Selected papers from “L’innovazione scientifica per la nutrizione”, 15th October, 2015, Lodi (MI), Italy 8 

HAF © 2013 

Vol. II, No. 2s  ISSN: 2283-3927 

   

 

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Introduction 

Intramammary infection (IMI) can adversely affect, in dairy goats, milk quality and milk yield leading to high 

economical losses. Although somatic cell count (SCC) and microbiological tests could be valid approaches to detect 

IMI, other methods of IMI early detection may be useful to detect infected animals and to improve milk quality. In 

this respect, the evaluation of electrical conductivity (EC) of milk, by on-line sensors, represents an interesting 

approach. The concentrations of Na+ and Cl- in milk increase during an IMI due to a change of the permeability of 

the udder tissue, influencing the EC of milk (Tangorra et al. 2010). This effect has been largely studied in dairy cows 

and the use of EC has been adopted with successful results in terms of detection accuracy (De Mol et al. 2001). On 

the contrary, in dairy goats, this has not been the case mainly because less research studies have been conducted. 

However, our research group has shown that a specificity of 65% and a sensitivity of 81% could be reached by a 

univariate model based on evaluations of time series of gland milk EC (Zaninelli et al. 2015). These results are in 

accordance with other authors (Diaz et al. 2011; Romero et al. 2012) that suggest: to consider the intrinsic variation 

of animals (as in cows), to avoid the use of simple thresholds, and to use other significant factors in the model such 

as the EC values of milk in different milking fractions (Romero et al. 2012). In agree with these latter suggestions, in 

another study our research group has tested a multivariate model, developed with the fuzzy logic technology, 

based on the EC of gland milk and the evaluation of the goats milk yield (Zaninelli et al. 2014). The results obtained 

have shown an improvement in the detection accuracy of the model evaluated (specificity of 69% and a sensitivity 

of 81%). Nevertheless, the reached values are not still enough high if compared with results obtained in dairy cows 

(De Mol et al. 2001). Further studies, on multivariate models that use more informative parameters derived from the 

EC of milk, are necessary. 

The aim of this study was to test a new multivariate model developed with the fuzzy logic technology and 

based on the milk EC - acquired on-line for each gland by dedicated sensors - and on new qualitative and 

quantitative indexes derived from the spectrum of the recorded signals. 

 

Material and Methods 

The experiment was carried out for two weeks. Ten healthy Saanen goats at second lactation were randomly 

selected from a herd of 400 dairy goats. The animals were milked twice a day (7:00 a.m. and 5:00 p.m.). Milking 

parlor had: a low-line design, self-locking gates and 2 platforms with 16 milking units and milking posts per platform. 

Milking parameters were: a pulsation rate of 90 cycles/min, a vacuum level of 40 kPa and a pulsation ratio of 60%. 

Two individual milk samples were collected from each mammary gland, during the morning milking, and 

frozen. According to microbiological tests and SCC performed on collected samples results were classified as: Case 1 

(C1) if SCC<1,000,000 cells/mL and no pathogenic microorganisms were found; Case 2 (C2) if milk samples had 

bacteriological tests positive for IMI; and Case 3 (C3) if SCC>1,000,000 cells/mL in 2 or more consecutive sampling 

 

 

KEYWORDS 

Electrical conductivity; Fuzzy 

logic; dairy goat; 
 

CORRESPONDING AUTHOR 

Mauro Zaninelli, 

mauro.zaninelli@unisanraffaele.gov.it 

 

JOURNAL HOME PAGE 

riviste.unimi.it/index.php/haf 

Use of Electrical Coductivity Sensors to 

monitor Health Status and Quality of Milk 

in Dairy Goats 

M. Zaninelli 
1
*, L. Rossi 

2
, A. Costa 

2
, F.M. Tangorra 

2
, A. Agazzi 

2
,  

G. Savoini 
2
 

1 
Faculty of Agricolture, Università Telematica San Raffaele Roma, Via di Val 

Cannuta 247, 00166, Roma, Italy; 

2 
Department of Health, Animal Science and Food Safety, Università degli 

Studi di Milano, Via Celoria 10, 20133 Milan, Italy; 

 

Article 



Selected papers from “L’innovazione scientifica per la nutrizione”, 15th October, 2015, Lodi (MI), Italy  9 

HAF © 2013 

Vol. II, No. 2s  ISSN: 2283-3927 

days for non-physiological causes and without pathogenic microorganisms. Subsequently, samples classified in C1 

were associated with healthy glands, while those in C2 and C3 with non-healthy mammary glands. 

Five experimental milking clusters were used to measure on-line the EC (mS/cm) of gland milk (Zaninelli et al. 

2015b). Estimated EC values were then calculated through a moving-average model (using the ten previous values of 

EC observations) and the relative deviations of EC between measured and estimated values were calculated.  

