Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise

Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise

Exercise-related physiological changes were evaluated in hydrated, exercise-conditioned working dogs with free access to tap water (TW) with or without a nutrient-enriched water supplement (NW). Physiological samples and measures were collected before and after work-related field tasks in a warm and...

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Bibliographic Details
Main Authors: Brian M. Zanghi, Patrick J. Robbins, Meghan T. Ramos, Cynthia M. Otto
Format: Article
Language:English
Published: Frontiers Media S.A. 2018-08-01
Series:Frontiers in Veterinary Science
Subjects:
working dog
hydration
core body temperature
brain temperature
drinking
ear temperature
Online Access:https://www.frontiersin.org/article/10.3389/fvets.2018.00202/full
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spelling doaj-d7291c4dcb1f4a5088da5ea54bb39a1e2020-11-24T23:46:17ZengFrontiers Media S.A.Frontiers in Veterinary Science2297-17692018-08-01510.3389/fvets.2018.00202395008Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After ExerciseBrian M. Zanghi0Patrick J. Robbins1Meghan T. Ramos2Cynthia M. Otto3Nestlé Purina Research, St. Louis, MO, United StatesPenn Vet Working Dog Center, University of Pennsylvania School of Veterinary Medicine, Philadelphia, PA, United StatesPenn Vet Working Dog Center, University of Pennsylvania School of Veterinary Medicine, Philadelphia, PA, United StatesPenn Vet Working Dog Center, University of Pennsylvania School of Veterinary Medicine, Philadelphia, PA, United StatesExercise-related physiological changes were evaluated in hydrated, exercise-conditioned working dogs with free access to tap water (TW) with or without a nutrient-enriched water supplement (NW). Physiological samples and measures were collected before and after work-related field tasks in a warm and moderately humid ambient environment. In a cross-over design study, 12 dogs (age range 8–23 months) were evaluated on 3 separate occasions within each period with exercise bouts up to 30 min, on days −4, 3, and 11. Dogs were offered either ad libitum TW or portion-controlled NW daily plus ad libitum TW. Prior to and serially after exercise, pulse rate (PR), core (BTcore) and ear (BTear) temperature were recorded. Urine was collected first thing in the morning, whereas blood samples collected and body weight (BW) recorded pre- and immediately post exercise. Ambient temperature was above 21.7°C (71°F) and relative humidity ranged from 36 to 76%. Activity parameters, AM urine measures, post-exercise percent change of BW, resting PR and resting BTcore did not differ between treatment groups on any exercise day. At the completion of exercise, mean BTcore for all dogs ranged from 104.8 to 105.6°F. Immediate post-exercise BTear was always lower compared to BTcore and means ranged from 103.3 to 104.0°F. The effect of time was highly significant (P < 0.001) for both BT measures with both BTcore and BTear recovering to resting levels by 60 min post exercise. PR and several blood values showed a significant main effect of time. Over the recovery period, dogs in the NW group had lower mean BTear and PR by 0.6°F and 3.4 bpm, respectively. Daily ingestion of a NW in combination with free access to TW can reduce the post-exercise-related BTcore and BTear hyperthermia, and improve pulse rate recovery following exercise in this population of working dogs undergoing 30 min bout of exercise.https://www.frontiersin.org/article/10.3389/fvets.2018.00202/fullworking doghydrationcore body temperaturebrain temperaturedrinkingear temperature
collection DOAJ
language English
format Article
sources DOAJ
author Brian M. Zanghi
Patrick J. Robbins
Meghan T. Ramos
Cynthia M. Otto
spellingShingle Brian M. Zanghi
Patrick J. Robbins
Meghan T. Ramos
Cynthia M. Otto
Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise
Frontiers in Veterinary Science
working dog
hydration
core body temperature
brain temperature
drinking
ear temperature
author_facet Brian M. Zanghi
Patrick J. Robbins
Meghan T. Ramos
Cynthia M. Otto
author_sort Brian M. Zanghi
title Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise
title_short Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise
title_full Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise
title_fullStr Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise
title_full_unstemmed Working Dogs Drinking a Nutrient-Enriched Water Maintain Cooler Body Temperature and Improved Pulse Rate Recovery After Exercise
title_sort working dogs drinking a nutrient-enriched water maintain cooler body temperature and improved pulse rate recovery after exercise
publisher Frontiers Media S.A.
series Frontiers in Veterinary Science
issn 2297-1769
publishDate 2018-08-01
description Exercise-related physiological changes were evaluated in hydrated, exercise-conditioned working dogs with free access to tap water (TW) with or without a nutrient-enriched water supplement (NW). Physiological samples and measures were collected before and after work-related field tasks in a warm and moderately humid ambient environment. In a cross-over design study, 12 dogs (age range 8–23 months) were evaluated on 3 separate occasions within each period with exercise bouts up to 30 min, on days −4, 3, and 11. Dogs were offered either ad libitum TW or portion-controlled NW daily plus ad libitum TW. Prior to and serially after exercise, pulse rate (PR), core (BTcore) and ear (BTear) temperature were recorded. Urine was collected first thing in the morning, whereas blood samples collected and body weight (BW) recorded pre- and immediately post exercise. Ambient temperature was above 21.7°C (71°F) and relative humidity ranged from 36 to 76%. Activity parameters, AM urine measures, post-exercise percent change of BW, resting PR and resting BTcore did not differ between treatment groups on any exercise day. At the completion of exercise, mean BTcore for all dogs ranged from 104.8 to 105.6°F. Immediate post-exercise BTear was always lower compared to BTcore and means ranged from 103.3 to 104.0°F. The effect of time was highly significant (P < 0.001) for both BT measures with both BTcore and BTear recovering to resting levels by 60 min post exercise. PR and several blood values showed a significant main effect of time. Over the recovery period, dogs in the NW group had lower mean BTear and PR by 0.6°F and 3.4 bpm, respectively. Daily ingestion of a NW in combination with free access to TW can reduce the post-exercise-related BTcore and BTear hyperthermia, and improve pulse rate recovery following exercise in this population of working dogs undergoing 30 min bout of exercise.
topic working dog
hydration
core body temperature
brain temperature
drinking
ear temperature
url https://www.frontiersin.org/article/10.3389/fvets.2018.00202/full
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