CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 57, 2017 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Sauro Pierucci, Jiří Jaromír Klemeš, Laura Piazza, Serafim Bakalis 
Copyright © 2017, AIDIC Servizi S.r.l. 

ISBN 978-88-95608- 48-8; ISSN 2283-9216 

Shelf Life Extension to Reduce Food Losses: the Case of 
Mozzarella Cheese 

Giacomo Falcone, Anna I. De Luca, Teodora Stillitano*, Nathalie Iofrida, Alfio 
Strano, Amalia Piscopo, Maria Luisa Branca, Giovanni Gulisano 
AGRARIA Department, Mediterranean University of Reggio Calabria, Feo di Vito, 89122 Reggio Calabria, Italy 
teodora.stillitano@unirc.it 

Agro-food is considered one of most polluting economic sector, in particular due to the large amount of 
greenhouse gases (GHGs) emission, the contribute to the terrestrial acidification, the depletion of water 
resources and the large amount of wastes linked to agricultural production, end of life of food products and 
food losses. Among agro-food systems, livestock sector represents the worse performance, producing, for 
example, about 60 % of GHG emissions. Dairy production amplifies this phenomenon, requiring a large 
amount of input materials to produce little quantity of products and generating, along the supply chain, a great 
quantity of wastes.   
The aim of this study is to evaluate, from an environmental and economic point of view, the introduction of an 
innovative shelf life extension (SLE) technique and its effects in terms of reduction of wastes and food losses 
in the Lacto Fermented Mozzarella Cheese production. A new liquid formulation containing antimicrobials, that 
extends the shelf-life of mozzarella, was tested as governing liquid to contrast the product degradation due to 
the bacterium Pseudomonas syringae. The use of calcium lactate and bergamot extract in freshwater solution, 
allowed an extension of shelf life close to 50 %.  
Life Cycle Assessment and Life Cycle Costing methodologies were applied to evaluate the effects of SLE 
implementation, taking also into account the potential reduction of food loss and returned goods. 
Results showed that despite a minimal increase of impacts and costs due to the introduction of the innovation, 
the SLE could allow reducing the share of losses up to 50%. Expressing results in terms of days of product 
shelf life, the innovative solution is more sustainable from both the environmental and the economic point of 
view. Insights can be used for the eco-design of high quality products.  

1. Introduction 

Food represents the principal requirement for every organisms, in particular for humans, who, in function of 
food resources, shaped the geographical conformation of the planet and influenced the history of humanity 
(Kiple and Ornelas, 2000; Diamond, 2002).  
The incessant challenge for food production, allowed the rich countries to respond to food requirement of 
people, also providing an answer to other emerging needs linked to the food, for example cultural or aesthetic 
ones (Notarnicola et al., 2017). The inexorable race to produce more and better food generated the rebound 
effect of food losses, producing, according to FAO estimation, 1.3 billions of edible food wastes (Gustavsson 
et al., 2011; Corrado et al., 2017). According to Garrone et al. (2016), food production, represents today an 
environmental cost, boosting scientific community and food companies searching innovative solutions to 
reduce environmental impacts and wastes. 
In this scenario, the development of Life Cycle Thinking and of methodologies inspired to it (Life Cycle 
Assessment - LCA, Life Cycle Costing - LCC and Social Life Cycle Assessment – sLCA) gained increasing 
consensus as appropriate tools for the evaluation of environmental, economic and social burdens (De Luca et 
al., 2015a, 2015b, 2015c; Iofrida et al., 2016). Several papers were published in the agro-food sector, 
specially thanks to the boost given by International Conferences on LCA of Food (Schenck and Huizenga, 
2014; LCA Food Conference Committee, 2016). Different supply chains have been object of study, for 
example, the agricultural sector (Gresta et al., 2014) the beverage industry (De Marco et al., 2016a), the food 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1757309

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Falcone G., De Luca A.I., Stillitano T., Iofrida N., Strano A., Piscopo A., Branca M.L., Gulisano G., 2017, Shelf life 
extension to reduce food losses: the case of mozzarella cheese, Chemical Engineering Transactions, 57, 1849-1854   
DOI: 10.3303/CET1757309 

