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Insects of forensic importance from Rio Grande do Sul state in southern Brazil
641Insects of forensic importance from Rio Grande do Sul state in southern Brazil
Revista Brasileira de Entomologia 52(4): 641-646, dezembro 2008
Alex Sandro Barros de Souza1, Frederico Dutra Kirst1 & Rodrigo Ferreira Krüger2
Decomposition is responsible for returning the organic
matter of dead plant and animals to the ecosystem.
Decomposition is first carried out by fungi and bacteria, and
then by large variety of arthropods (Weigelt 1989). The process
consists of the metabolic transformation of organic matter into
simple organic and inorganic compounds, with energy release.
The degradation process is continuous, but its division into
stages makes their study easier; the number and duration of
stages are highly dependent on climatic and seasonal variations
(Keh 1985; Richards & Goff 1997). The importance of the
decomposition process has reached beyond its role in nutrient
transformation, as it contributes for the establishment of
associated communities (Moura 2004).
Studies of fauna associated with cadavers are the most
important application of entomology to legal medicine, whereby
stored data can be used as forensic indicators. Some of the
species collected in these studies not only visit the carcass,
Insects of forensic importance from Rio Grande do Sul
state in southern Brazil
1Coordenação de Pesquisas em Entomologia ? Instituto Nacional de Pesquisas da Amazônia/INPA - Campus II, Caixa Postal 478, 69011-970
Manaus-AM; +55 92 3643-3201. alexsouza@inpa.gov.br; fdkirst@inpa.gov.br
2Campus Rio Paranaíba Universidade Federal de Viçosa, Rodovia BR 354 - km 310, 38810-000 Rio Paranaíba-MG , +55 31 38993136.
rfkruger@insecta.ufv.br
ABSTRACT. Insects of forensic importance from Rio Grande do Sul state in southern Brazil. The experiment was
conducted throughout the year 2005, at the Universidade Federal de Pelotas campus. The objectives of the study were
to analyze the decomposition of rabbit (Oryctolagus cunniculus L.) with mean weight 2.67 Kg carcass and describe the
interaction of insects acting on it, as well as the insect?s potential use in legal medicine. We collected 5.239 insect
specimens; 1.827 of them were obtained from larvae collected from carcasses and reared. The specimens were identified
and 20 species were of forensic importance. The species Lucilia eximia (Wiedemann, 1819) and Chrysomya albiceps
(Wiedemann, 1819) (Diptera, Calliphoridae) were better indicators of post-mortem interval (PMI) because they occurred
in all seasons and were the first to reach the carcass. Hemilucilia semidiaphana (Rondani, 1850), H. segmentaria
(Fabricius, 1805) (Diptera, Calliphoridae), Muscina stabulans (Fallén, 1817) and Synthesiomyia nudiseta (Wulp, 1883)
(Diptera, Muscidae) can disclose death time because they occur only in certain months of the year. Oxyletrum discicolle
(Brullé, 1840) (Coleoptera, Silphidae) and Dermestes maculates De Geer, 1774 (Coleoptera, Desmestidae) were found in
advanced stages of decomposition.
KEYWORDS. Carrion fauna; Coleoptera; Diptera; forensic entomology; IPM.
RESUMO. Insetos de importância forense do Rio Grande do Sul, sul do Brasil. Durante todas as estações do ano de 2005
foi conduzido um experimento em uma área do campus da Universidade Federal de Pelotas. O objetivo do estudo foi
analisar a decomposição de carcaças de coelho (Oryctolagus cunniculus L.) pesando 2,67 Kg em média e descrever como
os insetos atuam na decomposição e seu possível uso na medicina-legal. Foram coletados 5.239 espécimes; 1.827 foram
obtidos a partir da criação de imaturos coletados na carcaça. Foram identificadas 20 espécies com importância forense.
As espécies mais propícias para serem usadas com indicadoras de intervalo post-mortem (IPM) são Lucilia eximia
(Wiedemann, 1819) e Chrysomya albiceps (Wiedemann, 1819) (Diptera, Calliphoridae) por terem sido encontradas em
todas as estações de coleta e por serem uma das primeiras espécies a chegar à carcaça. Hemilucilia semidiaphana
(Rondani, 1850), H. segmentaria (Fabricius, 1805) (Diptera, Calliphoridae), Muscina stabulans (Fallén, 1817) e
Synthesiomyia nudiseta (Wulp, 1883) (Diptera, Muscidae) são espécies que podem indicar época da morte, pois ocorrem
em meses específicos do ano. Oxyletrum discicolle (Brullé, 1840) (Coleoptera, Silphidae) e Dermestes maculatus De
Geer, 1774 (Coleoptera, Desmestidae) são encontrados em estágios avançados de decomposição.
