about
Fever as an important resource for infectious diseases researchPredicting organismal vulnerability to climate warming: roles of behaviour, physiology and adaptationSeasonal patterns of body temperature daily rhythms in group-living Cape ground squirrels Xerus inaurisAdaptive thermoregulation during summer in two populations of an arid-zone passerine.Temperatures in excess of critical thresholds threaten nestling growth and survival in a rapidly-warming arid savanna: a study of common fiscals.Identifying biologically meaningful hot-weather events using threshold temperatures that affect life-historyA framework for integrating thermal biology into fragmentation research.An efficient and inexpensive method for measuring long-term thermoregulatory behavior.Body temperature patterns and rhythmicity in free-ranging subterranean Damaraland mole-rats, Fukomys damarensis.Direct impacts of climatic warming on heat stress in endothermic species: seabirds as bioindicators of changing thermoregulatory constraints.Environmental challenges and physiological solutions: comparative energetic daily rhythms of field mice populations from different ecosystemsField evidence for a proximate role of food shortage in the regulation of hibernation and daily torpor: a review.When to initiate torpor use? Food availability times the transition to winter phenotype in a tropical heterotherm.Social huddling and physiological thermoregulation are related to melanism in the nocturnal barn owl.Inducing Cold-Sensitivity in the Frigophilic Fly Drosophila montana by RNAiLocomotor Activity and Body Temperature Patterns over a Temperature Gradient in the Highveld Mole-Rat (Cryptomys hottentotus pretoriae).Springs, steroids, and slingshots: the roles of enhancers and constraints in animal movement.A review of the thermal sensitivity of the mechanics of vertebrate skeletal muscle.Heterothermy in large mammals: inevitable or implemented?Thermal requirements for growth, survival and aerobic performance of weatherfish larvae Misgurnus fossilis.Torpor in dark times: patterns of heterothermy are associated with the lunar cycle in a nocturnal bird.The bare head of the Northern bald ibis (Geronticus eremita) fulfills a thermoregulatory function.Seasonal changes in energy expenditure, body temperature and activity patterns in llamas (Lama glama).Individual variation in metabolic reaction norms over ambient temperature causes low correlation between basal and standard metabolic rate.Hibernation patterns of Turkish hamsters: influence of sex and ambient temperature.Thermoregulatory plasticity in free-ranging vervet monkeys, Chlorocebus pygerythrus.Balancing Biomechanical Constraints: Optimal Escape Speeds When There Is a Trade-off between Speed and Maneuverability.Nutritional state reveals complex consequences of risk in a wild predator-prey community.Heterothermy in growing king penguins.Chasing the Patagonian sun: comparative thermal biology of Liolaemus lizards.Broad-scale ecological implications of ectothermy and endothermy in changing environmentsRegional thermal specialisation in a mammal: temperature affects power output of core muscle more than that of peripheral muscle in adult mice (Mus musculus)A global heterothermic continuum in mammalsHeterothermy in two mole-rat species subjected to interacting thermoregulatory challengesVariation in body temperature is related to ambient temperature but not experimental manipulation of insulation in two small endotherms with different thermoregulatory patternsReflection of near-infrared light confers thermal protection in birds
P2860
Q26748091-F357AD57-F8BD-41F0-A852-AC5C0D3701F7Q28730012-EFED4A83-D878-469C-A4E1-10D7A48C057EQ28730304-95468912-A7F8-4208-95A2-C123FC0D0814Q30655515-6D577E5A-8765-4FCC-9471-6C3EE6EA46A5Q30667220-64FC932A-B503-4541-9DF2-28AD3B5D1BF5Q30717810-ECFBECBC-6AE7-405F-9172-A8DDD0FED47EQ31047700-4A9A8737-1AD6-4615-99A4-CBAA67AB81EBQ31120456-FCA11F02-9E02-4DA8-B8FA-3EA9C7FEC88AQ34058541-A207CABF-8CFD-4176-9353-774680C5621BQ34301168-E94A9DEB-2F66-481C-92F8-C0FE56826D38Q34516301-715B6E77-0938-403D-A5DD-18385AA512B1Q35172292-30D5B020-C0A9-4746-8F86-ED8A0C111538Q35624760-88B2DE75-AC53-4B5B-822F-FA2911A0EF11Q35836309-A0184E1F-4E19-452C-A0B2-BC4EF59EE835Q36188641-F810AD07-1195-49D5-B059-6A0FE2153823Q36245508-5480FF56-7D2C-472F-90D6-53F7190515D6Q38071938-92029DA5-3E0D-442B-B5C5-683C51326DDCQ38088662-387737DB-A9F6-4E5E-8F2F-9B8371B9B139Q38293212-0880C200-DB74-45AB-A2FB-10A0F11EC8D4Q38405940-84301261-8ECB-4865-8AE5-303822080BF4Q38473702-F15F984C-1C15-48AF-881E-4F072E7912BFQ39164606-8CF6ADB9-BD76-46C3-851C-FB3ADD3874D4Q41310108-02AB23C3-9E58-44D6-969F-DD89A0B581E7Q42512029-BF9E7FDD-353C-4CA1-BCD3-E529040EA912Q44745997-17F497C5-4EC8-4150-8A4F-7C10198B2DC3Q46460060-FF9322DD-94D9-461F-AE3F-75218B4F53D4Q50564674-872EB323-7C15-4471-97B9-B6E09935F140Q51192808-AAC1CB14-DE18-4805-86B5-CBD7FD67B59AQ51369438-8E78D1E6-206F-4EAA-A03E-BE7642D613B0Q51549583-A2EB3612-D613-45DE-9368-AB75BE3A6456Q56985373-04839276-0313-4D13-B9D2-3332076569BEQ57577863-9AE46C5B-82BD-4C09-BC5B-529F3CA8997FQ57653297-24F4C142-4C9A-409F-8404-D38A4A637813Q57653309-EB80495F-2532-4CB2-BADE-BB04BDD67744Q57653314-6C706E37-35A3-457D-936E-43E3252B98C6Q58761878-2F1ADB73-520A-49E5-B4CF-F7A5F54A6512
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on June 2010
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
The evolution of thermal physiology in endotherms.
@en
The evolution of thermal physiology in endotherms.
@nl
type
label
The evolution of thermal physiology in endotherms.
@en
The evolution of thermal physiology in endotherms.
@nl
prefLabel
The evolution of thermal physiology in endotherms.
@en
The evolution of thermal physiology in endotherms.
@nl
P2093
P356
P1476
The evolution of thermal physiology in endotherms.
@en
P2093
Brandon S Cooper
Justin G Boyles
Matthew S Schuler
Michael J Angilletta
P304
P356
10.2741/E148
P577
2010-06-01T00:00:00Z