1849

mailto:teodora.stillitano@unirc.it


processing (De Marco et al., 2016b) and the bioenergy production (Beaver et al., 2016). Life cycle 
methodologies have been applied as stand-alone tools (e.g. Stillitano et al., 2016) or jointly in order to assess 
the integrated sustainability (De Luca et al., 2015b and 2015c). 
Livestock production represents one of most investigated theme (McAuliffe et al., 2016; Baldini et al., 2017) 
due to its environmental relevance.  
According to FAOSTAT (2017), over 65 % of global agricultural emissions of CO2 equivalent were produced 
by livestock and connected activities. Farm animals are also a great exploiter of resources. For example, in 
terms of water, the animal production shares about 29 % of global agricultural water footprint (Mekonnen and 
Hoekstra, 2012). Dairy industry produces a multiplier effect of impacts, using a large amount of primary 
products to make little quantity of cheese (approximatively 10 litres of milk for 1 kg of cheese) and then, each 
unit of product loss carries with it several impacts. 
The aim of this study was to evaluate, from an environmental and economic point of view, a new technique for 
the shelf life extension (SLE) of Lacto Fermented Mozzarella Cheese. Results showed that the new SLE 
technique could contribute to the reduction of product loss and then to the improvement of environmental and 
economic sustainability. 

2. Methodological implementation to the case study 

The Lacto-fermented mozzarella cheeses were manufactured from cow’s milk in a firm located in Reggio 
Calabria, southern Italy. About four mozzarella cheeses (weighting 125 g each) were then packaged in 
polypropylene trays with tap water (control) and an alternative governing liquid consisting of 0.2 % calcium 
lactate + bergamot extract solution (CL-B). The samples were stored at 5 °C and several microbiological and 
chemical-physical indexes were monitored to 18 days. All the analyses were conducted in triplicate and 
statistically analysed by ANOVA one-way using SPSS Statistics 17.0 software.  
After the technological check of CL-B, an environmental and economic evaluation was performed in order to 
define the effectiveness of innovative solution. The environmental analysis was made through the LCA 
methodology (ISO, 2006a and 2006b) by evaluating as Functional Unit (FU) both 1 kg of packaged product 
and 1 day of shelf life, in order to assess the effects of SLE on environmental profile. The study was extended 
from cradle to grave in order to include in the system boundaries also the unsold products (Figure 1).  
 

 

Figure 1: System boundary flow chart 

Primary data were directly collected from three different dairy farms which confer the milk to the cheese 
factory where the experimentation was made. Data on animal feeds composition were directly collected as 
well as data on feed production, water and energy consumption and waste production and treatment. Data on 
methane, ammonia, nitrogen and carbon dioxide emissions were taken from Agri-footprint (Blonk Agri-footprint 
BV, 2015) and Ecoinvent V3.3 (Frischknecht et al., 2007) database. Data on energy use in the cheese factory 