PALAVRAS-CHAVE. Diptera; Coleoptera; decomposição; entomologia forense; IPM.
but also use it as a resource during their immature development
stages (Keh 1985). The identification of larvae development
period makes possible the determination of the post-mortem
interval (PMI) (Catts & Haskell 1991).
Firstly, the determination of PMI depends on the physical
conditions of the cadaver; in late-decomposition cases, on
the study of bones and associated fauna (Oliveira-Costa 2008).
For greater reliability, such studies are conducted by an
entomologist and other experts, such as a legal physician and
a forensic pathologist (Catts & Haskell 1991). These studies
provide an initial data basis on species adapted to human
biocenose and their oviposition preferences, indicating the
species to be used for forensic investigations. In Brazil, most
studies of this kind have been conducted in Rio Claro (Gomes
& Von-Zuben 2004), Campinas (Monteiro-Filho & Peneireiro
1987; Sousa & Linhares 1997; Carvalho et al. 2001; Carvalho
& Linhares 2001), Rio de Janeiro (Salviano et al. 1996; Oliveira-
642 Souza et al.
Revista Brasileira de Entomologia 52(4): 641-646, dezembro 2008
Costa & Mello-Pattiu 2004), and Curitiba (Moura et al. 1997,
Mise et al. 2007).
In our paper, we discuss two central issues in forensic
entomology. First, the truly necrophagous species that can be
used as forensic indicators in the Pelotas region, southern
Brazil. Second, we discuss the seasonal insect behaviours.
Both approaches will contribute for the development of
forensic entomology in the extreme South of Brazil, as a data
basis for further medico-criminal investigations in the region.
MATERIAL AND METHODS
Site description. The research was conducted on the
campus of the Universidade Federal de Pelotas (31° 48? 58?? S;
52° 25? 55??W), Capão do Leão, Rio Grande do Sul (RS), southern
coastal plains, bioma Campo Sulinos, Brazil. The climate is Cfa
(Köppen classification), with annual mean temperature and
rainfall 18.2°C and 1283 mm, respectively.
Experimental proceeding. Metal cages (50 cm x 40 cm)
were used for the exclusion of necrophagous vertebrates. Each
cage was placed at a depth of 10 cm, for carcass contact with
the soil. At each collection site, a small area was cleaned for
better visualization and installation of the cage, following the
pattern described in Monteiro-Filho and Peneireiro (1987).
Four female rabbit carcasses , with mean weight 2.67 ± 0.71
Kg were used. All animals were mechanically killed by cervical
displacement; chemical substances that could affect the
decomposition process were not used (Micozzi 1986).
Specimens Collection. The carcasses were observed daily,
between 11 am and 2 pm, with a minimum observation time of
one hour per sample. The following data on carcass condition
were collected: decomposition stage, presence of larvae, and
decomposed organs, following the stage nomenclature
proposed by Rodriguez & Bass (1983).
The collections were conducted with minimum impact on
the fauna, particularly on the immature specimens. The actively
flying insects were collected with a modified entomological
net. Insects not captured for the trap and immature specimens
in larvae stage were collected directly on the carcass and in
the cages, with tweezers. All adult insects were killed with
ethyl acetate and preserved dry by entomological mounting
or in alcohol 70%.
The larvae were placed into containers with ground beef,
and placed in larger vials containing moist soil brought from
the collection site, for further pupariation of the reared
individuals. These vials were properly labelled with the date
and larva instars?, and covered with tulle. The pots were placed
at the Laboratory of Biology of Insects, Microbiology and
Parasitology Departament, Universidade Federal de Pelotas.
Temperature was not controlled until adult emergence due to
seasonality.
Climatic data were provided by the Agriculture
Climatological Station, Embrapa-Universidade Federal de
Pelotas.
RESULTS
Environmental conditions. Maximum and minimum
temperatures are in Figure 1, and means of relative humidity
are 72, 78; 82, 3; 89, 5 and 85, 71% in spring, summer, autumn
and winter, respectively.
