Total body water and ECFV measured using bioelectrical impedance analysis and indicator dilution in horses

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Total body water and ECFV measured using bioelectrical impedance analysis and indicator dilution in horses

Mariann Forro, Scott Cieslar, Gayle L. Ecker, Angela Walzak, Jay Hahn, and Michael I. Lindinger

Department of Human Biology and Nutritional Sciences, University of Guelph, Guelph, Ontario, Canada N1G 2W1

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The purposes of this study were 1) to determine the compartmentation of body water in horses by using indicator dilutiontechniques and 2) to simultaneously measure bioelectrical impedanceto current flow at impulse current frequencies of 5 and 200 kHzto formulate predictive equations that could be used to estimatetotal body water (TBW), extracellular fluid volume (ECFV), andintracellular fluid volume (ICFV). Eight horses and ponies weighingfrom 214 to 636 kg had catheters placed into the left and rightjugular veins. Deuterium oxide, sodium thiocyanate, and Evansblue were infused for the measurement of TBW, ECFV, and plasmavolume (PV), respectively. Bioelectrical impedance was measuredby using a tetrapolar electrode configuration, with electrodepairs secured above the knee and hock. Measured TBW, ECFV, andPV were 0.677 ± 0.022, 0.253 ± 0.006, and 0.040 ± 0.002 l/kg bodymass, respectively. Strong linear correlations were determinedamong measured variables that allowed for the prediction of TBW,ECFV, ICFV, and PV from measures of horse length or height andimpedance. It is concluded that bioelectrical impedance analysis(BIA) can be used to improve the predictive accuracy of noninvasiveestimates of ECFV and PV in euhydrated horses atrest.

hydration; equine; deuterium oxide; sodium thiocyanate; plasma volume; water balance; extracellular fluid volume; intracellular fluid volume; bioelectrical impedance analysis; body weight

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

IN CLINICAL AND FIELD SITUATIONS, the rapid assessment of body mass and hydration status are important for performance, health,and treatment evaluation. In horses, as in humans, dehydrationfrom disease, prolonged exercise, or transport impairs health,well-being, and physical and cognitive performance (4, 19,27). At present, it is not yet possible to assess noninvasively,rapidly, and accurately the magnitude of extracellular and intracellulardehydration in horses and other mammals (6). Indicator dilutiontechniques have been used to estimate extracellular fluid volume(ECFV) and total body water (TBW) in the horse (for review, seeRef. 2). However, these methods are invasive and time consumingand must be repeated sequentially to follow a time course of changein body water compartmentation. Because bioelectrical impedanceanalysis (BIA) technology is small, portable, noninvasive, andeasy to perform (13), BIA may prove to be an important diagnostictool if found to be a reliable method for assessing body fluidstatus of horses. The present study provides an initial assessmentof the use of BIA for the empirical determination of body massand water compartment volume in euhydratedhorses.

Multifrequency BIA has been used for the determination of hydration state in humans for a number of years and has been thesubject of review (6, 12, 25). The principle of the techniqueis based on the impedance to the flow of a constant, microamperealternating current passed through conductive fluid cylinders(conductors) that represent trunk and limb segments (13, 20).The electrical conductivity of the body is dependent on the amountof water and electrolytes present in the various body fluid compartments.With the assumption that the conductors have a uniform cross section,the volume (V) of the conductor is proportional to its length(L) squared divided by its impedance (Z), V = $rho$ L²/Z, where $rho$ is a specific resistivity term (6). Specific resistivityis an electrical characteristic of the conductor that is independentof its volume and shape (6, 35). The resistance to currentflow is due to the specific resistivity and the volume of theconducting fluid or the fat-free mass of the animal. Cell membranesact as electrical condensers and are a barrier to current flowat low frequencies ( $<=$ 50 kHz). Hence, bioelectrical impedance measuredat 1-5 kHz has been used to estimate ECFV (34, 35). In contrast,at frequencies >50 kHz, cell membranes are not a barrier to currentflow, allowing bioelectrical impedance measured at 200 kHz toestimateTBW.

