Intensive Agricultural Production Research Articles

Phosphorus availability influences disease-suppressive soil microbiome through plant-microbe interactions.

Soil nutrient status and soil-borne diseases are pivotal factors impacting modern intensive agricultural production. The interplay among plants, soil microbiome, and nutrient regimes in agroecosystems is essential for developing effective disease management. However, the influence of nutrient availability on soil-borne disease suppression and associated plant-microbe interactions remains to be fully explored. This study aims to elucidate the mechanistic understanding of nutrient impacts on disease suppression, using phosphorous as a target nutrient. A 6-year field trial involving monocropping of tomatoes with varied fertilizer manipulations demonstrated that phosphorus availability is a key factor driving the control of bacterial wilt disease caused by Ralstonia solanacearum. Subsequent greenhouse experiments were then conducted to delve into the underlying mechanisms of this phenomenon by varying phosphorus availability for tomatoes challenged with the pathogen. Results showed that the alleviation of phosphorus stress promoted the disease-suppressive capacity of the rhizosphere microbiome, but not that of the bulk soil microbiome. This appears to be an extension of the plant trade-off between investment in disease defense mechanisms versus phosphorus acquisition. Adequate phosphorus levels were associated with elevated secretion of root metabolites such as L-tryptophan, methoxyindoleacetic acid, O-phosphorylethanolamine, or mangiferin, increasing the relative density of microbial biocontrol populations such as Chryseobacterium in the rhizosphere. On the other hand, phosphorus deficiency triggered an alternate defense strategy, via root metabolites like blumenol A or quercetin to form symbiosis with arbuscular mycorrhizal fungi, which facilitated phosphorus acquisition as well. Overall, our study shows how phosphorus availability can influence the disease suppression capability of the soil microbiome through plant-microbial interactions. These findings highlight the importance of optimizing nutrient regimes to enhance disease suppression, facilitating targeted crop management and boosting agricultural productivity. Video Abstract.

Multivariate optimization of the extraction and cleaning procedure to determine neonicotinoids in honey from intensive livestock and agricultural production areas by UHPLC-MS/MS

Neonicotinoid insecticides have been associated with the decline of bee population. This study aimed to investigate the occurrence of neonicotinoids in honey samples from apiaries located in areas of intensive livestock and agricultural production in Argentina. For this purpose, a QuEChERS-based analytical method was developed and optimized using multivariate strategies to reduce the processing time and the necessary amount of salts and sorbents. Validation was based on SANTE 11312/2021 guidelines, with recovery percentages between 79 and 120 %, and limits of quantitation between 0.25 and 1.00 µg kg−1. The present study provides a highly sensitive and reliable method for ascertaining residue levels of eight insecticides in 151 honey samples using liquid chromatography coupled to mass spectrometry (UHPLC-MS/MS). The presence of three of the target analytes was determined in 13 % of the samples, indicating that honey bee colonies were exposed to neonicotinoids, especially imidacloprid and thiamethoxam. The maximum residue limits were not exceeded in any of the samples; therefore, there is no risk to consumers from the public health point of view.

Integrated analysis of ammonium origins in a Serbian anoxic alluvial aquifer: Insight from physicochemical, isotopic, microbiological data