The lowest mean for maximum temperature occurred in the
winter. For the other seasons the temperature was
approximately 27°C and a variation lower than 1°C. The widest
temperature range per day was observed in the summer (13-
31.6°C) and fall (19-30.2°C).
Relative humidity means were stable in all seasons,
approximately 86%, except for the winter, when the lowest
relative humidity mean was observed.
The duration of each experiment accomplished a change
of temperature on each season (Fig. 2).
Decomposition Stages.
Fresh Stage. Carcass shape has no visible change. Only
the body has a slight muscular rigidity that disappears in a
few hours, except in the winter, when rigidity lasted
approximately 48 hours. Small lesions on the nose and the
external ear due to the action of Pheidole sp. and Camponotus
rufipes Fabricius, 1775 (Hymenoptera, Formicidae) can also be
seen.
Bloated Stage. The abdominal region swells due to bacterial
action (Smith 1986). It is in the bloated stage that some
ovipositions can be seen, particularly in the mouth and anus,
which leads to an increase in the populations of Pheidole sp.
and C. rufipes. These individuals start predating eggs and
some first instar larvae. Other insects also begin to visit the
animal, such as Deltochilum sp. (Coleoptera, Staphylinidade),
Euspilotus ?group??azureus sp. (Coleoptera, Histeridae), and
Oxyletrum discicolle (Coleoptera, Silphidae).
Decaying Stage. The greater structural changes in the
carcass and the intensification of insect action in the
decomposition process can be observed. This stage has the
greatest richness of species, which are attracted either by the
exudates discharged by the body or by the large quantity of
larvae developing in the carcass. Larvae of Peckia (Pattonella)
resona (Lopes, 1935) (Diptera, Sarcophagidae) and other
insects start to develop, such as Dermestes maculatus
(Coleoptera, Dermestidae) Gastrisus sp. (Coleoptera,
Staphylinidae), Necrobia rufipes (De Geer, 1775), and Necrobia
ruficollis (Fabricius, 1775) (Coleoptera, Cleridae). Populations
of Pheidole sp, C. rufipes and Euspilotus ?group??azureus
sp. also are maintained.
Adipocere-like Stage. This stage is characterized by
hydrolysis of the carcass fatty tissue. The carcass loses its
shape completely and becomes a mass of non-decomposed
hair, fat, skin, and cartilage. Decomposition occurs firstly in
the subepitelial fat, which becomes a mass containing parts of
the digestive tract. The skin becomes rigid and protects the
643Insects of forensic importance from Rio Grande do Sul state in southern Brazil
Revista Brasileira de Entomologia 52(4): 641-646, dezembro 2008
larvae remaining in the carcass as well as the insects attached
underneath the carcass, on the soil. No insect characterizes
this stage, but Sarconesia chlorogaster (Wiedemann, 1830)
(Diptera, Calliphoridae) and Muscina stabulans (Diptera,
Muscidae) were present in winter.
Dry Stage. In contact with air, the carcass skin dries
completely due to the incidence of sun rays. Also in this stage,
the internal organs decompose completely. Decomposition
starts to slow down, with a strong decline in the number of
associated species. The skin portions exposed directly to sun
rays become very hard and partially twisted. Diptera do not
oviposit in this stage. We found final instar larvae of D.
maculatus and Oxyletrum discicolle, as well as adults of
Pheidole sp, C. rufipes, N. rufipes, and Gastrisus sp.
Insects of Forensic Importance. Of the 5.239 collected
specimens, 1.827 were obtained from the larvae collected on
the carcass and reared. All specimens were identified and 20
of them have medico-legal (Table I) either because they used
the carcass as rearing site or played an important role in
controlling populations in immature stages. Only Coleoptera
D. maculatus and O. discicolle used the carcass as rearing
sites for their immature; all others use it only for feeding the
adults.
Three patterns were observed that species were indicators
of post-mortem interval (PMI): I. Species found in all seasons,
such as Lucilia eximia, Chrysomya albiceps, Gastrisus sp.,
Euspilotus ?group??azureus sp., Pheidole sp., and
Camponotus rufipes; II. Species found in two seasons, such
as Peckia (Pattonella) resona and Muscina stabulans in
autumn and winter; III. Species found in one season, such as
Hemilucilia semidiaphana and Sarconesia chlorogaster in
winter and Hemilucilia segmentaria, Fannia pusio
(Wiedemann, 1830) (Diptera, Fanniidae), and Synthesiomyia
nudiseta in autumn.
