GaughanJB. Which physiological adaptation allows camels to tolerate high heat load – and what more can we learn?J Camelid Sci (2011;4, 85–8.
2.
Cain IIIJW, KrausmanPR, RosenstockSS, TurnerJC. Mechanisms of thermoregulation and water balance of desert ungulates. Wildlife Society Bulletin. 2006;34, 570–81.
3.
YousefMK, DillDB, MayesMG. Shifts in body fluids during dehydration in the burro, Equus asinus. J Appl Physiol. 1970;29, 345–9.
4.
Schmidt-NielsenK, CrawfordEC, NewsomeAE, RawsonKS, HammelHT. Metabolic rate of camels: Effect of body temperature and dehydration. Am J Physiol. 1967;212, 341–6.
5.
ElkhawadAO. Selective brain cooling in desert animals: The camel (Camelus dromedarius). Comp Biochem Physiol. 101A. 1992)195–201.
6.
BouaoudaH, AchaabanMR, OuassatM, OukassouM, PiroM, ChalletE, El AllaliK, PevetP. Daily regulation of body temperature rhythm in the camel (Camelus dromedarius) exposed to experimental desert conditions. Physiol Reports. 2014;2, e12151.
7.
WardaM, PrinceA, KimHK, KhafagaN, ScholkamyT, LinhardtRJ, JinH. Proteomics of old world camelid (Camelus dromedarius): Better understanding the interplay between homeostasis and desert environment. J Adv Res. 2014;5, 219–42.
8.
HetemRS, StraussWA, FickLG, MaloneySK, MeyerLCR, ShobrakM, FullerA, MitchellD. Variation in the daily rhythm of body temperature of free-living Arabian oryx (Oryx leucoryx): Does water limitation drive heterothermy?J Comp Pathol (2010;180, 1111–9.
9.
MaloneySH, FullerA, MitchellG, MitchellD. Brain and arterial blood temperatures of free-ranging oryx (Oryx gazelle). Pflugers Arch. 2002;443, 437–45.
MartiniJ, CarpentierB, Chavez NegreteA, CabralesP, TsaiAG, IntagliettaM. Beneficial effects due to increased blood and plasma viscosity. Clin Hemorheol Microcirc. 2006;35, 51–7.
12.
BertugliaS. Increased viscosity is protective for arteriolar endothelium and microvascular perfusion during severe hemodilution in hamster cheek pouch. Microvasc Res. 2000;61, 56–63.
13.
DietrichHH, EllsworthML, SpragueRS. Red blood cell regulation of microvascular tone through adenosine triphosphate. Am J Physiol. 2000;278, H1294–8.
14.
PöschlCH. Die Vollblutviskosität in Abhängigkeit von Hämatokrit und Temperatur. Thesis Medical University Vienna2015.
ChebbiR. Dynamics of blood flow: Modeling of the Fahraeus-Lindqvist effect. J Biol Phys. 2015;41, 313–26.
17.
StoiberB, ZachC, IzayB, WindbergerU. Whole blood, plasma viscosity, and erythrocyte aggregation as a determining factor of competitiveness in standard bred trotters. Clin Hemorheol Microcirc. 2005;32, 31–41.
18.
AuerR, GleissA, WindbergerU. Towards a basic understanding of the properties of camel blood in response to exercise. Emir J Food Agric. 2015;27, 302–11.
19.
LuoZY, BaiBF. Dynamics of biconcave vesicles in a confined shear flow. Chem Engineering Sci. 2005;137, 548–55.
20.
OmorphosSA, HawkeyCM, Rice-EvansC. The elliptocyte: A study of the relationship between cell shape and membrane structure using the camelid erythrocyte as a model. Comp Biochem Physiol. 94B. 1989)789–95.
21.
WardaM, ZeisigR. Phospholipid- and fatty acid-composition in the erythrocyte membrane of the one-humped camel and its influence on vesicle properties prepared from these lipids. Dtsch Tieraerztl Wschr. 2000;107, 349–88.
22.
Al-QuarawiAA, MousaHM. Lipid concentrations in erythrocyte membranes in normal, starved, dehydrated and rehydrated camels (Camelus dromedarius), and in normal sheep (Ovis aries) and goats (Capra hircus). J Arid Environ. 2004;59, 675–83.
23.
EitanA, AloniB, LivneA. Unique properties of the camel erythrocyte membrane II. Organisation of membrane proteins. Biochim Biophys Acta. 1976;426, 647–58.
24.
McPhersonRA, SawyerWH, TilleyL. Band 3 mobility in camelid elliptocytes: Implications for erythrocyte shape, Biochemistry (1993;32, 6696–702.
25.
RalstonGB. Protein components of the camel erythrocyte membrane. Biochim Biophys Acta. 1975;401, 83–94.
26.
WaughRE. Red cell deformability in different vertebrate animals. Clin Hemorheol. 1992;12, 649–56.
27.
KhodadadJK, WeinsteinRS. The band 3-rich membrane of Ilama erythrocytes: Studies on cell shape and the organisation of membrane proteins. J Membrane Biol. 1983;72, 161–71.
28.
WaughRE, EvansEA. Thermoelasticity of red blood cell membrane. Biophys J. 1979;26, 115–32.
29.
HochmuthR. Properties of red blood cells. In: SkalakR & ChienS, editors. Chapt.12 1987)12–McGraw-Hill Book ComHandbook of Bioengineering New York.
30.
ElsnerR, MeiselmanHJ, BaskurtOK. Temperature-viscosity relations of bowhead whale blood: A possible mechanism for maintaining cold blood flow. Marine Mammal Science. 2004;20, 339–44.
31.
GuardCL, MurrishDE. Effects of temperature on the viscous behavior of blood from antarctic birds and mammals. Comp Biochem Physiol. 52A. 1975)287–90.