The significance of examining groundwater quality is highlighted by the fact that 75% of the European Union population relies on groundwater for their water supply. In the Republic of Serbia, over 50% of the groundwater used for public water supply comes from alluvial aquifers, with 80–90% of this water originating from river water infiltration. This study investigates the origin of increased ammonium concentrations (up to 4.7 mgN/l) in the Danube alluvial aquifer near Kovin-Dubovac area, Serbia, a potential future regional water supply source surrounded by intensive agricultural production and an open coal mine. Comprehensive research involved statistical processing of physicochemical data (13 parameters from 33 sampling sites), isotopic analyses (δ15N–NH4 – 12 samples; δ34S–SO4, δ18O–SO4 in 5 samples), and microbiological tests (denitrifying, sulphate-reducing, iron-related, and heterotrophic aerobic bacteria in 15 samples). Factor analysis revealed significant positive loadings (>0.5) among indicators of autochthonous organic matter origin (Fe2+, Fetot, and TOC), geological matrix components (Na, H2S, Cl), and groundwater state parameters (pH, Eh, and NH4+). This multifaceted approach and the spatial concentration gradients of parameters associated within extracted principal components revealed the predominance of two NH4+ sources. The riparian zone is characterized by sediment organic matter mineralization, increased iron content, and natural ammonium origin (δ15N–NH4+ from +4.82‰ to +6.93‰) accompanied by conditions suitable for DNRA and sulphate reduction. Approaching to the hinterland lower iron and total organic matter content, accompanied by increased redox values revealed the signature of fertilizers application (δ15N–NH4+ −0.84‰ and −0.33‰), associated with denitrification influence. This multifaceted approach reduces ambiguity, providing a clearer interpretation of results when discerning the origin of nitrogen and aquifer potential for nitrogen loss or conservation in a reducing groundwater environment.

Shallow groundwater table fluctuations promote the accumulation and loss of phosphorus from surface soil to deeper soil in croplands around plateau lakes in Southwest China

The continuous excessive application of phosphorus (P) fertilizers in intensive agricultural production leads to a large accumulation of P in surface soils, increasing the risk of soil P loss by runoff and leaching. However, there are few studies on the accumulation and loss of P from surface soil to deep soil profiles driven by shallow groundwater table (SGT) fluctuations. This study used the intensive cropland around 7 plateau lakes in Yunnan Province as an example and conducted in situ monitoring of P storage in the soil profile and SGT during the rainy season (RS) and dry season (DS) as well as simulation experiments on soil P loss. The aim was to study the spatiotemporal variation in P accumulation in the soil profile of cropland driven by SGT fluctuations in the RS and DS and estimate the P loss in the soil profile driven by SGT fluctuations. The results showed that fluctuations in the SGT promoted P accumulation from the surface soil to deeper soil. The proportions of P stored in various forms in the 30–60 cm and 60–100 cm soil layers in the RS were greater than those in the DS, while the average proportion in the 0–30 cm soil layer in the DS was as high as 48%. Compared with those in the DS, the maximum decreases in the proportion of P stored as TP and Olsen-P in the 0–100 cm soil layer in the RS were 16% and 58%, respectively, due to the rise in the SGT (SGT <30 cm), while the soil TP storage decreased by only 1% when the SGT was maintained at 60–100 cm. The critical thresholds for soil Olsen-P and TP gradually decreased with increasing soil depth, and the risk of P loss in deeper soil increased. The loss of soil P was increased by fluctuations in the SGT. Based on the cropland area around the 7 plateau lakes, P storage, and SGT fluctuations, the average loss intensity and loss amount of TP in the 0–100 cm soil layer around the 7 plateau lakes were estimated to be 25 kg/ha and 56 t, respectively. Therefore, reducing exogenous P inputs, improving soil endogenous P utilization efficiency and maintaining deep soil P retention are the basic strategies for preventing and controlling P accumulation and loss in deep soil caused by SGT fluctuations.

Antibiotics, pesticides, and heavy metals contaminants of honey as affected by antibiotics usage and agricultural practices in different Egyptian environments