The horse, like humans, may be considered a series of conductive cylinders for the purposes of BIA. As in humans, the impedanceof the whole body can be measured by means of a tetrapolar electrodeconfiguration, by using the forelimb and hindlimb together withthe length of the horse to calculate the total and extracellularconductive volumes of the body. Impedance to the flow of electricalcurrent injected into one cylinder and detected in another cylindercan be measured at different frequencies, allowing for the estimationof TBW and ECFV (6, 13, 24, 35).

The primary purposes of this study were 1) to determine the compartmentation of body water in horses via indicator dilutiontechniques and 2) to simultaneously measure bioelectrical impedanceto current flow at impulse frequencies of 5 and 200 kHz. Thesemeasures would allow us to determine whether BIA can be used toreliably estimate TBW and ECFV in horses compared with standardindicator dilution techniques and to determine the practicalityof using BIA in horses. Accordingly, we hypothesized that theuse of dual-frequency BIA increases the accuracy with which TBWand ECFV can be predicted, compared with using body length orheight measures alone without BIAmeasures.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Subjects

The experiments consisted of a pilot study that used three horses (two Standardbreds and one Thoroughbred cross) and a subsequentfull study that used eight horses (Table 1) from the Universityof Guelph herd. Horses were fasted overnight but had access towater in their stalls. The horses were healthy but not physicallytrained to perform exercise. Food and water were withheld duringthe experiment. The experiments were approved by the Animal CareCommittee and the Veterinary Teaching Hospital of the Universityof Guelph and were performed in accordance with the guidelinesof the Canadian Council on Animal Care.

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Table 1. Characteristics of the horses participating in the study

Length was measured with a measuring tape on the left side of the horse as the horizontal distance from the point of the shoulderto the furthest curve of the rump without wrapping the tape aroundthe curve of the rump (Fig. 1). Height of the horse was measuredwith a height measurement stick for horses as the vertical distancefrom the ground to the highest point of the withers when the horsewas standing squarely on a flat surface (Fig. 1). Body mass wasmeasured with a large animal scale (±0.5 kg, KSL Scales, Kitchener,ON, Canada) during the experiment.

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Fig. 1. Schematic diagram showing electrode placement and anatomic landmarks for height and length measurements.

Pilot Study

Pilot studies were conducted on three horses to 1) determine suitable sites for electrode placement, 2) compare stainlesssteel electrodes with carbon fiber electrodes, and 3) determinethe frequencies of current injection required to obtain impedancemeasures that yielded a high degree of correlation to TBW andECFV. In the pilot study, ECFV was estimated as 0.222 × body mass(2). On the forelimb, electrodes were placed on clipped andcleaned areas just above and below the left knee, and on the lefthindlimb electrodes were placed just above and below the hock.After application of electrode gel to skin sites and electrodes,electrodes were secured on the limbs with wide elastic bands withVelcro attachments. Stainless steel and carbon fiber electrodeswere used in sequence at the leg site to compare the two electrodetypes. On the torso, the carbon fiber electrodes were placed inpairs 15 cm apart (center to center) on the neck and rump andsecured to the skin with tape (see Fig. 1 for electrode placement).The stainless steel electrodes were not used on the torso. Impedancemeasurements were obtained in triplicate by using a Bodystat 5000multifrequency bioelectrical impedance analyzer (Bodystat, Douglas,Isle of Man, UK), with data collected at frequencies of 5, 50,200, and 500kHz.

Full Study

Infusion and sampling. The deuterium oxide (D₂O) dilution volume has recently been shown to be useful for the measurement of TBW in horses (1).Similarly, sodium thiocyanate (NaSCN) and Evans blue indicatordilution techniques are well established for the measurement ofECFV (3, 10, 22) and plasma volume (PV; Refs. 17, 21,22).

