Effect of massing on larval growth rate.

Citation data:

Forensic science international, ISSN: 1872-6283, Vol: 241, Page: 141-9

Publication Year:
2014
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Citations 14
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Repository URL:
https://ro.uow.edu.au/smhpapers/2433
PMID:
24972255
DOI:
10.1016/j.forsciint.2014.05.006
Author(s):
Johnson, Aidan P; Wallman, James F
Publisher(s):
Elsevier BV
Tags:
Medicine; Mass volume; Maggot massing; Growth rate; Chrysomya rufifacies; Calliphora vicina; Postmortem interval; Medicine and Health Sciences; Social and Behavioral Sciences
article description
Estimation of minimum postmortem interval commonly relies on predicting the age of blowfly larvae based on their size and an estimate of the temperatures to which they have been exposed throughout their development. The majority of larval growth rate data have been developed using small larval masses in order to avoid excess heat generation. The current study collected growth rate data for larvae at different mass volumes, and assessed the temperature production of these masses, for two forensically important blow fly species, Chrysomya rufifacies and Calliphora vicina. The growth rate of larvae in a small mass, exposed to the higher temperatures equivalent to those experienced by large masses, was also assessed to determine if observed differences were due to the known temperature effects of maggot masses. The results showed that temperature production increased with increasing mass volume, with temperature increases of 11 °C observed in the large Ch. rufifacies masses and increases of 5 °C in the large C. vicina masses. Similarly, the growth rate of the larvae was affected by mass size. The larvae from small masses grown at the higher temperatures experienced by large masses displayed an initial delay in growth, but then grew at a similar rate to those larvae at a constant 23 °C. Since these larvae from masses of equivalent sizes displayed similar patterns of growth rate, despite differing temperatures, and these growth rates differed from larger masses exposed to the same temperatures, it can be concluded that larval growth rate within a mass may be affected by additional factors other than temperature. Overall, this study highlights the importance of understanding the role of massing in larval development and provides initial developmental data for mass sizes of two forensically important blowfly species commonly encountered in Australian forensic casework.