Background and aim Environmental pollutants and global climate changes have a negative health effect on honeybees, and increase honey contamination.The aim of this study was to test the effect of antibiotic usage and agricultural practices on the presence of a total of 461 pesticides, 30 antibiotics, and five elements traces in honey samples collected from Egyptian apiaries of different environmental conditions representing intensive, and limited agriculture production regions. Materials and methods Pesticides and antibiotic residues in honey were detected at trace levels using tandem mass spectrometry techniques Gas Chromatography-Mass Spectrometry/Mass Spectrometry and Liquid Chromatography-Mass Spectrometry/Mass Spectrometry (GC-MS/MS and LC-MS/MS). Antibiotics were detected using only Liquid Chromatography-Mass Spectrometry/Mass Spectrometry LC-MS/MS. The quadrupole inductively coupled plasma mass spectrometry technique (QICP-MS) was applied for the trace element analysis. Results and conclusion Amitraz and acetamiprid were more frequent. The highest concentration of amitraz (0.022 mg/kg) was found in samples obtained from apiaries in the north delta. Iron and zinc were the highest frequently detected elements in all the collected honey samples. Also, Cu was less frequently detected elements in honey samples with percent values of 7%. Cd and Pb were found in honey samples from apiaries in the south delta of Egypt at 20%, and 27%, respectively. Most of the collected samples were contaminated with antibiotics. A direct relation between agriculture production and uncontrolled antibiotics applications on a beehive was concluded due to the increased diseases of bees in the regions of intensive agriculture production. Only two pesticides were detected along with low concentrations of toxic elements in too low levels to exceed their ‘European Union Maximum Residue Limit’ EU MRL.

Accommodating agriculture at al-Khayran: Economic relations and settlement practices in the earliest agricultural communities of the southern Levant

Early agricultural practices are often viewed as such a radical transformation that they not only structured and drove the long-term development of subsistence economies, but also required a dramatic reorganization of how community-wide economic relations were reckoned and enacted. This article examines how data derived from loci of economic production can inform us about the structure of economic relations in early agricultural communities, so as to better test such claims of political-economic disruption against the archaeological record. It does so by analyzing the site of al-Khayran in the west-central Jordan. Al-Khayran dates to the southern Levantine Middle Pre-Pottery Neolithic B, the time period when predominantly agricultural economies first emerge in the region. Results show that a typical village-based residential group temporarily and repeatedly inhabited a substantially-built in-field structure while practicing intensive agricultural production. These results indicate that the site’s inhabitants carried out a form of dual residence mobility with heavy investment on-site in perimetrics via landesque capital. Such behavior suggests that at least some residential groups in this time period were indeed corporate groups that agentively intervened in economic systems to actively assert and enact the private holding of the means of production during the emergence of agricultural economies.

Using an Uptake Enhancer to Mitigate Nitrogen Leaching While Enhancing Uptake Efficiency

Nitrogen (N) has the most crucial influence on raising agricultural productivity of all other plant nutrients given to crops. However, 50% of the N given to crops is dissipated to the environment globally, resulting in environmental concerns due to leaching. Current research shows that intensive agricultural production systems, which are still used in a large proportion around the world, are prone to N loss. This study aimed to investigate the effect of uptake enhancer applications on N movement in the soil profile based on 10 cm depth intervals, as well as its effects on N uptake and vegetative growth of oats at 4-week intervals over a 16-week period, using sandy soil as a growing medium. Oats were cultivated in a glasshouse setting in polyvinyl chloride (PVC) columns of 60 cm in height. Six treatments were employed at the 3rd leaf growth stage, and each was replicated four times. The experiment had a constructive and a destructive part, which was employed to monitor crop N uptake at four growth stages. Analyses of soil and plant samples were carried out in all the growth stages. The treatments containing the uptake enhancer prevented N from leaching, particularly at the top 20 cm soil depth, with impressive reductions of 194% at 0–10 cm depth and 186% at 10–20 cm depth, during the first 4 weeks after planting. The uptake enhancer also promoted early vegetative growth and crop performance with 15%. In conclusion, the study revealed that employing the uptake enhancer can improve the efficacy of N fertilizer, thereby reducing the application rate of the fertilizer in agroecosystems.

The effect on the carbon footprint of the rice-wheat system of substituting chemical fertilizers by pig manure: The results of a field experiment