Lucilia eximia and Chrysomya albiceps started visiting
the carcass during the fresh stage. All other species started in
the bloated stage, except in the winter, when Muscina
stabulans appeared during the fresh stage. Among the
Coleoptera species, only Euspilotus ?group??azureus sp.,
Gastrisus sp. and O. discicolle started their visits during the
bloated stage; all others were found from the decaying stage
on. Pheidole sp. remained in the carcasses during all stages.
By observing reared species, we found that Calliphoridae
is firstly seen in the carcass two to four days after the individual
death. Only Hemilucilia semidiaphana was found six
decomposition days, in winter. Larvae of L. eximia were found
in the first days of carcass exposure, whereas larvae of C.
albiceps were found mainly in the last decomposition stages.
Among the Muscidae, larvae of M. stabulans were found two
days after the animal death and the larvae of S. nudiseta were
found three days after the anima death. Third-instar larvae of
Peckia (Pattonella) resona were found approximately four
days after death, in autumn and winter (Table II). The O.
discicolle larvae were first seen nine days after death in autumn
and after 10 in winter; D. maculatus were found after 12 days,
in winter.
Fig. 1. Relation of maximum, minimum and internal temperature (°C) in Spring (A), Summer (B), Autumn (C) and Winter (D).
644 Souza et al.
Revista Brasileira de Entomologia 52(4): 641-646, dezembro 2008
DISCUSSION
The carcass decomposition period in our study differs from
previous research results obtained in Brazil and other countries,
probably because variation in carcass size and environmental
conditions was important for determining process duration.
In Curitiba, the decomposition period of rats weighing
approximately 250g (Moura et al. 1997) was five times shorter
than the period observed in our study, and approximately three
days longer for pigs weighing 10 Kg (Carvalho & Linhares
2001). In India, the decomposition rate of rabbits weighing
1.2kg was lower than the rate we observed (Bharti & Singh
2003) The decomposition period for carcasses of rabbits reared
in the desert was much longer, particularly in the last
decomposition stages (Tantawi et al. 1996).
The findings above support the hypothesis that
communities are affected by local and geographic variations
Campobasso et al. (2001), although it is widely accepted that
bodies decompose more slowly in forest areas (Carvalho &
Linhares 2001).
The necrophagous species collected in our study are very
similar in genus to those collected by Carvalho & Linhares
(2001) in pigs, by Oliveira-Costa et al. (2001) in human corpses,
and by Moura et al. (1997) in rats. Carvalho & Linhares (2001)
collected eight species of Calliphoridae; two of them were
dominant, as also found by other authors such as Oliveira-
Costa et al. (2001), who collected seven species and three of
them were dominant. In this kind of community, one or two
dominant species are commonly found, which suggests that
they should be considered as potential species for the
determination of PMI (Goff et al. 1988).
In our study, L. eximia and C. albiceps did not prefer any
season for visiting the carcass; they alternated their population
peaks and presented an inverse relation. This situation can be
easily observed in the summer, when C. albiceps was collected
in larger numbers and L. eximia was little abundant. This might
be due to the predator role of C. albiceps (Denno & Cothran
1975), thus explaining the asynchronic behavior of the two
species, as they were constant in winter, due to the longer
decomposition period that enhanced the species? coexistence
(Moura 2004).
Hemilucilia semidiaphana and H. segmentaria also were
collected in Curitiba (Moura et al. 1997) and Campinas
(Carvalho & Linhares 2001), the former collected in winter and
the latter in autumn. In our studies, Hemilucilia semidiaphana
and H. segmentaria were collected in the summer and spring.
Sarconesia chlorogaster, an essentially necrophagous species
(Bonatto 1996), was collected only in winter, as also observed
by Moura et al. (1997).
The Sarcophagidae Peckia (Pattonella) resona is very
common in carcass and had been collected by several
Fig. 2. Duration (days) of each experiment in relation to temperature (ºC)
during the four seasons.
Table I. Insects of forensic importance collected in carcass.