The hair coat over the jugular vein, 10-20 cm below the mandible, was clipped short to the skin on both sides of the neck.Each jugular vein catheterization site was aseptically preparedfor insertion of catheters. A topical analgesic [EMLA cream (2.5%lidocaine and 2.5% prilocaine), Astra Pharma, Mississauga, ON,Canada] was applied 30-45 min before insertion of catheters todesensitize the skin. Local anesthetic (2% Xylocaine, Astra Pharma)was injected subcutaneously to complete the analgesia. A catheter(14-gauge, 5.25-in. Angiocath, Becton-Dickinson, Mississauga,ON, Canada) was inserted anterograde into the left and right veins,secured with tape, and stitched to the skin. Four-way stopcockswith 20-in. extensions (Medex-Hilliard) were attached to the cathetersfor ease of infusion and blood sampling. Patency of the catheterswas maintained with sterile, heparinized 0.9% NaCl (2,000 IU/lNaCl).

The dilution indicator used for measuring TBW was D₂O (110 mg/kg; Refs. 1, 13), infused as a 50% vol/vol solution with0.9% sterile saline for a total volume of 60-100 ml. ECFV wasmeasured using NaSCN (22 mg/kg; Refs. 3, 10), infused asa 20% wt/vol solution in 0.9% sterile saline for a total volumeof 40-60 ml. PV was measured using Evans blue (0.11 mg/kg; Refs.17, 23, 24) infused as a 0.5% wt/vol solution in sterilesaline for a total volume of 6-10 ml. D₂O was purchased from SigmaChemical (St. Louis, MO) or from Acros (Fisher Scientific, Nepean,ON, Canada), NaSCN from Sigma Chemical, and Evans blue from FisherScientific.

The indicators were injected in sequence (Evans blue, 9 ml; D₂O, 25-50 ml; NaSCN, 25-50 ml) using the right catheter overa period of 5 min. Sterility of the infusates was ensured by usinga nonpyrogenic, sterile 0.22-µm nylon filter (Millex-Ap/GS Filter,Millipore S.A. 67, Mosheim, France) placed on the syringe. Immediatelyafter the final infusion, the catheter was flushed with 50 mlof sterile 0.9% saline. Blood was sampled from the left catheterwith 7.5-ml lithium-heparin syringes (Monovette-Sarstedt, Sarstedt,Germany) before infusion of indicators and 10, 20, 30, 45, 60,90, and 120 min after infusion. Each blood sample was transferredto five 1.5-ml Eppendorf centrifuge tubes. Four blood sampleswere centrifuged for 3 min at 15,000 g, and the other was placedon ice for subsequent whole blood analysis. Plasma (2-3 ml) wasstored in 1.5-ml Eppendorf tubes and kept on ice until analyzedfor Evans blue and NaSCN. Remaining plasma was stored in 1.8-mlscrew-cap cryovials at $-$ 20°C until analyzed for D₂O.

BIA measurements. On the basis of the pilot study results, it was decided that the electrodes should be situated on the legs above the kneeand hock, with bioelectrical impedance measured at 5 and 200 kHz.The hair coat was clipped short on the lateral surfaces of theleft forelimb and hindlimb above the knee and hock (about 2-mmhair length). These sites were cleaned well with water and weredried with gauze or towels. BIA measurements were obtained byusing a prototype Equistat 2005 (Equistat, Douglas, Isle of Man,UK), with shielded leads connecting the measuring unit to carbonfiber electrode pairs (5-cm diameter) placed on prepared areas.Before electrode placement, some conductive gel was rubbed intothe hair coat directly where the electrode would sit. A smallamount of gel was also applied to the surface of each electrode.On the forelimb, the two electrodes (10 cm between centers) weresituated below the elbow on the lateral portion of the radiusdirectly over the common digital extensor, ulnaris lateralis,and radial carpal extensor muscles. On the hindlimb, the electrodepair (10 cm between centers) was placed on the tibia directlyover the long digital extensor and lateral digital extensor muscles.The distal electrode was used for current injection (800 µA emittedat frequencies of 5 kHz and 200 kHz), and the proximal electrodewas used for current detection from the other limb. The instrumentreported impedance in ohms at each frequency. Measurements wererepeated a minimum of three times to ensure repeatability andconsistency.