Livestock manure is widely recycled to enhance intensive agricultural production. Nevertheless, the environmental and agronomic benefits of liquid manure, such as biogas slurry, have rarely been comprehensively evaluated. To boost food production while maintaining environmental sustainability, a field experiment was performed to assess the effects of solid and liquid manure substitution for chemical fertilizer on direct greenhouse gas (GHG) emissions, soil organic carbon (SOC), grain yield, and carbon footprints (CF) in a rice-wheat system. The treatments involved only chemical fertilizer (NPK), 50 % NPK + 50 % pig manure (50 % PM), 100 % pig manure (100%PM), 50 % NPK + 50 % biogas slurry from PM (50 % PS), and 100 % biogas slurry from PM (100 % PS) in the circumstances of equal nitrogen fertilization. The results showed that rice CH4 emissions dominated the direct GHG emissions, and followed the order of 100%PM > 50%PM > 50%PS = NPK = 100%PS on average of three years. The 100%PM had the highest area-scaled CF with 11.84 Mg CO2-eq ha−1 due to high CH4 emissions and carbon emissions from pig manure production and compost indirectly without considering the changes in SOC stock. Meanwhile, 100%PM significantly increased SOC stock at 0–30 cm depth by 49.1 %, 11.8 %, 44.8 %, and 56.5 % compared with NPK, 50%PM, 50%PS, and 100%PS, respectively (P < 0.05). Notably, 100 % PM had the lowest area-scaled CF with 0.99 Mg CO2-eq ha−1 when considering the changes in SOC stock, followed by 50%PM. The 50%PM significantly increased the annual grain yield of rice and wheat from 2010 to 2018, with an average of 4.9 %, 4.5 %, and 5.7 % compared with NPK, 100%PM, and 100%PS, respectively (P < 0.05). Overall, although there was a trade-off between SOC sequestration and CH4 emissions under pig manure, pig manure substitution for chemical fertilizer significantly decreased yield-scaled CF, followed by biogas slurry substitution relative to NPK (P < 0.05). Thus, pig manure substitution for chemical fertilizer is recommended for environmental and yield benefits simultaneously considering the whole chain of production process in a rice-wheat system. In future, strategic fertilizer management based on PM and PS could potentially offer a sustainable solution to mitigate the trade-off and sustain the respective benefits of PM (i.e. SOC and grain yield) and PS (i.e. CH4 emissions).

Exploring the Potential of Biostimulants to Optimize Lettuce Cultivation in Coupled and Decoupled Aquaponics Systems: Growth Performance, Functional Characteristics and Metabolomic Analysis

Zero-discharge and low-input aquaponics systems are a promising alternative to the intensive agricultural and aquacultural production systems currently used, ensuring high environmental sustainability. However, new approaches and management practices are needed to increase their productivity to reach the yields of classic production systems. In this context, the present study investigated for the first time the potential of two biostimulants to improve lettuce performance in aquaponics, whether coupled or decoupled, with hydroponics serving as a control. A comprehensive evaluation was conducted to assess the plant functional (focusing on the photosynthetic process evaluation) and growth responses at the whole-plant level. In addition, the nutritional state of the leaves was determined and metabolomic analysis was performed at the cellular level, the latter also for the first time in aquaponics research. The results demonstrated the limitations that coupled aquaponics poses in relation to lettuce growth, function and metabolism, which were already obvious from the 12th day of the experiment. Indicatively, the plants grown under coupled aquaponics exhibited a notable decrease in the leaf fresh weight, potassium content and nitrogen content, with reductions of 80%, 60%, and 30%, respectively, in comparison to the hydroponics control. However, the combined physiological and metabolomic data indicate that these plants down-regulate processes and metabolism to acclimate to low nutrient levels in lettuce leaves rather than experiencing damage. The application of biostimulants did not significantly optimize the plants’ performance, though one of them appeared to be effective in improving some aspects of the photochemical efficiency. The decoupled and hydroponics systems resulted in similarly high yields and efficiency in terms of plant function, without any marked contribution from the biostimulants. We conclude that the decoupled aquaponics system has been successful in achieving yields comparable to those of hydroponics, with lower chemical inputs. Future studies should focus on examining other biostimulants in this system to further improve its performance while maintaining its environmental benefits within a circular economy framework.