Diptera
Coleoptera
Hymenoptera

Calliphoridae
Muscidae
Fanniidae
Sarcophagidae
Dermestidae
Silphidae
Cleridae
Staphylinidae
Histeridae
Formicidae

S, A, W, P
S, W
S, A, W, P
A
W
W
A,W
A
A
A, W
S
S, A, W
A, W
S, A
S, A
S, A, W, P
S, A, W, P
S, A, W, P
S, A, W, P
Lucilia eximia (Wiedmann)
Chrysomya megacephala (Fabricius)
Chrysomya albiceps (Wiedmann)
Hemilucilia segmentaria (Fabricius)
Hemilucilia semidiaphana (Rondani)
Sarconesia chlorogaster (Wiedmann)
Muscina stabulans (Fallén)
Synthesiomyia nudiseta (Wulp)
Fannia pusio (Wiedmann)
Peckia (Pattonella) resona (Lopes)
Sarcophaga (Lyopygia) crassipalpis (Macquart)
Dermestes maculatus (DeGeer)
Oxyletrum discicolle (Brullé)
Necrobia rufipes (De Geer)
Necrobia ruficolis (Fabricius)
Gastrisus sp.
Euspilotus ?group??azureus sp.
Pheidole sp.
Camponotus rufipes (Fabricius)
S: summer; A: autumn; W: winter; P: spring.
645Insects of forensic importance from Rio Grande do Sul state in southern Brazil
Revista Brasileira de Entomologia 52(4): 641-646, dezembro 2008
researchers in Brazil (Moura et al. 1997; Monteiro-Filho &
Peneireiro 1987). The species was collected in autumn and
winter and its larvae, as well as larvae of Calliphoridae were in
found in large numbers and in no competition. The synchronic
carcass exploration by larvae of Sarcophagidae and
Calliphoridae does not necessarily result in competition
because each of these families uses the carcass in a different
way. The Sarcophagidae are ovoviviparous and deposit their
larvae on the carcass, thus feeding themselves immediately.
The Caliphoridae, on the contrary, deposit their eggs. The two
families also differ in development period (Denno & Cothran 1975).
Muscina stabulans and S. nudiseta grow on the carcass in
large numbers and in specific periods. The first occurred only
in autumn and winter, and the second only in winter. Muscina
stabulans had collected on carcass in Brazil by Freire (1923),
and therefore it still had not been characterized as being of
forensic importance, but in Buenos Aires, M. stabulans occurs
on carcasses is considered of forensic importance in Argentina
(Centeno et al. 2002). S. nudiseta has already been collected
in Rio de Janeiro, Brazil, from human corpses (Oliveira-Costa
et al. 2001). Fannia pusio occurred only in autumn and was
collected in Campinas (Carvalho & Linhares 2001), in all
seasons except in autumn.
Among the Coleoptera species, D. maculatus is very
common in the necrophagous fauna (Sousa & Linhares 1997;
Kulshrestha & Sapathy 2001). Authors disagree on the arrival
time of the Dermestidae on carcasses. For Greenberger & Wells
(1998), they reach the cadaver approximately 30 days after
death. Early and Goff (1986) collected adults three or four days
after death. In our study, the species appeared seven to 10
days after death. Oxyletrum discicolle was collected from the
decaying stage on and differing in seasonality. In Curitiba,
Oxyletrum discicolle occurred in all seasons (Moura et al.
1997), differently from observations in the Pelotas region.
Necrobia rufipes and N. ruficolis are very common on
carcasses; the first is used for PMI estimation (Sousa &
Linhares 1997; Kulshrestha & Sapathy 2001). Souza and
Linhares (1997) collected adult and immature individuals, and
in our study, only adults were collected. The other species
have the trophic role as larva predators, which makes possible
the occurrence of Euspilotus ?group??azureus sp. in basically
all decomposition stages and in all seasons. These findings
are supported by Mise et al. (2007) was collected the genus
throughout the year, beginning at the bloated stage. Our data
are similar, except for the autumn and spring, when adults
were found from the fresh stage.
The species of Formicidae collected in our study were also
reported in most studies conducted in Brazil, being considered
omnivores (Monteiro-Filho & Peneireiro 1987; Catts & Haskell
1991; Moura et al. 1997). In spite of these considerations, the
participation of Formicidae species is much more important in
tropical regions (Conarby 1974). We observed that they can
predate eggs, larvae, and pupae of Diptera, thus acting as a
population regulation agent for the fly species population.