Forage
Concentrate 

feed

Concentrate 
feed + 
forage

Water

Energy

Calves

Beef

Milk

40% 40%20%

Dairy Cattles

Methane

Slurry

Manure

Ammonia

Nitrogen

Wastes

Transports

CO2

Emissions 
and wastes

Included

Meat 
production

Transports

Milk 
reception 

and cooling

Pasteurisation

Heating and 
curdling

Curd 
ripening 

Curd transfer 

Spinning and 
molding 

Hardening 
and cooling

Cheese making

Mozzarella 
Cheese

Cream

Ricotta 
cheese

Whey

Wastes

Packaging, 
distribution 

and use

Tap water

0.2% Calcium Lactate 
+ 0.05 % Bergamot 
Concentrated Juice

125g packaging

125g packaging

Transports

End of life

Excluded

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were measured through Fluke 179 True RMS Digital Multimeter instruments; data on water use were 
measured through a Water Flow Meter and data on methane gas used for heating were measured through the 
Flow Meter installed to the plant. Transports distances were measured, and classified according to the 
typology of means of transport. Data on distance travelled by final consumers were estimated. Waste water 
treatment was included using the waste scenario included in Ecoinvent 3.3 and all the packaging was 
considered as waste disposed to the municipal landfill (both consumed and unsold ones). Both dairy farms 
and cheese factory input and output were allocated in function of economic value of products (Thomassen et 
al., 2008). Data were processed through the ReCiPe midpoint impact method (Goedkoop et al., 2013). 
The same criteria were used for Life Cycle Cost evaluation, by adding to the monetized values of inputs and 
outputs, the cost of wages, the quotas and other duties, interests, land capital use and externalized services 
(Falcone et al., 2015, 2016). The computational framework proposed by Ciroth and Franze (2009) and by 
Moreau and Weidema (2015) was used, borrowing the same computational framework of LCA. Considering 
the same selling price both for control and innovative products, the adding value originated by different 
production processes was determined. Also for economic evaluations, two FUs were used in order to define 
the effects of SLE. In particular, the cost was determined per day of SL, also considering the costs for unsold 
returned goods, as lost value (Buzby et al., 2014). 

3. Results and discussion 

In Table 1 some significant qualitative parameters measured in Mozzarella cheeses are reported. Compared 
to the initial time of storage, the Mozzarella cheeses underwent several expected variations during the time, 
as a decrease of pH, NaCl %, the hardness parameter and an increase of the Total Microbial Count. The shelf 
life of the control Mozzarella sample was attested to 12 days. The CL-B sample manifested a longer shelf life 
(18 days) than the control sample that did not appear instead acceptable from both the sensorial and 
microbiological points of view. 
 
Table 1: Qualitative parameters of Mozzarella samples. ** Significance at P<0.01 

Storage time 12 18 Sign. 
Sample Control CL-B  
pH 5,98±0,02 5,56±0,01 ** 
NACl (%) 3,41±0,10 0,92±0,10 ** 
Hardness (N) 9271,54±2,14 4741,87±59,70 ** 
TMC (log CFU/g) 3,08±0,74 6,63±0,01 ** 
 
The improvement of the mozzarella shelf life corresponds, from an environmental point of view, to a minimal 
increase of impacts in all categories. However, this increase did not exceed the 1 % (see the ratio CONT./CL-
B), except for Ozone depletion and Photochemical oxidant formation, where the increase of impacts get close 
to 3 %. Analysing the findings from another perspective, using 1 day of shelf life as FU, the CL-B mozzarella 
resulted to be better than Control, with a ratio that overtake the 30 % (Table 2).Confirming other studies (e.g. 
González-García et al., 2013) milk production represents the most important hotspot, contributing for each 
impact category at least the 50 % of environmental loads, in particular for Water depletion, Agricultural land 
occupation and Natural land transformation. Impact of milk production can vary effectively, as verified also by 
the findings of Fantin et al. (2012). Ozone depletion, Urban land occupation and Fossil depletion are highly 
influenced by transports, nevertheless, significant are the impacts of cheese-making processes due to the 
high energy requirement. Insights by Palmieri et al. (2017) showed that transports have lower impacts ratio, 
however, as specified by authors, this can be attributable to the short distance from dairy farms to the 
processing plant. 
From the economic point of view, results showed a more complex scenario. Costs were equal for both 
products, except for the packaging, as the innovative solution is obviously more expensive (Figure 2). 
However, accounting as a cost the unsold product, the control scenario overtook of 2.5 % the innovative 
solution, because the SLE reduced the amount of returned goods (Figure 2). In this context, considering the 
same selling price for both solutions, the CL-B mozzarella had a higher value added (Control, 0.51 € kg-1; CL-
B, 0.65 € kg

-1). In term of costs, the gap between Control and CL-B was in favour of CL-B solution, while 
considering as FU “1 day of shelf life”, the CL-B resulted a 36.7 % better. Also from the economic point of 
view, milk represented the biggest hotspot, followed by wages and packaging, confirming results obtained by 
Durham et al. (2015). Likewise, quotas had a higher economic impact as well as electricity and other energy 
sources. 
 