Implications of current soil phosphorus levels for manureshed analysis in North Carolina

AbstractManure relocation strategies are needed to mitigate excessive phosphorus (P) application to agricultural land in areas of intensive animal agricultural production. This requires conceptual frameworks such as the manureshed, which categorizes agricultural areas according to the potential to export or receive manure for P fertilization. To further understand how the manureshed concept could be utilized, assessments of the potential implementation and necessity of the manureshed model are needed. With North Carolina at the center of the largest manureshed in the United States, North Carolina is an ideal test case to identify areas of concern for manure relocation under the manureshed framework. Swine and poultry dominate North Carolina's agricultural production, and because the vast majority of North Carolina producers are not required to limit manure applications to a P‐based rate, P accumulates. Therefore, soil test data from samples submitted to the North Carolina Department of Agriculture and Consumer Services (NCDA&amp;CS) from 2017 to 2019 were used to determine how manureshed classes defined by Spiegal et al. correspond to current soil test P levels. It was determined that 36% of counties experience very high (&gt;100 mg P kg−1; N = 36) median P concentrations in soil. Furthermore, fields cultivated with warm‐season forages had the highest mean P concentration (188 mg kg−1) and high median P trended toward counties with high animal production. Lastly, while mean soil P for all manureshed classifications fell into the very high category, manure source counties had the highest mean soil P concentrations (188 mg kg−1), which was 39%–52% higher than the other classifications. This suggests that, in addition to manuresheds classification, soil test data are needed to design and promote manure redistribution strategies.

ПРОБЛЕМЫ И ПЕРСПЕКТИВЫ РАЗВИТИЯ ОРГАНИЧЕСКОГО СЕЛЬСКОГО ХОЗЯЙСТВА В РОССИИ

Currently, more and more attention is being paid to the problems of interaction between economics and ecology. As a result, among the priorities for the development of the agricultural sector of the economy, it is advisable to consider the development of the production segment of organic agricultural products. The priority of this area is considered from the perspective of ensuring sustainable economic growth, which in the “classical” version is associated with increased pollution and environmental degradation, which has negative consequences in the form of disturbances in the agroecosystem and limits the possibilities for further development. Organic agricultural production aims to solve problems that are difficult or impossible to solve within intensive agricultural production. Providing the country's population with safe and high-quality products, as well as preserving the environment from the point of view of ensuring ecological balance, is an urgent task of the modern “green” economy. It is worth noting that the prerequisites for the development of organic production are varied; environmental and social components can be distinguished. However, today the share of the organic products segment in the domestic market is only 0,13 %. The process of development of the domestic market for organic products is hampered by the presence of certain facts, and, above all, by the imperfection of the regulatory framework governing the certification processes of commodity producers, as well as the requirements for the production of products and the export procedure. In addition, compliance with certain industry principles serves as the basis for the formation of the production of organic agricultural products in Russia. The task of developing organic production is deeply studied at the federal level; the result of this attention was the project “Strategy for the development of organic production in the Russian Federation until 2030”, which clearly outlines the goals, objectives and key indicators for the development of organic production, which allows us to highlight the directions of its development in the near future. perspective.

Impact of Inter-Row Cultivation on Potato Tuber Yields in Organic Farming

The paper highlights the surging interest in organic agriculture among both food producers and consumers in Russia. However, when transitioning from intensive agricultural production to organic technologies, certain problems arise. This applies to crop cultivation, especially potatoes, as the ban on traditional mineral fertilizers necessitates the search for rational and science-based alternative methods. (Research purpose) The study aims to investigate the impact of deep inter-row potato cultivation on tuber yield without using fertilizers. (Materials and methods) To adapt crop cultivation practices in the North-West region to organic production requirements, a six-field crop rotation, including potatoes, was implemented at the Institute of Agroengineering and Environmental Problems of Agricultural Production. The experimental field soil is characterized as soddy-podzolic and light loamy. For the experiment, the domestic potato variety Udacha was used. Continuous monitoring was conducted for the soil’s physical parameters. Inter-row cultivation was performed in two ways: hilling with harrowing using the row-crop cultivator KON-2.8 + BRU (control planting) and deep cultivation to 27 centimeter depth with the KNO-2.8 + BRU (test planting). (Results and discussion) Digital agromonitoring of environmental climatic parameters and soil physical characteristics, including hardness and moisture content, was conducted. The study examined the impact of inter-row-cultivation method on potato yields over three years. In three-year retrospective study, the highest yield of 20.57 tons per hectare was achieved in 2022, while adverse soil and climatic conditions in 2021 led to the lowest yields of 12.8 tons in the control planting and 14.19 tons in the experiment planting. (Conclusions) By creating favorable soil conditions for potato development through eliminating compaction in the rows, the increase in yield can reach 27 percent due to deep row cultivation, improved soil moisture, and moisture retention.

