Abstract
Poultry meat production and consumption face several challenges under economic, social and environmental perspectives, and increasing concerns are associated with food loss and waste minimization. One of the main issues is related to the absence of a homogeneous and standardized separate collection of bio-waste at country level, which makes chicken bones, skin and food waste valorization a challenging goal. The present research, implementing the material flow analysis to the Italian poultry sector, aims at measuring poultry-related co-products and by-products, exploring food waste, chicken bones and skin and the current trends in the Italian bio-waste separate collection. Then, it discusses alternative separate collection strategies and sustainable consumption habits. Data have been collected according to a research triangulation approach, whereas system boundaries consider slaughterhouse, distribution and final consumption stage. It emerges that more than 1.50 Mt of live animals have been processed to obtain 0.46 Mt of fresh meat and 0.76 Mt of co-products and by-products, of which more than 0.32 Mt are represented by chicken bones and skin. In addition, more than 0.15 Mt of food waste have been recorded. The research adds an extra step towards the identification of awareness campaigns and separate collection strategies at national level.
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Introduction
Poultry meat production and consumption face several challenges under economic, social and environmental perspectives, and increasing concerns are associated with food loss and waste minimization. At present, European poultry meat production has increased (and still increases) at high rates, reaching an upsurge by 20% from 2014 to 2019 [1]. Europe represents the third market player in the poultry sector, being Poland the first producer (16%), followed by Turkey (13%), Spain and France (10%) [2]. In terms of companies, the largest European ones are localized in France, Netherlands and Italy, with, respectively, 541, 426 and 350 million animals slaughtered in 2019 [3].
The United Nations, through the proposal of the Sustainable Development Goals (SDGs), have addressed several strategies towards climate change reduction and human well-being in the field of agri-food industries [4]. Livestock production, meat processing and consumption, as well as food waste generation, impose concrete challenges either under social, environmental or financial perspective, and high rate of natural resource consumption in terms of water and energy. Therefore, environmental inventories and circular strategies become crucial [5]. It is estimated that the entire agri-food sector, from agricultural production to household and food service consumption, is responsible for approximately 29% of the entire humanity’s ecological footprint [6], highlighting the urgency to assess food production and consumption related-hidden costs [7, 8]. The agribusiness, defined as the “sum of all operations involved in manufacture and distribution of farm supplies, production operations on the farm, and the storage, processing, and distribution of farm commodities”, must be able to maximize its profit without compromising consumers satisfaction and environmental needs [9, 10]. Currently, it represents one of the major land users, as well as one of the main responsible of biodiversity and ecosystems alteration, causing more than 80% of global deforestation, 70% of freshwater use and terrestrial biodiversity loss, 52% of degraded agricultural land, 50% of freshwater biodiversity loss and 29% global greenhouse gases emissions [11,12,13]. In addition, the recent national and international strategies (e.g., “SDGs”, “Closing the Loop—An EU Action Plan for Circular Economy”, “Farm to Fork strategy”) have estimated food waste issue in more than 1.3 billion tons/per year of food thrown away along the entire supply system. This amount represents approximately 3.3 Gigatons (Gt) of CO2 equivalent (6% of total greenhouse gases emission), more than USD 1 trillion per year, over 250 km3 of blue water footprint and approximately 1.4 billion hectares of land losses [14,15,16].
The present research, through the application of the material flow analysis (MFA), explores the Italian poultry production, highlighting the importance of co-products and by-products sorting and valorization towards agribusiness sustainability and circularity. At present, the Italian meat industry is subject to the Regulation (EC) 1069/2009, which addresses the agri-food sector circularity and forces, among others, food waste minimization and proper use, assuring public and animal health, food safety, environmental sustainability and consumers’ confidence [17]. In addition, being food waste disposal a “not realistic option”, the legislative framework highlights the urgency for food waste measurement (i.e., quantification and qualification), collection and valorization, either guaranteeing financial or environmental benefits.
