paper No. 136. Center for International Forestry Research, Bogor, Indonesia.Google Scholar
Read, J.M., Fragoso, J.M.V., Silvius, K.M., Luzar, J., Overman, H., Cummings, A. & de Oliveira, L.F. (2010) Space, place, and hunting patterns among indigenous peoples of the Guyanese Rupununi region. Journal of Latin American Geography, 9, 213243.Google Scholar
Robinson, J.G. & Redford, K.H. (1991) Sustainable harvest of Neotropical forest animals. In Neotropical Wildlife Use and Conservation (eds Robinson, J.G. & Redford, K.H.), pp. 415429. The University of Chicago Press, Chicago, USA.Google Scholar
Salas, L.A. & Kim, J.B. (2002) Spatial factors and stochasticity in the evaluation of sustainable hunting of tapirs. Conservation Biology, 16, 8696.Google Scholar
Sclater, P.L. & Thomas, O. (1900) The Book of Antelopes. R.H. Porter, London, UK.Google Scholar
Smythe, N. & Brown De La Guanti, O. (1993) La domesticación y cría de la paca (Agouti paca). Guía de Conservación No. 26. FAO, Rome, Italy.Google Scholar
Sutherland, W.J. (2008) The Conservation Handbook: Research, Management and Policy. Blackwell Publishing, Oxford, UK.Google Scholar
Tacutu, R., Craig, T., Budovsky, A., Wuttke, D., Lehmann, G., Taranukha, D. et al. (2013) Human Ageing Genomic Resources: integrated databases and tools for the biology and genetics of ageing. Nucleic Acids Research, 41(database issue), D1027D1033.Google Scholar
Valsecchi, J., El Bizri, H.R. & Figueira, J.E.C. (2014) Subsistence hunting of Cuniculus paca in the middle of the Solimões River, Amazonas, Brazil. Brazilian Journal of Biology, 74, 560568.Google Scholar
Vanegas, L., van Vliet, N., Cruz, D. & Sandrin, F. (2016) Contribución proteica de animales silvestres y domésticos a los menús de los contextos rurales, peri-urbanos y urbanos de varias regiones de Colombia. Biota Colombiana, 17, 2643.Google Scholar
van Vliet, N., Fa, J.E. & Nasi, R. (2015) Managing hunting under uncertainty: from one-off ecological indicators to resilience approaches in assessing the sustainability of bushmeat hunting. Ecology and Society, 20(3), 7.Google Scholar
van Vliet, N., Milner-Gulland, E.J., Bousquet, F., Saqalli, M. & Nasi, R. (2010) Effect of small-scale heterogeneity of prey and hunter distributions on the sustainability of bushmeat hunting. Conservation Biology, 24, 13271337.Google Scholar
van Vliet, N. & Nasi, R. (2008) Why do models fail to assess properly the sustainability of duiker (Cephalophus spp.) hunting in Central Africa? Oryx, 42, 392399.Google Scholar
van Vliet, N., Nasi, R., Emmons, L., Feer, F., Mbazza, P. & Bourgarel, M. (2007) Evidence for the local depletion of bay duiker Cephalophus dorsalis, within the Ipassa Man and Biosphere Reserve, north-east Gabon. African Journal of Ecology, 45, 440443.Google Scholar
van Vliet, N., Sandrin, F., Vanegas, L., L'haridon, L., Fa, J.E. & Nasi, R. (2017) High-tech participatory monitoring in aid of adaptive hunting management in the Amazon. Unasylva, 68, 5361.Google Scholar
Von Ketelhodt, H.F. (1977) The lambing interval of the blue duiker, Cephalophus monticola Gray, in captivity, with observations on its breeding and care. South African Journal of Wildlife Research, 7, 4143.Google Scholar
Weigl, R. (2005) Longevity of Mammals in Captivity: From the Living Collections of the World. Kleine Senckenberg-Reihe. Senckenberg, Frankfurt, Germany.Google Scholar
Weinbaum, K.Z., Brashares, J.S., Golden, C.D. & Getz, W.M. (2013) Searching for sustainability: are assessments of wildlife harvests behind the times? Ecology Letters, 16, 99111.Google Scholar
Wilkie, D.S., Wieland, M., Boulet, H., Le Bel, S., van Vliet, N., Cornelis, D. et al. (2016) Eating and conserving bushmeat in Africa. African Journal of Ecology, 54, 402414.Google Scholar
Wilson, V.J. (2001) Duikers of Africa (Masters of the African forest floor). Chipangali Wildlife Trust, Bulawayo, Zimbabwe.Google Scholar
Zapata-Ríos, G., Urgilés, C. & Suárez, E. (2009) Mammal hunting by the Shuar of the Ecuadorian Amazon: is it sustainable? Oryx, 43, 375385.Google Scholar
Figure 0

Table 1 Primary data available on basic biological and ecological parameters (reproduction, mortality, dispersal and seasonality) for the blue duiker Philantomba monticola. No data were available on age at last reproduction, mortality rate, seasonality of mortality and seasonality of dispersal. Blank cells indicate data were not provided in the source document.

Figure 1

Table 2 Primary data available on basic biological and ecological parameters (reproduction, mortality, dispersal and seasonality) for the lowland paca Cuniculus paca. No data were available on dispersal (age, rate, distance, seasonality). Blank cells indicate data were not provided in the source document.