Land management policy shift influenced seasonal variation of erosion-induced nitrogen and phosphorus outputs from intensive agricultural catchment

A shift in policy to intensive agricultural production and land management often leads to excessive fertilizer application and accelerated erosion with consequent detrimental effects to water bodies. We investigated the impact of that shift by quantifying the spatial and temporal change in sediment sources and associated total nitrogen (TN) and total phosphorus (TP) pollutants output loads in an intensive agricultural catchment in North China across one year (November 2021–November 2022). We describe the implications of this work for intensive agriculture elsewhere in China and other countries. Seasonal sediment source apportionment was estimated at the catchment outlet using Berillium-7 (7Be) combined with compound-specific stable isotope (CSSI) signatures from sources and sediments. Diagnostic ‘fingerprints’ in MixSIAR were used to discriminate sediment sources between forest and crop farmland converted from forest (F + C(F)), crop farmland (C), and vegetable farmland (V). Our study identified F + C(F) as the dominant sediment source (mean 55.24 ± 2.91 %), intermediate on V (mean 30.06 ± 2.20 %), and least on C (mean 14.70 ± 2.13 %). Sedimentation ranged from 37.98 ± 3.02 to 89.60 ± 12.68 t·ha−1·event−1 and coincided with shifted land use policy and rainfall distribution. The TN and TP in sediment were both mainly derived from F + C(F) (averaged 22.27 ± 4.26 t·event−1 and 11.62 ± 2.28 t·event−1) and least from V (averaged 1.63 ± 0.29 and 2.09 ± 0.33 t·event−1). Despite being a significant sediment source, V contributed little sediment TN and TP input for eutrophication. Our findings imply that F + C(F) are diffuse sources of catchment pollution over the short term. These results describe the successful use of CSSI and 7Be to cost-effectively quantify the seasonal variation of sediment TN and TP loads from land-use-specific sources in the catchment under shifting land management policy in China with potential for use elsewhere. These findings enable soil conservation strategies and land management practices optimized for implementing targeted pollutant abatement initiatives in intensive agriculture in China and elsewhere.

Index-Based Groundwater Quality Assessment of Nestos River Deltaic Aquifer System, Northeastern Greece

The Nestos River delta is one of the most important and sensitive basins in Greece and Europe due to its ecosystem functions, combining intensive agricultural production with low-enthalpy geothermal energy and important ecotopes. High water quality is of paramount importance to the sustainability of the system. Systematic and continuous assessment of water quality needs to be carried out in a way that is easy and quick for decision makers and non-expert societal partners to comprehend. In this way, decisions may be made more rapidly, and involved water users may be sensitized to rational water use. To this end, this paper presents the assessment of groundwater quality in the Nestos River’s western delta with the use of Poseidon (PoS), a versatile, index-based method. Groundwater samples collected from 24 and 22 wells tapping the unconfined and the confined aquifers, respectively, in four time periods (May and October 2019 and 2020) were analyzed. Using the PoS index, groundwater samples were classified according to their quality status, highlighting the parameters driving quality degradation issues, thus assisting water managers in obtaining an overview of quality status and evolution through datasets that were often large. PoS index is applied in the study area for the first time and provides a groundwater quality assessment through a unique score representative of the overall water quality status regardless of processes (anthropogenic or natural) or any kind of pressures.

Intercropping Systems to Modify Bioactive Compounds and Nutrient Profiles in Plants: Do We Have Enough Information to Take This as a Strategy to Improve Food Quality? A Review.