In the light of these premises, the present research aims at measuring poultry-related co-products and by-products, estimating food waste, bones and skin quantities from slaughterhouse to final consumption and analyzing the current trends in the Italian municipal separate collection. Further, considering the absence of a homogeneous and standardized separate collection of bio-waste at country level, it discusses alternative separate collection strategies and sustainable consumption habits towards bio-waste reduction. Although several studies applied the MFA in the agri-food sector [18, 19] with reference to food waste [20, 21], and several researches evaluated bones valorization opportunities [22,23,24], none of them assesses their quantity and evaluates their quality in the Italian poultry meat system, helping academics, managers or public authorities to enhance national separate collection targets and reach SDGs proposals. The present research tries to add an extra step in bio-waste sorting and valorization, highlighting the need to adopt homogeneous and standardized separate collection techniques.
Literature review and current trends in poultry production and consumption
The global meat consumption is expected to increase in the next decade on a global scale, either in developed or developing countries such as Asia, Latin America, Central and Eastern Europe [5]. As reported by official statistics [25], the leading country in terms of consumption is North America (over 95 kg per capita per year), followed by Oceania (70 kg) and Europe (65 kg). In addition, the average meat consumption is expected to increase at a constant rate, from 34 kg per capita in 2018 to roughly 35 kg in 2028. Among European countries, the average consumption, affected by economic development, well-being and culture differences [26], is nearly twice the global average. In terms of meat type, poultry meat represents the second most consumed typology (24 kg per capita per year) after pork (32.5 kg), with positive consumption outlooks.
As far as the production side, Italy represents an interesting case in European reality, slaughtering more than 600,000 heads in 2020 [2] and recording an increase by 13.4% compared to 2010. Moreover, the global number of Italian animals has been bred within approximately 2,690 farms essentially localized in Northern Italy (i.e., Veneto, Emilia-Romagna and Lombardy), more than 90% of national slaughtered animals have been processed by two single companies (i.e., Gruppo Veronesi, Amadori) and the total revenues has been estimated in more than USD 11 billion dollars in 2020, with an expected increase equal to USD 12 billion in 2024 [27]. In addition, considering the average European rate, the Italian poultry sector represents a concrete example of self-sufficiency intending its ability to cover all domestic consumption by domestic production. The poultry “net production” is equal to the “internal production” and records a self-sufficiency rate of more than 108%, which is expected to increase in the next few years [28, 29]. The increase in domestic production favors esports, stimulating an enhancement in the Italian trade balance. Further, an increase in internal production provokes an increase in individuals’ consumption. Related to this last issue, an exceptional surge in poultry sales compared to other meat typologies [29] has been recorded because of the COVID-19 pandemic effects that have imposed unpredictable lifestyles, improvements in smart food delivery and never experienced time management. Poultry industry shows a faster expansion to respond to an increasing demand for protein and low-fat meat but consequently its waste production grows equally fast, mainly composed of food waste, emitting over 0.6 Gt of CO2 equivalent (18% of global food waste-related emissions) [30, 31]. To improve companies’ environmental performances and enhance environmental entrepreneurship, strong waste management policies at local level are required. On the one hand, sustainable waste management practices should encourage landfill diversion through recycling, composting or energy recovery [32], enabling municipalities and single companies to produce high-added value products or biofuels (e.g., biodiesel, bio-methane) [33]. On the other hand, academics have highlighted the need to enhance waste management planning by combining material and substance flow analyses in a holistic and integrated approach [34], at the same time maximizing environmental savings and minimizing management and disposal costs [35]. Several authors have analyzed poultry production environmental impacts, from agricultural stage [36, 37] to retail, highlighting the significant role of feed production, farm management and transportation towards climate change, but final consumption research is still missing. In addition, although some previous research has investigated the poultry system in Southern Italy [38] and more recent authors have investigated local experiences in Central Italy [39], Italian poultry industry-related co-products, by-products or food waste potential seems to be still unexplored.