Analyses. The whole blood sample was analyzed, in duplicate, for hematocrit and plasma ion and metabolite concentrations (Nova StatProfile 9+, NOVA Biomedical, Waltham, MA). Plasma protein concentrationwas determined by using refractometry (clinical refractometermodel SPR-T2, Atago, Tokyo, Japan). Plasma was analyzed for Evansblue concentration via the dual-wavelength method (17) by useof a spectrophotometer (DU-70, Beckman, Mississauga, ON, Canada).Plasma NaSCN concentration was measured spectrophotometricallyby a microvolume modification of the method described by Chatterjeeet al. (5). Analysis of plasma D₂O concentration was performedby Metabolic Solutions (Nashua, NH), as described previously (1).The D₂O in plasma and water samples was reduced at 490°C to producedeuterium gas that was measured with an isotope-ratio mass spectrometer.The data are expressed in delta D/ml ( $delta$ ) relative to Vienna standardmean ocean water(VSMOW).

Calculations. TBW was calculated from plasma D₂O concentrations by two different sets of equations: Eqs. M1 to M3 by Metabolic Solutions(Nashua, NH) and equation Eq. M4 from Andrews et al. (1)

TBW (mol)<IT>=</IT>(WA<IT>/</IT>18.02a) (M1)

×[(&dgr;dose<IT>−&dgr;</IT>tap)<IT>/</IT>(<IT>&dgr;</IT>post<IT>−&dgr;</IT>pre)]

where W is grams of water used to dilute the dose, A is grams of dose administered to the subject, a is grams of dose dilutedfor analysis, $delta$ _pre and $delta$ _post are the delta deuterium values determinedfor the predose and postdose samples, $delta$ _dose is the measured deuteriumcontent of the diluted dose, and $delta$ _tap is the measured deuteriumcontent of local (tap) water. To convert TBW to kilograms

TBW (kg)<IT>=</IT>TBW (mol)<IT>×18.02 </IT>(g<IT>/</IT>mol)<IT>/</IT>1,000 g<IT>/</IT>kg (<IT>M2</IT>)

The D₂O dilution technique overestimates TBW by 4% because of binding of deuterium to acidic amino acids and other nonexchangeablesites. To correct for the nonexchange of deuterium in the body,a corrected TBW (TBW_MS) was obtained by dividing TBW from Eq.M2 by 1.04

TBWMS<IT>=</IT>TBW<IT>/</IT>1.04 (M3)

The value calculated from the equation of Andrews et al. (1) was also divided by 1.04 and is reported as TBW_A

TBWA (kg)<IT>=</IT><FR><NU>Dose<IT>×</IT>APEdose<IT>×18.02 </IT>g<IT>/</IT>mol</NU><DE>1.04<IT>×</IT>MWdose<IT>×100×</IT>(<IT>&dgr;</IT>p<IT>−&dgr;</IT>b)</DE></FR><IT>×</IT>Rstd (M4)

where Dose is dose in grams, APE_dose is atom percent excess of dose (99.9%), MW_dose is molecular weight of D₂O = 20.02 g/mol, $delta$ _P is $Delta$ D₂O vs. VSMOW for plateau sample, $delta$ _b is $Delta$ D₂O ofbaseline sample (time 0), and R_std is ratio of deuterium to hydrogenin VSMOW (standard = 0.00015576).

ECFV was calculated from plasma NaSCN concentration (5) and PV from plasma Evans blue concentration (16). Intracellularfluid volume (ICFV) was calculated as the difference between TBWandECFV.

Statistics. Single and multiple stepwise linear regression analyses were used to determine relationships among measured variables. Statisticalsignificance was accepted at P < 0.05 at a power of 80%.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Pilot Study

The range in body mass spanned 119 kg (406.5-525.5 kg), length ranged from 152 to 160 cm, and height ranged from 146.5 to156.5cm.