Besides the trophic role of the members of this family in
carcasses, the Formicidae are also important because they
leave special marks on the carcass and can also cause lesions
due to the action of formic acid. These marks and lesions can
mislead an expert ass being death marks (Keh 1985).
Acknowledgments. Special thanks for Drs. José Albertino Rafael
(Instituto Nacional de Pesquisas da Amazônia) and Janyra Oliveira da
Costa (Secretaria de Segurança do Rio de Janeiro) for the critical reading,
and Milton Amado (Universidade Federal de Pelotas) for yielding the
rabbits for the experiment, and Paulo Bretanha Ribeiro (Universidade
Federal de Pelotas) for the loan of the Laboratory of Biology of Insects
for rearing of the immatures. To biologist Rodrigo Rickes Azevedo for
the help in the identifications of the Calliphoridae. To Msc. Lisiane
Dilli Wendt (Universidade Federal do Paraná) for the help in the
identifications of the Fanniidae and Msc. Kleber Makoto Mise
(Universidade Federal do Paraná) for the help in the identifications of
the Coleoptera.
REFERENCES
Bharti, M. & D. Singh. 2003. Insect faunal succession on decaying
rabbit carcasses in Punjab, Índia. Journal of Forensic Science
48: 1133?1143.
Table II. Periods of development according to species occurring in rabbit carcass during the year.
Taxon
Lucilia eximia
Chrysomya albiceps
Hemilucilia semidiaphana
Muscina stabulans
Fannia pusio
Synthesiomyia nudiseta
Peckia (Pattonella) resona
Chrysomya megacephala
Hemilucilia segmentaria
Sarconesia chlorogaster
Sarcophaga (Lyopygia) crassipalpis
Total
Season of the year
S, A, W, P
S, A, W, P
W
A, W
A
A
A, W
S, W
A
W
S
N
1145
379
165
46
32
28
22
4
3
2
1
1827
T (ºC)
18.34
17.67
11.33
14.91
16.00
16.23
14.54
16.02
17.60
13.60
20.70
I: number of adults; T: mean temperature; X: mean; I: Instar; SD: standard deviation; S: summer; A: autumn; W: winter; P: spring; L1: first instar;
L2: second instar.
I
L1
L1
L2
L1
L2
L1
L1
L2
L2
L1
L1
X
28.03
10.26
12.41
28.57
23
27.61
25.53
11
13.67
35
24
-
SD
5.92
2.86
2.50
4.33
-
2.08
2.61
0.61
4.07
-
-
-
Development
646 Souza et al.
Revista Brasileira de Entomologia 52(4): 641-646, dezembro 2008
Bonatto, S. R. 1996. Ciclo de vida de Sarconesia chlorogaster
(Wiedmann) (Diptera, Calliphoridae, Toxotarsine), criada sob
condições de laboratório em dieta artificial. Revista Brasileira
de Zoologia 13: 685?706.
Campobasso, C. P.; G. Di Vella & F. Introna. 2001. Factors affecting
decomposition and Diptera colonization. Forensic Science
International 120: 18?27.
Carvalho, L. M. L. & A. X. Linhares. 2001. Seasonality of insects
succession and pig carcass decomposition in a natural forest área in
southearstern Brazil. Journal of Forensic Science 46: 604?
608.
Carvalho, L. M. L.; P. J. Thyssen; M. L Goff & A. X. Linhares. 2004.
Observations on the succesion patterns of necrophagous insects
on a pig carcass in a urban área of southearstern Brazil. Aggrawals
Internet Journal of Forensic Medicine and Toxicology 5:
33?39.
Catts, E. P. & N. H. Haskell. 1991. Entomological and Death: A
procedual guide. Joyce?s Printshop, Clemsom, 182 p, 1991.
Centeno, N.; M. Maldonado & A. Oliva. 2002. Seasonal of arthropods
occuring on sheltered na unsheltered pig carcass in Buenos Aires
province (Argentina). Forensic Science International 126: 63?
70.
Conarby, W. B. 1974. Carrion reduction by animals in constrating
tropical habitats. Biotropica 6: 51?63.
Denno, R. & W. R. Cothran. 1975. Niche relationships of a gulid of
necrophagous flies. Annals of the Entomological Society of
America 68: 741?754.
Early, M. & M. L. Goff . 1986. Arthropod succession patterns in
exposed carrion on the island of O?ahu, Hawaii Islands, USA.
