PT - JOURNAL ARTICLE
AU - Andrés Escala
TI - Universal Ontogenetic Growth without Fitted Parameters: Implications for Life History Invariants & Population Growth
AID - 10.1101/2021.10.10.463814
DP - 2022 Jan 01
TA - bioRxiv
PG - 2021.10.10.463814
4099 - http://biorxiv.org/content/early/2022/06/28/2021.10.10.463814.short
4100 - http://biorxiv.org/content/early/2022/06/28/2021.10.10.463814.full
AB - Since the work of Von Bertalanffy (1957), several models have been proposed that relate the ontogenetic scaling of energy assimilation and metabolism to growth, which are able to describe ontogenetic growth trajectories for living organisms and collapse them onto a single universal curve (West et al. 2001; Barnavar et al. 2002). Nevertheless, all these ontogenetic growth models critically depend on fitting parameters and on the allometric scaling of the metabolic rate. Using a new metabolic rate relation (Escala 2019) applied to a Bertalanffy-type ontogenetic growth equation, we find that ontogenetic growth can also be described by a universal growth curve for all studied species, but without the aid of any fitting parameters (i.e., no fitting procedure is performed on individual growth curves). We find that the inverse of the heart frequency fH, rescaled by the ratio of the specific energies for biomass creation and metabolism, defines the characteristic timescale for ontogenetic growth. Moreover, our model also predicts a generation time and lifespan that explain the origin of several ‘Life History Invariants’ (Charnov 1993) and predict that the Malthusian parameter should be inversely proportional to both the generation time and lifespan, in agreement with the data in the literature (Duncan et al. 1997; Dillingham et. al 2016; Hatton et al 2019). In our formalism, several critical timescales and rates (lifespan, generation time and intrinsic population growth rate) are all proportional to the heart frequency fH, and thus, their allometric scaling relations come directly from the allometry of the heart frequency, which is typically fH ∝ M−0.25 under basal conditions.Competing Interest StatementThe authors have declared no competing interest.