There was no difference in the bioelectrical impedance measurements obtained using stainless steel vs. carbon fiber electrodes.At 5 kHz, impedance was 221 ± 1 $Omega$ and 219 ± 1 $Omega$ for stainlesssteel and carbon fiber electrodes, respectively. At 50 kHz, impedancevalues were 184 ± 1 and 183 ± 1 $Omega$ ; at 200 kHz, 157 ± 1 and 156± 1 $Omega$ ; and at 500 kHz, 145 ± 2 and 142 ± 1 $Omega$ .

Bioelectrical impedance measured at each frequency was considerably less at the torso site than at the legs. The variability,as represented by the standard error of triplicate measures oneach horse, was also less with torso impedance measurements thanwith leg impedance measurements. There was also less intersubjectvariability with torso site measures compared with leg site measures.At 5 kHz, impedance was 44.1 ± 1.8 $Omega$ and 211 ± 16 $Omega$ for torsoand leg sites, respectively. At 50 kHz, impedance was 33.4 ± 1.3and 175 ± 12 $Omega$ ; at 200 kHz, 23.0 ± 1.0 and 148 ± 12 $Omega$ ; and at500 kHz, 24.6 ± 2.8 and 132 ± 12 $Omega$ .

During the course of our observations and measurements (total of 83 data sets) on seven horses, it was found that the stanceof the horse had no effect on bioelectrical impedance measuredat the leg or torsosites.

Blood and Plasma Characteristics

All measured plasma and plasma characteristics were normal: hematocrit 36 ± 2%, plasma protein concentration 61 ± 3 g/l, Na⁺ concentration 136 ± 1 mmol/l, K⁺ concentration 4.1 ± 0.2 mmol/l, Ca²⁺ concentration 1.26 ± 0.02 mmol/l, Cl concentration 99 ± 2 mmol/l, and glucose concentration 5.9 ±0.4 mmol/l.

Fluid Compartment Volumes

Measured values for TBW, ECFV, and PV are presented in Table 1. When normalized for body mass, TBW_MS was 0.677 ± 0.022 l/kg,ECFV was 0.253 ± 0.006 l/kg, ICFV was 0.356 ± 0.013, and PV was0.040 ± 0.002 l/kg. There was no difference between TBW_MS comparedwith TBW_A (0.676 ± 0.023 l/kg).

Linear Regression Analysis

TBW was highly correlated to mass, height, and length (Table 2). Length was the single most powerful predictor of TBW. Usinglength and height together provided an excellent estimate of TBW,reducing the standard error of the estimate (SEE) by 25% comparedwith using mass alone. Using mass in addition to length and heightprovided no additional predictive power. Inclusion of bioelectricalimpedance measured at 200 kHz in the regression analysis had noeffect on the SEE of these euhydrated horses and did not increasethe predictive power of the equations. Figure 2A shows that measuredTBW_MS agreed closely with calculated TBW (Eq. 2 with BIA, Table2).

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Table 2. Regression equations correlating total body water to mass, height, and length

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Fig. 2. Graphical representations of the relationships between measured and calculated total body water (TBW, A; r² = 0.987), extracellular fluid volume (ECFV, B; r² = 0.998), and plasma volume (PV, C; r² = 0.975), all in liters. Solid line, mean; dashed lines, SE; dotted lines, 95% confidence intervals.

ECFV was also highly correlated to mass, height, and length (Table 3). As with TBW, length was the single most powerful predictorof ECFV. Using bioelectrical impedance measured at 5 kHz withlength (Eq. 7, Table 3) resulted in a threefold decrease in theSEE. Similar results were obtained when using height and bioelectricalimpedance measured at 5 kHz, with this correlation yielding thelowest SEE of 1.25 liters (Eq. 8, Table 3). There was no benefitfrom including mass into the regression analysis, nor from usinga combination of length and height together. Calculated ECFV (Eq.7 with BIA, Table 3) agreed closely with measured ECFV (Fig.2B).