32.
FullerA, MossDG, SkinnerJD, JessenPT, MitchellG, MitchellD. Brain, abdominal, and arterial temperatures of free-ranging eland in their natural habitat. Pflugers Arch. 1999;438, 671–80.
33.
PreziosiV, TomaiuoloG, FeniziaM, CasertaS, GuidoS. Confined tube flow of low viscosity emulsions: Effect of matrix elasticity. J Rheology. 2016;60, 419–32.
34.
OuajdS, KamelB. Physiological particularities of dromedary (Camelus dromedarius) and experimental implications (2009;36, 19–29.
35.
Tran-Son-TayR, SuteraSP, RaoPR. Determination of red blood cell membrane viscosity from rheoscopic observations of tank-threading motion. Biophys J. 1984;46, 65–72.
36.
NashGB, MeiselmanHJ. Red cell and ghost viscoelasticity. Biophys J. 1983;43, 63–73.
37.
BaskurtOK, MeiselmanHJ. Analyzing shear stress-elongation index curves: Comparison of two approaches to simplify data presentation. Clin Hemorheol Microcirc. 2004;31, 23–30.
38.
JohnnH, PhippsC, GascoyneS, HawkeyC, RamplingMW. A comparison of the viscometric properties of the blood from a wide range of mammals. Clin Hemorheol Microcirc. 1992;12, 639–47.
39.
HawkeyCM, HartMG. Age-related changes in the blood count of the scimitar-horned oryx (Oryx tao). J Zoo Anim Med. 1984;15, 157–60.
40.
SaaedA, HusseinMM. Change in normal haematological values of camels (Camelus dromedaries): Influence of age and sex. Comp Clin Pathol. 2008;17, 263–6.
41.
WindbergerU, BartholovitschA, PlasenzottiR, KorakKJ, HeinzeG. Whole blood viscosity, plasma viscosity and erythrocyte aggregation in nine mammalian species: Reference values and comparison of data. Exp Physiol. 88. 2003;3, 431–40.
42.
SchmeidlK. Hämorheologische Eigenschaften des afrikanischen Nguni-Rindes und der Vergleich zum österreichischen Fleckvieh. Thesis, Veterinary University Vienna, Austria2010.
43.
PopelAS, JohnsonPC, KamenevaMV, WildMA. Capacity for red blood cell aggregation is higher in athletic mammalian species than in sedentary species. J Appl Physiol. 1994;77, 1790–4.
44.
GrintN, DugdaleA. Brightness of venous blood in South American camelids: Implications for jugular catheterization. Vet Anaesth Analg. 2009;36, 63–6.
45.
WindbergerU, BaskurtOK. Comparative hemorheology. In: BaskurtOK, HardemanMR, MeiselmanHJ editors 2007–IOS pressHandbook of Hemorheology and Hemodynamics, Amsterdam.
46.
PlasenzottiR, StoiberB, PoschM, WindbergerU. Red blood cell deformability and aggregation behaviour in different animal species. Clin Hemorheol Microcirc. 2004;31, 105–11.
VassartM, GrethA. Hematological and serum chemistry values for Arabian oryx (Oryx leucoryx). J Wildlife Diseases. 1991;27, 506–8.
49.
HusseinMF, Al-jumaahRS, HomeidaA, AlhaidaryAA, AlshaikhMA, GarelnabiA, MohamedO, OmerS. Hemostatic profile, platelets, and blood constituents of the Arabian oryx (Oryx leucoryx). Comp Clin Pathol. 2010;19, 585–91.
50.
WeberRE, VoelterW, FagoA, EchnerH, CampanellaE, LowPS. Modulation of red cell glycolysis: Interaction between vertebrate hemoglobins and cytoplasmic domains of band 3 red cell membrane proteins. Am J Physiol. 2004;287, R454–64.
51.
Schmidt-NielsenK. Desert animals: Physiological problems of heat and water1979–Dover pressNew York.
52.
YamaguchiK, JurgensKD, BartelsH, PiiperJ. Oxygen transfer properties and dimensions of red blood cells in high-altitude camelids, dromedary camel and goat. J Comp Physiol. 1987;157, 1–9.
53.
VapL, BohnAA. Hematology of camelids. Vet Clin Exot Anim. 2015;18, 41–9.
54.
RossPD, MintonAP. Hard quasispherical model for the viscosity of hemoglobin solutions. Biochem Biophys Res Comm. 1977;76, 971–6.
55.
YagilR, Sod-Moriah, MeyersteinN. Dehydration and camel bloodII. Shape, size, and concentration of red blood cells. Am J Physiol. 1974;226, 301–4.
56.
BengaGh, GrieveSM, ChapmanBE, GallagherCH, KuchelPW. Comparative NMR studies of diffusional water permeability of red blood cells from different species. X. Camel (Camelus dromedarius) and Alpaca (Lama pacos). Comp Clin Pathol. 1999;9, 43–8.
57.
AbdoMS, AliAM, PrentisPF. Fine structure of camel erythrocytes in relation to its functions. Zschr Mikr Anat Forsch. 1990;104, 440–8.
58.
WilsonRT. Ecophysiology of the camelidae and desert ruminants1989–SpringerBerlin, Heidelberg.
59.
CabelM, MeiselmanHJ, PopelAS, JohnsonPC. Contribution of red blood cell aggregation to venous vascular resistance in skeletal muscle. Am J Physiol. 1997;272, H1020–32.
60.
YalcinO, UyukluM, ArmstrongJK, MeiselmanHJ, BaskurtOK. Graded alterations of RBC aggregation influence in vivo blood flow resistance. Am J Physiol. 2004;287, H2644–50.