Research methodology
Material flow analysis and food waste definition
In line with the Commission Delegated Decision (UE) 2019/1597 [40], the research applies the MFA to assess, under quantitative and qualitative perspective, Italian poultry system-related co-products, by products and food waste, investigating the amount of food waste, chicken bones and skin on a circular economy basis. The Delegated Decision sets a “common methodology and minimum quality requirements for the uniform measurement of levels of food waste”, imposing on European Member States to report by 30 June 2022 on food waste generated in 2020 through a quality check report. In addition, such a decision states that food waste amounts should be measured and reported for each stage of the supply chain at least once every 4 years [41]. Although several food waste definitions have been proposed worldwide, an amendment to Directive 2008/98/EC [42] defines food waste as “all food that has become waste”, including among them also inedible parts not separated from the edible parts such as bones attached to meat destined for human consumption (i.e., parts of food intended to be ingested or not). Therefore, food waste occurs along the entire food supply chain, either at upstream, core or downstream stages. The present research distinguishes between edible and inedible parts, intending as food waste those edible parts not addressed to human consumption, and defining inedible parts as co-products, by-products, bones and skin. Both edible and inedible parts are defined as bio-waste.
The MFA, defined as a “systematic assessment of the state and change of materials flow and stock in space and time” [43], has been successfully applied in literature, demonstrating its utility in evaluating single products, industrial sectors or entire countries socio-economic metabolism [44,45,46]. In addition, the MFA could: (i) provide an estimation of food waste currently generates at European Member States level; (ii) compare and complement the amounts reporter by each Member State, representing a possible benchmark; and (iii) provide a consistent overview of food waste evaluation, informing on possible reduction targets [47].
The present research has applied a stepwise approach [48] and Fig. 1 illustrates the research algorithm, distinguishing among four different steps, as follows: (i) definition of material flows and identification of the “qualitative” system; (ii) calculation of flows (“quantitative” system); (iii) outlooks approach and separate collection rates estimation; (iv) interpretation of results under a sustainable perspective. As regards the bio-waste separate collection rates in Italy, Ispra [49] has been considered. Data have been processed through STAN 2.6. (substance flow ANalysis), developed by the Institute for Water Quality, Resources and Waste Management at Vienna University of Technology to balance material and substance flows within a specific system.
In terms of system boundaries and material flows (Fig. 2), the research investigates fresh poultry meat production from slaughterhouse to final consumption, either considering food service or household consumption. Upstream stages (i.e., farm management, feed storage, livestock breeding) and related food waste (e.g., dead animals) are out of boundaries, as well as the food processing industry (e.g., chicken meat-based products, nuggets). Furthermore, because the Italian poultry system could be considered 100% self-sufficient [1, 29], a closed economy scenario has been investigated, not accounting for either import or export.
Data collection
To perform an analytical mass balance research, the authors have adopted both top-down and bottom-up approaches, including either official statistics [50], scientific articles or national and international reports [1, 29, 51,52,53]. First, data are essentially related to chickens and hens (synonym for poultry, from now on) representing on national scale over 94% of total slaughtered heads, while other meat subcategories, such as turkeys (4.8%), guinea fowl (0.7%), geese (0.1%), have not been accounted. Table 1 shows national data, providing the number of slaughtered animals, total live weight, average live weight per animal, total dead weight and national incidence (%) in 2020.
The poultry yield (dead weight/live weight) is estimated at 70.86%. As far as concerns carcass allocation at slaughterhouse gate, as well as fresh meat, co-products and by-products flows along the entire food supply chain, it has been estimated that more than 75% of carcasses are destined to retail, 12% to food service (i.e., intending canteens, restaurants, hotels) and 13% to food industry. This last percentage is out-of-boundaries and refers to the production of chicken meat-based products such as nuggets, patties, burgers, sausages, and others. At the retail stage, more than 40–45% of fresh meat is distributed within modern retail shops (i.e., large-scale distribution), while approximately 55–60% at traditional retail (i.e., butchers). The poultry industry shows a significant difference compared to other meat industries (e.g., pork and beef) where an additional deboning occurs at retail and slaughterhouse, considering that whole chickens, as well as chicken wings and thighs, are usually sold and consumed at households with bones (so-called “meat on the bone” or “bone-in meat”).