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Table 3. Regression equations correlating extracellular fluid volume to mass, height, length, and bioelectrical impedance measured at 5 kHz

PV, a component of ECFV, was also highly correlated to mass, height, length, and bioelectrical impedance measured at 5 kHz(Table 4). Height was a stronger predictor of PV than was length,and the combination of height and bioelectrical impedance measuredat 5 kHz yielded the lowest SEE (Eq. 13, Table 4). CalculatedPV using height with impedance at 5 kHz (Eq. 13 with BIA, Table4) closely matched measured PV (Fig. 2C). PV was also highlycorrelated to ECFV according to the relationship

PV<IT>=</IT>−<IT>1.004+</IT>(<IT>0.170×</IT>ECFV)<IT>; n=8,</IT> (16)

r2=0.917, P<0.001, SEE<IT>= 2.08 </IT>liters

Body mass (kg) was highly correlated to length (in cm; Eq. 17), and slightly more so to the combination of length and height(in cm; Eq. 19). There was no improvement in the correlation withthe addition of impedance measurements.

Mass<IT>=</IT>−<IT>584.6+</IT>(<IT>6.741×</IT>liters)<IT>; n=8,</IT> (17)

r2=0.989, P<0.001, SEE<IT>=15.3 </IT>kg

Mass<IT>=</IT>−<IT>356.2+</IT>(<IT>5.478×</IT>H)<IT>; n=8,</IT> (18)

r2=0.928, P<0.001, SEE<IT>=39.5 </IT>kg

Mass<IT>=</IT>−<IT>637.0−</IT>(<IT>1.638×</IT>H)<IT>+</IT>(<IT>8.654×</IT>liters)<IT>;</IT>

n=8, r2=0.992, SEE<IT>=14.0 </IT>kg (19)

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Table 4. Regression equations correlating plasma volume to mass, height, length, and bioelectrical impedance measured at 5 kHz

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The present study simultaneously measured TBW, ECFV, and PV in a group of horses ranging in mass from 212 to 636 kg. Compartmentvolumes, normalized to the mass of the animal, were remarkablyconsistent over the range of body mass. Furthermore, the sizeof these volume compartments could be estimated with reasonablygood accuracy by using dual-frequency BIA when horse length orheight was used in the predictive equation. For ECFV and PV, usingbioelectrical impedance measured at 5 kHz greatly improved thepredictive estimates of these volumes compared with not usingBIAmeasures.

Pilot Study

There was no difference in impedance readings between the stainless steel and carbon fiber electrodes. It was thought thatthat localized changes in skin temperature (and hence blood flow)may affect whole body bioelectrical impedance measurements; however,this has recently been disproved (9). Nonetheless, it is suggestedthat carbon fiber electrodes be used because 1) avoiding changesin skin temperature may increase comfort and acceptance with repeateduse and 2) the fact that carbon fiber electrodes are soft andcompliant makes them less likely to cause compression and discomforton thelegs.

The intrasubject variability of bioelectrical impedance measurements obtained from the torso were considerably reduced comparedwith leg measurements. This finding, along with the fact thatthe torso represents the main conductive cylinder in the body,indicates that the torso may be a preferred site for obtainingmeasures of bioelectrical impedance in large mammals. However,at this site, the difficulties include the need to shave the haircoat and ensuring good contact of the electrodes to the skin sites,particularly if the horse is moving around a bit. Therefore, thetorso is not a preferredsite.

On the leg sites, the choice of electrode placement above and below the knee or hock, although yielding reasonably good data,was also deemed not satisfactory for the following reasons. First,the interelectrode distance over the joint was variable from onetime to the next and between horses. This variance was due toanatomical differences between horses and to the shape of theleg around the joints, which made it difficult to maintain theelectrodes in the same position. Second, equine athletes, as dohumans, often experience joint swelling and inflammation; useof a swollen or inflamed joint for BIA measurements could be asource of error. For ease of measurement and for avoidance ofthe knee and hock joints, it was concluded that placement of bothelectrodes should be a minimum of 5 cm above the knee or hockjoint and that this placement be standardized, as described inMATERIALS AND METHODS.