From acquired electrical signals - and through a customised Matlab routine (The Mathworks, USA) - the Fourier 

frequency spectrum of each signal was calculated and other qualitative and quantitative indexes were determined: 

the bandwidth length and the three highest frequency peaks of each spectrum (Zaninelli et al. 2015b, 2015c). 

All the EC data were evaluated by a multivariate model developed using the fuzzy logic technology. Input 

variables were: the EC deviations, the bandwidth length and the three highest frequency peaks of each frequency 

spectrum. After “defuzzification”, a couple of sensitivity and specificity of the model was calculated for different 

cut-off levels. Finally, the cut-off level that allowed to reach a sensitivity of at least 80% was identified and the 

resulting pair of sensitivity and specificity was considered as the level of accuracy reached by the multivariate 

model. 

 

Results and Discussion 

The prevalence of bacteriological positive samples was 45.4% (n = 127). After the count of somatic cells in the 

milk samples, the resulting prevalence of glands with SCC > 1,000,000 and without pathogenic microorganisms was 

2.9% (n = 8). No cases of SCC > 1,000,000 due to physiological causes were observed. The overall prevalence of 

samples from not healthy glands was 61.1% (n = 171) and no cases of clinical mastitis were observed. 

As expected, not healthy glands showed higher mean value of SCC and of milk EC (Diaz et al. 2011, Romero et al. 

2012, Zaninelli et al. 2014, 2015a, 2015b, 2015c). The cut-off level for a sensitivity of at least 80% was equal to 0.7. With 

this cut-off level, the resulting specificity and sensitivity of the model were respectively: 73% and 81%. These results 

were better than those obtained by other multivariate and univariate models that use the EC of milk to detect 

healthy status of dairy goats. Nevertheless, these results cannot be considered enough if compared with those 

obtained in dairy cows (De Mol et al. 2001). 

However, “fuzzification” and “fuzzy inference” are the most important steps in the fuzzy logic technique since 

they affect the final accuracy of the model. In order to maximise the model accuracy, they need to use a big 

experimental data set. Therefore, with the collection of further experimental data the accuracy of the multivariate 

model, evaluated in this preliminary investigation, should be improved. 

 

Conclusions 

This preliminary evaluation demonstrated that the fuzzy logic model tested, based on the milk EC and on new 

qualitative and quantitative indexes derived from the spectrum of the recorded signals, could show better results 

than those already reached in dairy goat research. Nevertheless, further experiment and more field data could be 

useful to reach the best possible accuracy that this multivariate approach could show. 

 

References 

De Mol R. M. & Ouweltjes W. (2001). Detection model for mastitis in cows milked in an automatic milking system. PREVENTIVE VETERINARY 
MEDICINE, 49(1-2), 71–82. 

Diaz J. R., Romero G., Muelas R., Sendra E., Pantoja J. C.F., Paredes C. (2011). Analysis of the influence of variation factors on electrical conductivity 
of milk in Murciano-Granadina goats. J. DAIRY SCI., 94, 3885–3894. 

Romero G., Pantoja J.C.F., Sendra E., Peris C., Díaz J.R. (2012). Analysis of the electrical conductivity in milking fractions as a mean for 
detecting and characterizing mastitis in goats. SMALL RUMIN. RES., 107, 157–163. 

Tangorra F.M., Zaninelli M., Costa A., Agazzi A., Savoini G. (2010). Milk electrical conductivity and mastitis status in dairy goats: Results from a 
pilot study. SMALL RUMIN. RES., 90, 109-113. 

Zaninelli M., Rossi L., Tangorra F.M., Costa A., Agazzi A., Savoini G. (2014). On-line monitoring of milk electrical conductivity by fuzzy logic 
technology to characterise health status in dairy goats. ITAL. J. ANIM. SCI., 13, 340–347. 

Zaninelli M., Rossi L., Costa A., Tangorra F.M., Agazzi A., Savoini G. (2015a) Monitoraggio dello stato di salute delle capre attraverso l’analisi 
on-line della conducibilità elettrica del latte. LARGE ANIM. REV., 21, 81–86. 

Zaninelli M., Agazzi A., Costa A., Tangorra F.M., Rossi L., Savoini G. (2015b). Evaluation of the fourier frequency spectrum peaks of milk electrical 
conductivity signals as indexes to monitor the dairy goats’ health status by on-line sensors. SENSORS, vol. 15, 20698-20716 

Zaninelli M., Rossi L., Costa A., Tangorra F.M., Agazzi A., Savoini G. (2015c). Signal Spectral Analysis To Characterize Gland Milk Electrical 
Conductivity In Dairy Goats. ITALIAN JOURNAL OF ANIMAL SCIENCE, vol. 14, 362-367