Outlooks, separate collection rates and general assumptions
The authors investigate two different outlooks: (i) the baseline one, which explores material streams without considering chicken bones, skin and food waste weight along the entire food supply chain, from slaughterhouse to final consumption; (ii) the food waste–bones–skin (FWBS) outlook, which includes bones, skin and food waste streams, and focuses on food service and final consumption stages. The examination of different outlooks helps in comparing alternative perspectives and states of a system, accounting for different parameters and forecasting optimistic or pessimistic performances [54, 55]. As regards the second outlook, which includes in material flows calculations also bones, skin and food waste percentages, average component yields of chicken carcass have been considered, as follows: (i) fresh meat (59%); bones (25%); skin (16%) [56, 57]. Food waste percentages at distribution and food service/households have been estimated, respectively, at 12% and 3% [52]. Table 2 illustrates the alternative outlooks percentages.
To fill in data gaps, the authors contacted an Italian company, which is one of the highly involved representatives in the entire beef supply chain, and used the research triangulation to improve the overall validity and credibility of the data. Merging primary and secondary data, the research triangulation allows to exploit the synergistic effects of joining investigative techniques to decrease the bias [58,59,60]. In addition, considering the majority of data deriving from national reports [1, 29], international documents [2] and national official statistics [50], whereas a few information coming from scientific articles, the present research did not carry out an uncertainty analysis. As already discussed by previous studies applying the mass balance approach [61, 62], the uncertainty assessment would not have added additional value to the research.
Results
Material flow analysis (baseline outlook)
The process “slaughtering” within the “poultry meat system” encompassed three main phases [63], as follows: (i) pre-stunning, which includes arrival unloading of containers from the truck, lairage, handling/removing of birds from containers; (ii) stunning, which includes restrain; and (iii) bleeding, which includes bleeding following stunning and bleeding during slaughtering without stunning. The number of live animals entering the system is around 573 million, whose live average weight is 2.6 kg, and the total live weight is 1,505,635 t. Considering an average yield of approximately 71%, it is essential to distinguish the material composition of poultry, since live birds enter the system as inputs, but several components leave the system as outputs.
As illustrated by Fig. 3, the material streams flowing within the system are carcass, for an amount of approximately 1,068,994 t and co-products and by-products, distinguished as follows: (i) edible co-products (30,111 t); (ii) inedible offal (263,484 t); (iii) blood (52,697 t); (iv) feathers (90,338 t). Then, carcasses are addressed to three different paths, which are food service (128,179 t), distribution (801,745 t) and food industry (138,969 t). Among “distribution”, it is interesting to distinguish between traditional retail (338,838 t) and modern retail (228,628 t), where a certain amount of material streams is accounted as food waste and/or bones and skin (128,279 t), whereas at food service it is possible to estimate such a variable at 5,773 t. Therefore, the available amount of fresh meat at household consumption amounts to 673,466 t, of which 643,160 t actually for human nutritional intake and approximately 30,306 t represented by food waste, bones and skins.
Material flow analysis (FWBS outlook)
The first outlook essentially describes the easiest “poultry meat system”, illustrating the poultry flows along the supply chain, from slaughterhouse to consumption. It simply takes care of fresh meat, co-products and by-products, without considering the significant composition of food waste at food service and households, which represents a noteworthy amount on a national scale.
As illustrated by Fig. 4 (FWBS outlook), which focuses on households and food service and assumes that deboning (i.e., to obtain different meat cuts) occurs at final consumption stage, it is possible to estimate the material flows encompassed within the “poultry meat system”, distinguishing between fresh meat, bones, skin and food waste properly intended (i.e., thrown away fractions of fresh meat). Specifically, material flows at households have been estimated as follows: (i) fresh meat (383,876 t); (ii) bones (168, 367 t); (iii) skin (101, 020 t); and (iv) food waste (20,204 t), whereas at food service: (i) fresh meat (73,119 t); (ii) bones (32,070 t); (iii) skin (19,242 t); and food waste (3,848 t).