Bioelectrical and morphometric data were analyzed by using a series of single and stepwise multiple linear regression analyses.Statistical analysis of the pilot study data indicated that length,height, and bioelectrical impedance at both 5 and 200 kHz wererequired to obtain the best prediction of body mass and estimatedECFV. Impedance measurements made at 50 and 500 kHz provided noadditional power or accuracy to the predictiveequations.

Full Study

Methodology. In contrast to previous studies that have utilized mass as an independent variable for estimating the volume of body fluidcompartments in horses (see Ref. 2), the present study emphasizesthe use of length and height for two important reasons. First,body mass is a dependent variable that changes in response tofeeding and hydration state, and as such it can change substantiallyand rapidly with a time course that can be in the order of minutes.Therefore, the use of body mass may result in inaccurate estimatesof "normal" compartment volumes, as has been shown in humans withfluid disorders (34). Second, length and height measures areconstant, independent variables that can be accurately obtainedby careful measurement using a measuring tape (length) and height-measuringstick.

Volume of fluid compartments. The present measures of TBW, ECFV, and PV agree well with those obtained in previous studies using various indicator dilutiontechniques (Table 5). TBW, ECFV, and PV, when normalized to bodymass, were very consistent among horses over the >400-kg massrange of the present study. It is noteworthy that ECFVs obtainedin the present study are similar to those reported by Kohn etal. (22), in which the horses were physically fit and not fastedbefore determination of ECFV. The higher values obtained by Spurlocket al. (36) may be due to the fact that NaSCN was infused inconjunction with antipyrine (to determine TBW), which interfereswith the NaSCN determination and must be extracted before NaSCNconcentrations can be quantified.

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Table 5. Literature comparison of compartment volumes in horses

There is evidence in the literature that the volume of water compartments, expressed per kilogram body mass, varies with trainedstate and breed (Table 5). In longitudinal studies conductedin humans (8) and horses (28), as well as cross-sectionalstudies performed on horses (relatively untrained: present studyand Ref. 23, PV = 39.4 ± 1.4 ml/kg; well trained: Ref. 24,PV = 46.8 ± 2.9 ml/kg), PV increases after several weeks of exercisetraining. It appears that TBW and PV are greater in hot-bloodedhorses (Thoroughbreds, Arabians, quarter horses, Standardbreds)compared with draft horses (21, 26). Furthermore, among horsesstudied by Marcilese et al. (26), Thoroughbred English racehorseshad a markedly greater PV than did saddle horses, and both hada PV greater than that measured in the untrained horses in thepresent study. The PV data of the present study agree well withother studies of untrained horses (7). Some of the discrepancyamong studies may also be due to differences in measurement andsampling techniques (17) and fasted state of the horse. In ourlab, endurance-trained Thoroughbreds had a resting PV of 0.049± 0.003 l/kg (24), 10% higher than the horses in the presentstudy.

Andrews et al. (1) appear to have been the first to use and report the D₂O dilution space as a measure of TBW in horses,although earlier studies utilized tritiated water (11, 14).In contrast to previous studies that used oral administrationof D₂O in horses (1), the present study infused the D₂O (mixed50-50 with 0.9% NaCl) into the jugular vein to increase the rateof equilibration by bypassing gastric emptying and intestinalabsorption. Accordingly, steady-state values of TBW were obtainedwithin 120 min of infusion, compared with 3 h or more after oraladministration. For unknown reasons, TBW values measured usingtritiated water appear greater than those measured using D₂O.The TBW reported in the present study agrees well with that ofSpurlock (36) and Andrews et al. (1), in good agreement withTBW measured by direct analysis of carcass water content of ponies(33).

The predictive equations determined in the present study indicate that the volume of body fluid compartments may not scalesimply as a function of body mass. Using the scaling factors forTBW (0.666 × body mass) and ECFV (0.222 × body mass) providedby Carlson (2) will result in an increasing probability oferror as the mass of the horse decreases, yet these equationsare reasonably accurate in the 350- to 550-kgrange.