Various environmental, food security and population health problems have been correlated with the use of intensive agriculture production systems around the world. This type of system leads to the loss of biodiversity and natural habitats, high usage rates of agrochemicals and natural resources, and affects soil composition, human health, and nutritional plant quality in rural areas. Agroecological intercropping systems that respect agrobiodiversity, on the other hand, can significantly benefit ecosystems, human health, and food security by modifying the nutritional profile and content of some health-promoting bioactive compounds in the species cultivated in this system. However, research on intercropping strategies focuses more on the benefits they can offer to ecosystems, and less on plant nutrient composition, and the existing information is scattered. The topic merits further study, given the critical impact that it could have on human nutrition. The aim of this review is therefore to collect viable details on the status of research into the profile of nutrients and bioactive compounds in intercropping systems in different regions of the world with unique mixed crops using plant species, along with the criteria for combining them, as well as the nutrients and bioactive compounds analyzed, to exemplify the possible contributions of intercropping systems to food availability and quality.

Progress towards a more sustainable and equitable food system in Brazil?

Introduction: Brazil’s agri-food sector, traditionally being a low productivity sector, has evolved towards significant investment in technology-driven large-scale agribusiness, making Brazil a major food exporter. An increase in intensive large-scale agriculture production, while benefiting Brazil’s economy and export revenues, has also resulted in significant social and environmental externalities. With the aim to improve food security and more equitable access to food, Brazil’s federal government has intervened with a range of policies and initiatives to eliminate hunger and incentivize more sustainable practices for improved environmental outcomes. Objective: The paper provides an overview of the agri-food policy landscape, and policy innovations since the early 2000s intending to drive a transition towards a more sustainable and equitable agri-food system. Results and Discussion: It also highlights the challenges in implementing policies and programmes in the context of Brazil’s agrarian structures, vested interests and political conflicts surrounding the allocation of public assets. Successful implementation will require further innovation, collaboration and inclusive partnerships to foster food system transformation pathways towards the achievement of the Sustainable Development Goals.

Contextualization Matters: Beyond Abstract, Normative and Universal Approaches

The negative ecological, health and social impacts of intensive agricultural production and deforestation, coupled with rapid urban and suburban development motivated some architects, land-use planners, landscape and urban designers last century to consider how the morphology and size of human settlements impact on natural and human ecosystems at local, regional and global levels. Some initiatives 50 years ago, including the seminal contributions of Constantinos A. Doxiadis, John Habraken, Victor Papanek (among others), preceded current concerns about complex people-society-environment-biosphere interrelations in a rapidly urbanizing world. Notably, the United Nations 2030 Agenda for Sustainable Development and the New Urban Agenda recognize these dilemmas, but these initiatives have not borne anticipated outcomes since 2015. This article explains that the proposed responses to these societal challenges by these international initiatives have devalued fundamental elements of ekistics that combined and synthesized five forces - economic, social, political, technical and cultural factors in a holistic and systemic model. In addition, abstract, dogmatic, normative, and universal approaches commonly used in architecture and urban planning during the last century have remained dominant. The author requests a fundamental rethinking of key drivers of rapid urbanization that need to be understood and corrected according to the diversity and plurality of contextual conditions in which human settlements are constructed. These can be identified and accommodated in Living Labs which are creative real-world settings that explicitly reconnect knowledge and praxis about human habitats, thus overcoming the current deficit in implementing the SDGs, and in particular SDG 11.