As highlighted by the FWBS outlook, the following ratios emerged: (i) bones/fresh meat = 44%; (ii) skin/fresh meat: 26%; (iii) food waste/fresh meat = 5% either for households or food service individually considered. It means that, for each ton of poultry fresh meat produced, 440 kg of bones, 260 kg of skin and 50 kg of food waste are generated, which means approximately 750 kg (three-quarters of the global final product) of material flows which must be addressed, reused or recovered under circular perspective. Table 3 presents all co-products, by-products, bones, skin and food waste to fresh meat ratio, considering as basis the sum of fresh meat as estimated in FWSB outlook (456,995 t).
The ratio to fresh meat illustrates the significant impact, in terms of weight, of several poultry meat streams within the “poultry meat system”. At slaughterhouse gate, the main secondary output associated with fresh meat production is represented by inedible offal (58%), followed by feathers (20%) and blood (12%). In addition, either at food service or households, the highest amount is represented by bones and skin, and food waste still embodies a suggestive amount.
Italian bio-waste separate collection per region
Results from the FWBS outlook reveal an amount of 200,437 t of bones, 120,262 t of skin and 24,052 t of food waste at households and food services. Considering the Italian rate of bio-waste separate collection, recorded by Ispra [49] as follows: (i) 67% at Northern Italy; (ii) 54.1% at Central Italy; (iii) 46.1% at Southern Italy, with an average Italian rate at 58.1%, it is possible to estimate the number of bones, skin and food waste properly collected and addressed at regional level at households and food service (Table 4). The expected consumption rate per region has been estimated on the basis of the average population per region, assuming a homogeneous consumption of poultry meat among Italians [64].
As results confirm, the expected rate of FWBS production does not coincide with the expected amount of FWBS collection, creating a disparity between production, collection and recycling among Italian regions, and highlighting the need for implementing/improving awareness-raising policies and collection systems at regional level. On average, approximately 58% of FWBS are collected either at food service or households, while more than 144,000 t of FWBS are still addressed to landfill as unsorted waste. Therefore, it emerges that there is still room to improve national (and local) separate collection performances and reach national targets, thereby improving environmental performances through circularization. In addition, only seven regions out of twenty have already reached the national separate collection target (65%), highlighting the need to improve separate collection among all Italian local realities. The regions which record the most critical values (i.e., far from the mean value) result Sicily, Molise, Calabria, Apulia and Basilicata, being at the same time either the major bottlenecks or the main realities on which to intervene. The most relevant circumstance is represented by the fact that this target should have been reached already in 2012.
Discussion
Bio-waste separate collection and valorization
The mass balance results, defined under quantitative and qualitative perspective, open several opportunities for material flows evaluation either for environmental and resource management, both at companies and policy-maker level [19]. The achieved results provide a significant background for the choice of best-suited recycling and/or treatment technology of poultry bones, skin and food waste.
Bio-waste valorization opportunities differ from one food industry to another and depend on quantities and types of materials available, patterns of generation, qualitative and quantitative characteristics and variability [65]. However, although usually considered low-valuable materials, food waste could be valorized into valuable compounds through different techniques, as follows: (a) anaerobic digestion to obtain biogas and biofertilizers; (b) microbial fermentation to obtain bioalcohols, biodiesel and biohydrogen; (c) enzymatic hydrolysis to obtain biopolymers, biochemicals and bioplastics; (d) clarification to obtain value added components; (e) carbonization and activation to obtain bio-sorbents; and (f) incineration, gasification and pyrolysis to obtain bioenergy, biochar and bio-oil [66,67,68]. Though separate collection rates have increased in the last years by a rate of 23.8% from 2014 to 2018, one of the main Italian challenges are related to sorting and separate collection of bio-waste streams. Italian households and food services are still not homogeneously subjected to mandatory separate collection policies throughout the national territory, increasing disparities between the Italian regions. As reported by Ispra [49], several regions have not yet reached the minimum objectives of separate collection imposed at national level, including quite all the Southern regions such as Sicily, Molise, Calabria, Apulia and Basilicata. It means that several Italian municipalities are losing the theoretical potential deriving from bio-waste sorting and recycling.