BIA. The results indicate that TBW and body mass can be accurately predicted in mature, euhydrated horses by using the variableslength and height, without the need for bioelectrical impedancemeasurements. It stands to reason, therefore, that if these equationsare used to estimate TBW in a dehydrated horse, then the valueobtained will provide an estimate of what TBW should be in thathorse in the euhydrated condition. Such an estimate will thereforeoverestimate TBW in the dehydrated horse. During the course ofendurance rides, horses may lose up to 50 liters of water in 4-6h (4, 15), yielding a magnitude of loss in TBW that is muchgreater than the SEE obtained with the regression equations ofTable 2. Similar losses of TBW occur in response to the loopdiuretic furosemide administration (18). It is highly likely,therefore, that such decreases in TBW would be manifest by a changein bioelectrical impedance measured at 200 kHz, suggesting thatBIA could be used in conjunction with horse length and heightto detect dehydration in horses. BIA may also be useful to assessthe magnitude and rate of increase in PV and ECFV that occursduring exercise training (as noted above) and with heat acclimation(24). Although further research on horses needs to be conductedusing BIA to determine changes in TBW and ECFV, this techniquehas been used successfully to assess hydration status in humanswho have been administered furosemide (31).

Exercise, training, diuresis, and heat acclimation all result in simultaneous changes in hematocrit, plasma, and extracellularand intracellular fluid ion concentrations and volumes that mayneed to be considered when using BIA for assessing hydration status.Impedance to current flow is a function of the volume of the variousbody fluid compartments and the ion concentrations in those compartments;therefore, simultaneous changes in compartment volume and ionconcentration may impair the accuracy of the technique. Becausered blood cells are a tissue compartment and likely behave asthe rest of the body's cellular mass, it is not likely that changesin hematocrit during exercise or training will have an appreciableeffect on BIAmeasurements.

The "gold standard" technique most used for the determination of TBW in horses has been the dilution of tritiated water (seeTable 5). Because tritium is radioactive, it has not been usedfor the clinical determination of hydration status. The use ofD₂O produces similar values of TBW as does tritiated water (Table5), indicating that D₂O could be used in clinical testing; however,there are appreciable time constraints and costs associated withD₂O analysis. In contrast, a rapid and inexpensive determinationof hydration status and body water compartmentation could be achievedby using BIA. Length or height, when used in conjunction withbioelectrical impedance measured at 5 kHz, improved the predictiveaccuracy of estimates of ECFV (Table 3) and PV (Table 4). Theuse of bioelectrical impedance measured at 5 kHz resulted in athree- to fourfold decrease in SEE for ECFV and PV. Length andheight measurements yielded strong correlations because they reflectthe distances through which current passes in cylindrical segmentsof the body. A similar degree of predictive accuracy has beenreported in humans when using height squared (with intentionalomission of body mass) as the sole morphometric variable (34,35).

Conclusions

BIA is useful for improving the predictive accuracy for rapid, noninvasive estimation of ECFV and PV in mature, euhydrated,resting horses. For the clinician and researcher, BIA providesmany advantages over dilution techniques, which are time consumingand invasive. Because body mass is not required as an input variable,BIA, together with measures of length and height, can be readilyused in field and farm situations to assess hydration status.Ongoing research will determine the practical value of the BIAtechnique for estimating TBW, ECFV, and PV in dehydratedhorses.

	ACKNOWLEDGEMENTS

We acknowledge the assistance of Nelson Cole, Barry Cole, Gerry Finlay, and staff of the Veterinary Teaching Hospital. Wethank Dr. Leslie Huber for providing veterinary assistance andconsultation. We are grateful to Bodystat for providing the Equistat2005.

	FOOTNOTES

This research was supported by the Ontario Ministry of Foods and Rural Affairs, Bodystat, and the Natural Sciences and EngineeringResearch Council ofCanada.

Address for reprint requests and other correspondence: M. I. Lindinger, Dept. of Human Biology and Nutritional Sciences, Univ.of Guelph, Guelph, ON, Canada N1G 2W1 (E-mail: mlinding{at}uoguelph.ca).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Received 21 October 1999; accepted in final form 1 April 2000.

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