Use of computed tomography and radiation therapy planning software to develop a novel formula for body surface area calculation in dogs

Renee Girens; Alex Bukoski; Charles A. Maitz; Sarah E. Boston; Antonella Borgatti; Megan Sprinkle; Daniel Orrego; Shannon Kesl; Kim Selting

doi:10.1111/jvim.15440

Use of computed tomography and radiation therapy planning software to develop a novel formula for body surface area calculation in dogs

Renee Girens, Alex Bukoski, Charles A. Maitz, Sarah E. Boston, Antonella Borgatti, Megan Sprinkle, Daniel Orrego, Shannon Kesl, Kim Selting

Veterinary Clinical Sciences

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Background: Body surface area (BSA) can reflect metabolic rate that might normalize dosing of chemotherapeutics across widely variable weights within a species. The current BSA formula for dogs lacks height, length, and body condition. Hypothesis: Computed tomography (CT) imaging will allow inclusion of morphometric variables in allometric modeling of BSA in dogs resulting in an improved formula for BSA estimation. Animals: Forty-eight dogs from 4 institutions with whole-body CT images. Methods: Retrospective and prospective case series. Body surface area was contoured using whole-body CT scans and radiation therapy planning software. Body length and height were determined from CT images and also in 9 dogs by physical measurement. Nonlinear regression was used to model the BSA data sets using allometric equations. Goodness-of-fit criteria included average relative deviation, mean standard error, Akaike information criterion, and r ² (derived from the r-value generated by regression models). Results: Contoured BSA differed from the current formula by −9% to +19%. Nonlinear regression on untransformed data yielded BSA = 0.0134 × body weight [kg] ^∧ 0.4746 × length (cm) ^∧ 0.6393 as the best-fit model. Heteroscedasticity (increasing morphometric variability with increasing BSA) was an important finding. Conclusions and Clinical Importance: Computed tomography-derived BSA was used to incorporate body length into a novel BSA formula. This formula can be applied prospectively to determine whether it correlates with adverse events attributed to chemotherapy.

Original language	English (US)
Pages (from-to)	792-799
Number of pages	8
Journal	Journal of veterinary internal medicine
Volume	33
Issue number	2
DOIs	https://doi.org/10.1111/jvim.15440
State	Published - Mar 1 2019

Bibliographical note

Funding Information:
The authors gratefully acknowledge generous support from the Angiosarcoma Awareness Foundation and donations to the Animal Cancer Care and Research Program of the University of Minnesota that helped support this project.

Funding Information:
Merial, a Sanofi company; IDEXX BioResearch; Angiosarcoma Awareness Foundation; Animal Cancer Care and Research Program of the University of Minnesota; Masonic Cancer Center, University of Minnesota Sarcoma Translational Working Group; National Insititues of Health, Office of the Director, Grant/Award Number: K01OD017242; Masonic Cancer Center, University of Minnesota; National Canine Cancer Foundation, Grant/Award Number: AB15MN-002

Publisher Copyright:
© 2019 The Authors. Journal of Veterinary Internal Medicine published by Wiley Periodicals, Inc. on behalf of the American College of Veterinary Internal Medicine.

Keywords

allometric
calculation
chemotherapy
metabolism
morphometry
oncology

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title = "Use of computed tomography and radiation therapy planning software to develop a novel formula for body surface area calculation in dogs",

abstract = " Background: Body surface area (BSA) can reflect metabolic rate that might normalize dosing of chemotherapeutics across widely variable weights within a species. The current BSA formula for dogs lacks height, length, and body condition. Hypothesis: Computed tomography (CT) imaging will allow inclusion of morphometric variables in allometric modeling of BSA in dogs resulting in an improved formula for BSA estimation. Animals: Forty-eight dogs from 4 institutions with whole-body CT images. Methods: Retrospective and prospective case series. Body surface area was contoured using whole-body CT scans and radiation therapy planning software. Body length and height were determined from CT images and also in 9 dogs by physical measurement. Nonlinear regression was used to model the BSA data sets using allometric equations. Goodness-of-fit criteria included average relative deviation, mean standard error, Akaike information criterion, and r 2 (derived from the r-value generated by regression models). Results: Contoured BSA differed from the current formula by −9% to +19%. Nonlinear regression on untransformed data yielded BSA = 0.0134 × body weight [kg] ∧ 0.4746 × length (cm) ∧ 0.6393 as the best-fit model. Heteroscedasticity (increasing morphometric variability with increasing BSA) was an important finding. Conclusions and Clinical Importance: Computed tomography-derived BSA was used to incorporate body length into a novel BSA formula. This formula can be applied prospectively to determine whether it correlates with adverse events attributed to chemotherapy.",

keywords = "allometric, calculation, chemotherapy, metabolism, morphometry, oncology",

author = "Renee Girens and Alex Bukoski and Maitz, {Charles A.} and Boston, {Sarah E.} and Antonella Borgatti and Megan Sprinkle and Daniel Orrego and Shannon Kesl and Kim Selting",

note = "Funding Information: The authors gratefully acknowledge generous support from the Angiosarcoma Awareness Foundation and donations to the Animal Cancer Care and Research Program of the University of Minnesota that helped support this project. Funding Information: Merial, a Sanofi company; IDEXX BioResearch; Angiosarcoma Awareness Foundation; Animal Cancer Care and Research Program of the University of Minnesota; Masonic Cancer Center, University of Minnesota Sarcoma Translational Working Group; National Insititues of Health, Office of the Director, Grant/Award Number: K01OD017242; Masonic Cancer Center, University of Minnesota; National Canine Cancer Foundation, Grant/Award Number: AB15MN-002 Publisher Copyright: {\textcopyright} 2019 The Authors. Journal of Veterinary Internal Medicine published by Wiley Periodicals, Inc. on behalf of the American College of Veterinary Internal Medicine.",

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AU - Boston, Sarah E.

AU - Borgatti, Antonella

AU - Sprinkle, Megan

AU - Orrego, Daniel

AU - Kesl, Shannon

AU - Selting, Kim

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N2 - Background: Body surface area (BSA) can reflect metabolic rate that might normalize dosing of chemotherapeutics across widely variable weights within a species. The current BSA formula for dogs lacks height, length, and body condition. Hypothesis: Computed tomography (CT) imaging will allow inclusion of morphometric variables in allometric modeling of BSA in dogs resulting in an improved formula for BSA estimation. Animals: Forty-eight dogs from 4 institutions with whole-body CT images. Methods: Retrospective and prospective case series. Body surface area was contoured using whole-body CT scans and radiation therapy planning software. Body length and height were determined from CT images and also in 9 dogs by physical measurement. Nonlinear regression was used to model the BSA data sets using allometric equations. Goodness-of-fit criteria included average relative deviation, mean standard error, Akaike information criterion, and r 2 (derived from the r-value generated by regression models). Results: Contoured BSA differed from the current formula by −9% to +19%. Nonlinear regression on untransformed data yielded BSA = 0.0134 × body weight [kg] ∧ 0.4746 × length (cm) ∧ 0.6393 as the best-fit model. Heteroscedasticity (increasing morphometric variability with increasing BSA) was an important finding. Conclusions and Clinical Importance: Computed tomography-derived BSA was used to incorporate body length into a novel BSA formula. This formula can be applied prospectively to determine whether it correlates with adverse events attributed to chemotherapy.

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Use of computed tomography and radiation therapy planning software to develop a novel formula for body surface area calculation in dogs

Abstract

Bibliographical note

Keywords

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