Under a circular economy perspective, although several “rethink”, “redesign” or “reuse” rules as proposed by the European Commission Waste Framework Directive cannot be applied in the field of fresh meat production, it is still possible to recycle, compost or recover chicken bones and skin for other purposes (i.e., repurpose) [69]. As stated by Raggi et al. [70], residual flows deriving from one process could be conveniently forwarded to other processes for further uses, recovering them to produce pharmaceutical substances, high-quality commodities, pet food and animal feed, technical materials, fertilizers and biogas. Though the meat sector represents one of the less environmentally friendly industries among food productions, it offers significant opportunities to maximize the conversion of “secondary raw materials” (i.e., food waste, bones, skin) into novel products. In the field of slaughterhouse by-products (e.g., inedible offal, feathers, blood), a variety of applications could be considered [71, 72]. As proposed by Boles et al. [73] and Barakat et al. [74], bones could be converted, adopting the revalorizing technique of the subcritical water or the alkaline extraction, into hydroxyapatite and collagen, as well as in novel kind of meat-based products for human consumption. Then, being skin a significant part of poultry products (16% of its carcass weight), it could be transformed, through techniques like collagen recovery, enzymatic hydrolysis and chromatographic purification, into barrier membrane, drug delivery, fibroblast scaffolds or bioengineered tissues [75, 76]. In addition, considering the average theoretical methane potential (0.52–0.55 m3/kg) embedded within food waste as proposed by Wang et al. [77], it is possible to estimate the collected FWBS methane production at approximately 104–110 million m3, with the chance of increasing its amount by additional 75–79 million m3 if the unsorted FWBS fraction is accounted. Figure 5 summarizes FBWS applications (a) and the theoretical methane potential per region (b).
Bio-waste reduction and sustainable consumption habits
It is important to highlight that bio-waste valorization opportunities should be based on their relative value, intending the number of co-products and by-products concretely reinserted into the anthroposphere. Therefore, it is possible to assume that some municipalities could produce more methane than others but are not exploiting even half of their current potential. Further, several regions have not still reached the national separate collection target, increasing the loss of potential embedded in bio-waste. As highlighted by previous authors [78], the failure in achieving these objectives depends on deficiencies in national waste management systems and illegal traffic activities, as well as on socio-cultural factors, including the lack of involvement of citizens and knowledge on the potential (and impacts) of food waste. Further, the disparities recorded between Northern and Southern regions could be related to the less development managerial culture and the lack of infrastructures. Possible solutions to increase public awareness on the importance of separate collections have been examined by Saladié and Santos-Lacueva [79], who have discussed the importance of television, radio, newspaper or online campaigns. Further, Xu et al. [80] have suggested that economic rewards work better than social influence in enhancing bio-waste separate collection.
On the one hand, technological innovation in the field of Italian separate collection seems to be still limited. On the other hand, innovation in food practices (e.g., sustainable foods, eco consumption habits) could compensate for inefficient municipal waste management by reducing bio-waste production. Considering either the social influence or the concerns about health, animal welfare and environment, an always increasing number of consumers is willing to decrease meat consumption and adopt meat-free diets (e.g., vegans, vegetarians, flexitarians), therefore limiting its related environmental, social and disposal impacts [81]. Several alternative protein sources have emerged in recent years, such as meat substitutes (e.g., grain meat substitutes, seitan, tofu), seaweed, insects and cultured meat [81, 82], which do not account for bones, skin, offal and other co-products and by-products. Italian consumers, according to van de Pas [5], seem to be interested in vegetarians and vegan phenomena since meat-free diets are perceived as healthier, whereas protection of the environment does not represent an important reason to go vegetarian or vegan. Remarkable is the Italian role in the meat substitute market, because it represents the third-largest market, accounting for more than 175 million euros in 2018. On the side of food waste-related social, environmental and financial impacts, the adoption of meat-free diets could represent an interesting opportunity towards sustainability. However, the abandonment of meat consumption does not represent an optimal solution if its related socio-economic consequences are accounted. It is necessary to intervene on individuals’ consumption habits, stressing the role of education towards sustainable behaviors and implementing separate collection at individuals’ level. As outlined by Chriki and Hocquette [82], it is impossible to reproduce the diversity of meats obtained from various species, breeds and cuts, and consumers will always be disappointed by “unnatural food”. Not-consuming does not mean not-wasting: the crucial point is to learn to consume responsibly.
