David S. Hinds scite author profile

Allometric equations can be useful in comparative physiology in a number of ways, not the least of which include assessing whether a particular species deviates from the norm for its size and phylogenetic group with respect to some specific physiological process or determining how differences in design among groups may be reflected in differences in function. The allometric equations for respiratory variables in birds were developed 30 yr ago by Lasiewski and Calder and presented as "preliminary" because they were based on a small number of species. With the expanded data base now available to reconstruct these allometries and the call for taking account of the nonindependence of species in this process through a phylogenetically independent contrasts (PIC) approach, we have developed new allometric equations for respiratory variables in birds using both the traditional and PIC approaches. On the whole, the new equations agree with the old ones with only minor changes in the coefficients, and the primary difference between the traditional and PIC approaches is in the broader confidence intervals given by the latter. We confirm the lower VE/VO2 ratio for birds compared to mammals and observe a common scaling of inspiratory flow and oxygen consumption for birds as has been reported for mammals. Use of allometrics and comparisons among avian groups are also discussed.

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Water Regulatory Efficiency in Heteromyid Rodents: A Model and Its Application

MacMillen

Hinds

1983

Ecology

114

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We have developed and tested a model of water regulatory efficiency for the rodent family Heteromyidae. The model is based on the premise that granivory coupled with increasing aridity and seasonality of rainfall has been the major theme throughout the evolutionary history of the family; it states further that water regulatory efficiency is negatively correlated with body mass in the family, and that member species are largely dependent upon a common resource packet (seeds) to meet both energy and water needs. A test of the model with five genera and 13 species revealed positive results across the entire family, but the two most speciose genera, Perognathus and Dipodomys, showed seemingly conflicting patterns; the smaller (in mass) genus, Perognathus, conformed strongly to the model, while in Dipodomys water regulatory efficiency was fixed at a level equivalent to that of the largest Perognathus spp. (°35—40 g). At this mass in these genera, in addition, occurs the demarcation between strict quadrupedality (Perognathus) and bipedality (Dipodomys), a strict scaling of cheek pouch volume with mass in Perognathus but independence of mass in Dipodomys, and the common use of torpor in Perognathus, with its near absence in Dipodomys. We interpret our findings to indicate that initially selection favored a decrease in mass with a concomitant increase in water regulatory efficiency and reduction in absolute energy need in heteromyids, tracking progressive aridity during the Tertiary. In Dipodomys, the option of bipedality was adopted, apparently freeing them from energetic constraints imposed strictly by mass, coupled with an intermediate and fixed level of water regulatory efficiency that dictates use of seeds with high metabolic water yields. The quadrupedal Perognathus have retained a mass—specific water regulatory efficiency, ensuring maintenance of both water and energy balance on a broad array (with respect to protein: lipid: carbohydrate and metabolic water yield) of seeds, when their more—limited locomotor powers are consistent with seed availability; torpor is the tradeoff, enhancing survival during energetically demanding periods.

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Tracheal Dead Space in the Respiration of Birds

Hinds¹,

Calder²

1971

Evolution

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Scaling of Energy Metabolism and Evaporative Water Loss in Heteromyid Rodents

Hinds¹,

MacMillen²

1985

Physiological Zoology

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Water Regulatory Efficiency in Heteromyid Rodents: Model and Its Application

MacMillen¹,

Hinds²

1984

Ecology

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David S. Hinds

Scaling of Respiratory Variables and the Breathing Pattern in Birds: An Allometric and Phylogenetic Approach

Water Regulatory Efficiency in Heteromyid Rodents: A Model and Its Application

Tracheal Dead Space in the Respiration of Birds

Scaling of Energy Metabolism and Evaporative Water Loss in Heteromyid Rodents

Water Regulatory Efficiency in Heteromyid Rodents: Model and Its Application

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