 

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Table 2: Life Cycle Impact Assessment (LCIA) results 

Impact category Unit 

1 kg of product 1 day of shelf life 

CONTROL CL-B 
CONT./ 
CL-B CONTROL CL-B 

CONT./ 
CL-B 

Climate change kg CO2 eq 9.6E+00 9.6E+00 99.7% 8.0E-01 6.0E-01 132.9% 
Ozone depletion kg CFC-11 eq 5.5E-07 5.6E-07 98.3% 4.6E-08 3.5E-08 131.1% 
Terrestrial acidification kg SO2 eq 1.2E-01 1.2E-01 99.7% 9.7E-03 7.3E-03 133.0% 
Freshwater eutrophication kg P eq 1.1E-03 1.1E-03 99.7% 9.5E-05 7.1E-05 132.9% 
Marine eutrophication kg N eq 2.5E-02 2.5E-02 99.9% 2.1E-03 1.6E-03 133.2% 
Human toxicity kg 1,4-DB eq 8.5E-01 8.5E-01 99.4% 7.1E-02 5.3E-02 132.6% 
Photochemical oxidant formation kg NMVOC 1.5E-02 1.6E-02 97.1% 1.3E-03 1.0E-03 129.4% 
Particulate matter formation kg PM10 eq 2.0E-02 2.0E-02 99.2% 1.7E-03 1.3E-03 132.3% 
Terrestrial ecotoxicity kg 1,4-DB eq 2.3E-02 2.3E-02 100.0% 1.9E-03 1.4E-03 133.3% 
Freshwater ecotoxicity kg 1,4-DB eq 4.5E-02 4.5E-02 99.6% 3.7E-03 2.8E-03 132.8% 
Marine ecotoxicity kg 1,4-DB eq 3.8E-02 3.8E-02 99.5% 3.2E-03 2.4E-03 132.7% 
Ionising radiation kBq U235 eq 3.6E-01 3.6E-01 99.4% 3.0E-02 2.2E-02 132.5% 
Agricultural land occupation m2a 4.4E+00 4.4E+00 100.0% 3.7E-01 2.8E-01 133.3% 
Urban land occupation m2a 7.5E-02 7.5E-02 99.9% 6.2E-03 4.7E-03 133.1% 
Natural land transformation m2 1.1E-02 1.1E-02 99.9% 9.4E-04 7.0E-04 133.2% 
Water depletion m3 2.8E-01 2.8E-01 99.9% 2.3E-02 1.7E-02 133.1% 
Metal depletion kg Fe eq 1.6E-01 1.6E-01 99.2% 1.4E-02 1.0E-02 132.3% 
Fossil depletion kg oil eq 1.4E+00 1.4E+00 99.2% 1.2E-01 9.0E-02 132.3% 
 

 

Figure 2: Results of the economic analysis 

If the application of the 0.2 % calcium lactate + bergamot extract solution (CL-B) obviously contributed to the 
costs increasing, the decrease of economic performances was less than proportional with SLE. In this sense, 
we hypothesize that the extension of 50 % of SL could correspond to a reduction of 50 % of unsold product. 
Furthermore, considering that, from direct surveys, the total amount of unsold products represents on average 
the 9 %, the extension of six days of the Shelf Life could be sufficient to have “zero returns”, and then, 
probably, to contribute to reduce the food loss and waste. 

4. Conclusions 

The aim of this study was to evaluate, both from environmental and economic perspective, an innovative 
government liquid for lacto-fermented mozzarella cheese, in order to extend the shelf life and to reduce the 
food losses. Through LCA and LCC methodologies, the innovative solution, based on a mix of 0.2 % calcium 
lactate + bergamot extract, was compared to the Control one in order to evaluate the effectiveness of 
innovation. Results showed an extension of 50 % of the shelf life, maintaining the organoleptic characteristics, 
almost without environmental consequences. Considering the effects of SLE, the food losses are reduced 
and, consequently, the derived costs. Results were useful to highlight the main hotspots in mozzarella cheese 
production and to suggest improvements for a more sustainable management. Future studies would 

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experiment more government liquids at different concentrations, in order to identify other viable solutions to 
improve the SL of mozzarella cheese and furtherly reduce food losses. 

Acknowledgments  

This research is funded by the Italian Ministry of University and Research (MIUR) within the research project: 
PRIN 2012 - “Long Life - High Sustainability, Shelf Life Extension come indicatore di sostenibilità”. 

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