Separate collection techniques and rates across Europe
Sustainable waste management programs depend on their planning and implementation at local scale. Although a decisive part in the adoption of sustainable sorting and collection behaviors depend on consumers’ attitude towards environmental protection, waste-recycling programs also depend on: (a) raw materials quality; (b) manpower skills; (c) capital funded by local governments and municipalities; (d) technologies available to collect, handle, process and reuse bio-waste; (e) market studies; and (f) political will [83, 84]. It is estimated that education of people at all levels is essential to promote public awareness and minimize environmental pollution. Therefore, to enhance sorting and collection and implement waste management programs, local authorities should identify objectives and constraints, enhance data collection, analyze the principal options and decide the best practices.
On global scale, different separate collection systems and sorting rates have been estimated. Separate collection is part of the comprehensive urban waste management system, which starts with collection and gets to disposal [85, 86]. Technically, once waste have been separated, they are usually stored at home or collected on points located on the streets, according to different techniques: (a) door to door system; (b) kerbside system; (c) drop-off points system; (d) deposit and establishment level; (e) deposit at facility level.
Latest legislative addresses have proposed the harmonization of waste separate collection across Europe [87], as to increase collection rates in already virtuous countries, strengthen sorting capacities of poorly performing regions and tackle local disparities [88, 89]. Such a proposal is based on the assumption that efficient separate collection is a precondition for high-quality recycling and preparation for reuse, preventing hazardous waste from contaminating other waste streams, communities and the environment. Although it is difficult to establish the best system, State members should work together towards the identification of common quality management systems. Further, it has been estimated that door-to-door collection schemes deliver better results and are more likely to involve consumers in the sustainable process [90], making them more aware of the waste they produce [91]. Further, door-to-door collection could be easily monitored, and unsustainable consumers are more likely to be subject to fines [92].
On a European scale, the less virtuous countries are still Malta, Greece and Romania, which account for over 90%, 85% and 80% of landfill rates. Sweden, Germany and Belgium have reached near-zero landfilling, representing at current the best European benchmarks [93]. Italy still presents remarkable room for improvement in landfilling diversion.
Conclusions
The Italian poultry sector represents an interesting example in the field of meat industries, being the most efficient in terms of yield, compared with beef and pork production. It illustrates an interesting example as regards fresh meat final consumption, either at households or food services, as chicken leg portions, whole chickens, chicken wings and thighs are generally sold and consumed with bones. Nevertheless, one of the main challenges affecting the poultry sector regards the separate collection of its related bio-waste streams. It emerges that more than 144,000 t of bio-waste are still addressed to landfill as unsorted waste, representing at the same time an economic loss and an environmental burden. Considering the theoretical methane potential embedded within sorted poultry waste, it is possible to estimate an amount of more than 104–100 million m3. Further, such an amount could be increased by 75–79 million m3, if additional chicken bones and skins are properly collected instead of being landfilled.
The research outlines the urgency to increase knowledge on the poultry bio-waste potential among final consumers, stressing the importance of creating high-added value products and bio-methane. It seems that consumers are still too much unfamiliar with food waste consequences and bio-waste separate collection, and several efforts to educate consumers to sustainable consumption, food waste prevention or food donation are required. As regards the opportunities offered by the application of the MFA, its application allows at the same time food waste measurement—required by national and international authorities—and the valuation of production chain dysfunctions, both from a technological and a managerial perspective.
As far as future research, the authors intend to explore the correlations and the cause–effect relationships between food choices based on the abandonment of traditional meat or on the adoption of meat substitutes and the amount of bio-waste at country level. It seems appealing to comprehend if bio-waste reduction could be reached by the adoption of new diets and the reduction in traditional meat consumption.
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Bux, C., Amicarelli, V. Separate collection and bio-waste valorization in the Italian poultry sector by material flow analysis. J Mater Cycles Waste Manag 24, 811–823 (2022). https://doi.org/10.1007/s10163-022-01366-0
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DOI: https://doi.org/10.1007/s10163-022-01366-0