Innovative Soil, Water and Plant Management Promoting Sustainable Agriculture and Environments :A Review

There is a lot of pressure on today’s agricultural producers to fulfill the increasing food needs brought on by a growing population and a shrinking supply of land and other resources. In order to meet this challenge, many people are using excessive amounts of fertilizers and other chemicals. The soil health, land quality, and environmental impacts have all suffered as a result of this intense agricultural production that disregards ecological sustainability. So, future attempts to feed the expanding population should strive for higher agricultural productivity within sustainable ecosystems. In this context, creative initiatives are required, since business-as-usual approaches lack the capacity to deal with these issues. Agricultural sustainability is defined, and various soil and crop management strategies that aim to maximize crop yield under environmentally sustainable conditions are discussed. These include, but are not limited to, nutrient management, site-specific nutrient management, fertility management, integrated soil-crop system management, sustainable water management, and water conservation. In addition, nutrient management, fertility management, and integrated soil-crop system management have been shown to improve crop yields. According to this analysis, a sustainable production system may be created by integrating the many initiatives found in SCMS practices with both immediate and long-term preventative actions. Reducing chemicals’ consumption, such as that of fertilizers and pesticides, with improvements in the agricultural input use efficiency might cut greenhouse gases emissions while safeguarding the environment. The future of humanity and Earth depends on the success of sustainable agriculture, which has promise if both rich and developing countries work together to pursue ‘our shared destiny’ in order to increase food production with little impact on the environment.

Adapting and applying the rewilding score to assess the biodiversity potential of cattle-oriented farms

The loss of biodiversity in agricultural landscapes is caused mainly by intensive agricultural production, especially livestock farms. However, certain farms that favor biodiversity attempt to decrease this loss, and the biodiversity hosted by these farms needs to be assessed. To this end, certain methods assess integrated variables of the overall state of an ecosystem. Among them, the “rewilding score” is based on assessing human forcing (i.e. inputs used in the ecosystem and products exported from the ecosystem) and ecological integrity to consider short-term and long-term effects of human activities on ecosystems. This study aimed to adapt the rewilding score for cattle-oriented farms, apply the method, and compare its results to observed biodiversity in order to discuss the relevance of the adapted rewilding score for assessing the biodiversity potential of livestock farms. Two adapted rewilding scores were tested with seven farms by combining one assessment of human forcing with two approaches for estimating ecological integrity. Biodiversity indices based on bird species inventories were calculated and compared to the adapted rewilding scores. Their moderate correlations with the adapted rewilding scores (r = 0.54–0.69) supported using this score to assess one type of biodiversity potential of agroecosystems. Nonetheless, the correlation between the adapted rewilding score and biodiversity remains to be confirmed by using biodiversity indices for other taxonomic groups and for a larger set of farms. This method could be used as a decision aid by farmers or as a tool to help governments calculate subsidies by considering short-term and long-term effects of livestock farms on biodiversity.

Agricultural frontiers and environment: a systematic literature review and research agenda for Emerging Countries

AbstractDespite having the largest land and water reserves for agriculture on the planet, intensive agricultural production in emerging countries has stimulated research around the world, especially due to the numerous environmental impacts caused by the expansion of agricultural frontiers. Motivated to analyze the literature on the transformations brought about by the development of intensive agriculture since the middle of the twentieth century, this study analyzes the main studies on the interference of agricultural frontiers on the environment in emerging countries over the last 30 years (1993–2022). To do so, the Systematic Literature Review methodology was used, with the CIMO planning approach and the Preferred Reporting Items for Systematic Review and Meta-Analysis Protocols (PRISMA-P) reporting guideline. The analysis initially included 14,366 scientific articles from a wide range of subjects in the social and natural sciences, available on the Web of Science (Clarivate Analytics), ScienceDirect (Elsevier), and Google Scholar databases. One of the most significant findings of this study is that there is no specific framework to analyze the relationship between the agricultural frontier and the environment in developing countries; however, literature has mainly been concerned with measuring the impact of intensive agriculture on natural resources, as well as verifying how local socio-economic factors and/or public policies affect populations’ behavior regarding this relationship between the environment and agricultural production. The data also revealed that Brazil is the “country of origin” of the literature on agricultural frontiers and the environment, especially due to studies on the Amazon rainforest, followed somewhat distantly by studies on South America in general and the island regions of Indonesia and Malaysia. There is also a lack of studies on European economies in transition, emerging African countries and Russia, or on the agri-environmental impact of the demand for food in populous countries such as India and China. Finally, in addition to country-specific suggestions, this systematic literature review suggests directions and implications for future research.