Journal of Medical Entomology 23: 520?831.
Freire, O. 1923. Fauna cadavérica brasileira. Revista Medica 3: 15?
40.
Goff, M. L.; A. L. Omori & K. Gunatilake. 1988. Estimation of
postmortem interval by arthropod succession: three case studies
from the Hawaiian Islands (U.S.A.). American of Journal
Forensic Medical and Pathology 9: 220?225.
Gomes, L. E. & C. J. Von-Zuben. 2004. Dispersão larval radial pós-
alimentar em Lucilia cuprina (Diptera: Calliphoridae):
Profundidade, peso e distância de enterramento para pupação.
Iheringia, Série Zoologia 94: 135?138.
Greenberg, B. & J. D. Wells. 1998. Forensic use of Megaselia abdita
and M. scalaris (Phoridae: Diptera): case studies, development
ratyes, and eggs structure. Journal of Medical Entomology 35:
205?209.
Keh, B. 1985. Scope and applications of forensic entomology. Annual
Review Entomology 30: 137?154.
Kulshrestha, P. & D. K. Sapathy. 2001. Use of beetles in forensic
entomology. Forensic Science International 120: 15?17.
Mise, K. M.; L. M. Almeida & M. O. Moura. 2007. Levantamento da
fauna de Coleoptera que habita a carcaça de Sus scrofa L., em
Curitiba, Paraná. Revista Brasileira de Entomologia 51: 358?
368.
Monteiro-Filho, E. L. A. & J. L. Peneireiro. 1987. Estudo da
decomposição e sucessão sobre uma carcaça animal numa área do
estado de São Paulo, Brasil. Revista Brasileira de Biologia 47:
289?295.
Moura, M. O.; C. J. B. Carvalho & E. L. A. Monteiro-Filho. 1997. A
preleminary analysis of insects of médico-legal importance in
Curitiba, State of Paraná. Memórias do Instituto Oswaldo Cruz
92: 269?274.
Moura, M. O. 2004. Variação espacial como promotor da coexistência
em comunidades de insetos necrófagos. Revista Brasileira de
Zoologia 21: 409?419.
Micozzi, M. S. 1986. Experimental study of post mortem change
under field conditions: Effects of freezing thawning and mechanical
injury. Journal of Forensic Science 31: 953?961.
Oliveira-Costa, J.; C. A. Melo-Patiu & S. M. Lopes. 2001. Dipteros
muscoideos associados com cadáveres humanos no local da morte,
no estado do Rio de Janeiro, Brasil. Boletim do Museu Nacional,
Série Zoologia 470: 1?10.
Oliveira-Costa, J. 2008. Entomologia Forense: Quando os insetos
são vestígios. Editora Millenium, Campinas, 2º ed., 420 p.
Oliveira-Costa, J. & C. A. Mello-Pattiu. 2004. Application of forensic
entomology to estimate of the postmortem interval (PMI) in
homicidae investigations by Rio de Janeiro Police Departament in
Brazil. Aggrawals Internet Journal of Forensic Medicine and
Toxicology 5: 40?44.
Richards, E. N. & M. L. Goff. 1997. Arthropod succession on exposed
carrion in three contrsting tropical habitats on Hawaii Island,
Hawaii. Journal of Medical Entomology 34: 328?339.
Rodriguez, W. C & W. M. Bass. 1983. Insect activity and its relationships
to decay rates of human cadavers in East Tennessee. Journal of
Forensic Science 28: 423?432.
Salviano, R. J. B.; R. P. Mello; R. F. S. Beck & A. Ferreira. 1996.
Calliphoridae (Diptera) associated with human corpses in Rio de
Janeiro, Brazil. Entomologia y Vectores 3: 145?146.
Souza, A. M & A. X. Linhares. 1997. Diptera and Coleoptera of
potential forencic importance in southeastern Brazil: Relative
abundance and seasonality. Medical and Veterinary Entomology
11: 8?12.
Tantawi, T. L.; E. M. El-Kady; B. Greenberg & H. A. El-Ghaffar. 1996.
Arthropod succession on exposed rabbit carrion in Alexandria,
Egypt. Journal of Medical Entomology 33: 566?580.
Weigelt, J. 1989. Recent vertebrate carcasses and their
paleobiological implications. University Chicago Press.
Chicago. 204 p.
Received 03/02/2007; aceito em 22/07/2008
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