Infrared video thermography: a technique for assessing cold adaptation in insects
Insects can survive subzero temperatures by two main strategies: freeze tolerance and freeze avoidance. An array of techniques have been used to investigate the physiological limits of insects to low temperatures, such as differential scanning calorimetry, temperature-controlled cooling apparatus, t...
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ftanucanberra:oai:openresearch-repository.anu.edu.au:1885/77510 2024-01-14T10:11:12+01:00 Infrared video thermography: a technique for assessing cold adaptation in insects Palmer, Christopher Siebke, Katharina Yeates, David http://hdl.handle.net/1885/77510 unknown Eaton Publishing Co 0736-6205 http://hdl.handle.net/1885/77510 BioTechniques Keywords: Cooling Differential scanning calorimetry Freezing Insect control Thermography (imaging) Free tolerance Infrared video thermography Biotechnology alpine tundra article behavior cold acclimatization cooling environment hemolymph imaging syst Journal article ftanucanberra 2023-12-15T09:38:51Z Insects can survive subzero temperatures by two main strategies: freeze tolerance and freeze avoidance. An array of techniques have been used to investigate the physiological limits of insects to low temperatures, such as differential scanning calorimetry, temperature-controlled cooling apparatus, thermocouples, and computer-controlled chart recording equipment. However, these techniques require animals to be stationary, precluding behavioral data. We used infrared video thermography to investigate cold adaptation in an alpine insect, expanding such investigations to include behavioral response as an indicator of physiological stress. This technique is noninvasive and provides a large amount of physiological information, such as supercooling points, lower lethal temperatures, and hemolymph melting points. Insect supercooling points in response to a constant cooling rate were variable; however, temperatures at the initiation of behavioral stress response were less variable. Assessments of supercooling points and lower lethal temperatures obtained in this way are more biologically meaningful because allowing unhindered movement of insects more closely resembles natural environments. Article in Journal/Newspaper Tundra Australian National University: ANU Digital Collections |
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Open Polar |
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Australian National University: ANU Digital Collections |
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ftanucanberra |
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unknown |
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Keywords: Cooling Differential scanning calorimetry Freezing Insect control Thermography (imaging) Free tolerance Infrared video thermography Biotechnology alpine tundra article behavior cold acclimatization cooling environment hemolymph imaging syst |
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Keywords: Cooling Differential scanning calorimetry Freezing Insect control Thermography (imaging) Free tolerance Infrared video thermography Biotechnology alpine tundra article behavior cold acclimatization cooling environment hemolymph imaging syst Palmer, Christopher Siebke, Katharina Yeates, David Infrared video thermography: a technique for assessing cold adaptation in insects |
| topic_facet |
Keywords: Cooling Differential scanning calorimetry Freezing Insect control Thermography (imaging) Free tolerance Infrared video thermography Biotechnology alpine tundra article behavior cold acclimatization cooling environment hemolymph imaging syst |
| description |
Insects can survive subzero temperatures by two main strategies: freeze tolerance and freeze avoidance. An array of techniques have been used to investigate the physiological limits of insects to low temperatures, such as differential scanning calorimetry, temperature-controlled cooling apparatus, thermocouples, and computer-controlled chart recording equipment. However, these techniques require animals to be stationary, precluding behavioral data. We used infrared video thermography to investigate cold adaptation in an alpine insect, expanding such investigations to include behavioral response as an indicator of physiological stress. This technique is noninvasive and provides a large amount of physiological information, such as supercooling points, lower lethal temperatures, and hemolymph melting points. Insect supercooling points in response to a constant cooling rate were variable; however, temperatures at the initiation of behavioral stress response were less variable. Assessments of supercooling points and lower lethal temperatures obtained in this way are more biologically meaningful because allowing unhindered movement of insects more closely resembles natural environments. |
| format |
Article in Journal/Newspaper |
| author |
Palmer, Christopher Siebke, Katharina Yeates, David |
| author_facet |
Palmer, Christopher Siebke, Katharina Yeates, David |
| author_sort |
Palmer, Christopher |
| title |
Infrared video thermography: a technique for assessing cold adaptation in insects |
| title_short |
Infrared video thermography: a technique for assessing cold adaptation in insects |
| title_full |
Infrared video thermography: a technique for assessing cold adaptation in insects |
| title_fullStr |
Infrared video thermography: a technique for assessing cold adaptation in insects |
| title_full_unstemmed |
Infrared video thermography: a technique for assessing cold adaptation in insects |
| title_sort |
infrared video thermography: a technique for assessing cold adaptation in insects |
| publisher |
Eaton Publishing Co |
| url |
http://hdl.handle.net/1885/77510 |
| genre |
Tundra |
| genre_facet |
Tundra |
| op_source |
BioTechniques |
| op_relation |
0736-6205 http://hdl.handle.net/1885/77510 |
| _version_ |
1788066093679509504 |