Waste Products Research Articles

A grain boundary model of garnet growth

Numerical models for the growth of garnet are presented to evaluate the relative significance of reaction-limited growth and diffusion-limited growth following garnet nucleation after significant overstepping of the equilibrium garnet-in reaction. Reactions are only permitted among phases that are adjacent across grain boundaries and the extent of reaction at a given reaction site is scaled to the local amount of chemical affinity available to the two or three reactant phases relative to the grain boundary composition. This local affinity is dissipated as the local reaction proceeds, which changes the composition of the adjacent grain boundary “phase” and sets up chemical gradients that drive diffusion along the grain boundaries. Reactions proceed until all affinity is exhausted at which point the rock is essentially at equilibrium. Two extremes are modeled. Reaction-limited growth is modeled as infinitely rapid grain boundary diffusion whereas diffusion-limited growth is modeled by assuming that reactions proceed infinitely fast such that the supply of nutrients and removal of waste products from a reaction site is restricted by the rate of diffusion. Models are presented with model assemblages chlorite + quartz + garnet and chlorite + quartz + muscovite + biotite + plagioclase + garnet. Reaction-limited models result in garnets displaying well-formed “bell-shaped” Mn zoning profiles with all garnet crystals showing similar amounts of growth and zoning profiles. Diffusion-limited models result in mineral growth or consumption that is texture-sensitive such that the amount of consumption or production of a phase depends on the location of the crystal in the sample and the proximity of other phases. For example, the total amount of garnet continues to increase for the duration of diffusion-limited models although locally an individual garnet crystal may first grow and then be consumed. Mn zoning in models with short diffusion times display distinct “peaks” in the central garnet cores, in contrast to the bell-shaped profiles in reaction-limited models. With increasing diffusion times, these Mn zoning profiles evolve towards bell-shapes. These models demonstrate that diffusion-limited growth of garnet porphyroblasts may result in textural and compositional complexities that are not encapsulated by bulk-rock thermodynamic modeling.

The Role of Extracts of Edible Parts and Production Wastes of Globe Artichoke (Cynara cardunculus L. var. scolymus (L.)) in Counteracting Oxidative Stress.

In addition to the immature edible flower heads, the cultivation of globe artichoke (Cynara cardunculus L. var. scolymus (L.) Fiori) generates substantial quantities of by-products, including leaves, stems, and roots, which constitute potential sources of bioactive compounds and prebiotic dietary fiber. Preserving agricultural biodiversity and promoting socioeconomic development are essential for enhancing domestic production and fostering innovation. In the search for new biomolecules with antioxidant properties, this research focused on a globe artichoke landrace at risk of genetic erosion, still cultivated in the northern part of the Lazio region, known as the "Carciofo Ortano". To investigate the antioxidant properties of various globe artichoke tissues from the "Carciofo Ortano" landrace, methanolic extracts were prepared from the immature main and secondary flower heads, stems, and leaves of representative genotypes of this landrace. Additionally, extracts were obtained from the same tissues of four landraces/clones included in the varietal platform of the PGI "Carciofo Romanesco del Lazio", which served as reference genotypes: Campagnano, Castellammare, C3, and Grato 1. The antioxidant properties of these extracts were assessed using FRAP, ABTS, DPPH assays, and total phenolic content (TPC). The stem and secondary flower head extracts of two representative "Carciofo Ortano" genotypes and the Grato 1 clone, which have higher phenolic content, demonstrated the highest antioxidant activity. These extracts were therefore studied for their chemical profile using HPLC-DAD and SPME-GC/MS analysis. Additionally, the same extracts were investigated in vitro for their antioxidant capacity in differentiated SH-SY5Y cells, assessing their effects on ROS levels and the restoration of GSH levels. Furthermore, the in vivo beneficial effects of counteracting oxidative stress were evaluated in high sucrose-fed Drosophila melanogaster, as oxidative stress is a typical hallmark of hyperglycemic status. Overall, the results indicated that the edible immature inflorescences of the "Carciofo Ortano" landrace, along with the byproducts of its cultivation, are sources of raw materials containing biomolecules whose properties can be exploited for further applications in the pharmaceutical and medical sectors.

Determining the relative importance of key drivers influencing source separation behaviour of waste producers

The European Union aims to recycle 60% of its total waste by 2030, for which waste collection infrastructure and the source-separation behaviour of waste producers are among the crucial prerequisites. Proper source separation increases the chances of waste getting recycled. For this, identifying the key drivers influencing the source separation behaviour is crucial. The present study identified 12 drivers for each non-demographic and demographic category from 43 scientific publications and calculated their relative importance based on the perceptions of three groups: (i) the expert group, (ii) the population group from Leoben (Austria), and (iii) population group from Barcelona (Spain). Using the pairwise comparison matrix of the Analytical Hierarchy Process, weights were calculated based on the relative importance of the drivers. From the non-demographic category, ‘Beliefs and values’, ‘Environmental concern’, and ‘Habits’ were rated as most important, while from the demographic category, ‘Level of education’ and ‘Location’ had the highest importance. The results were discussed in terms of biodegradable plastic waste.

Enhanced Photoelectrocatalytic Performance of ZnO Nanowires for Green Hydrogen Production and Organic Pollutant Degradation.

With growing environmental concerns and the need for sustainable energy, multifunctional materials that can simultaneously address water treatment and clean energy production are in high demand. In this study, we developed a cost-effective method to synthesize zinc oxide (ZnO) nanowires via the anodic oxidation of zinc foil. By carefully controlling the anodization time, we optimized the Zn/ZnO-5 min electrode to achieve impressive dual-function performance in terms of effective photoelectrocatalysis for water splitting and waste water treatment. The electrode exhibited a high photocurrent density of 1.18 mA/cm2 at 1.23 V vs. RHE and achieved a solar-to-hydrogen conversion efficiency of 0.55%. A key factor behind this performance is the presence of surface defects, such as oxygen vacancies (OVs), which enhanced charge separation and boosted electron transport. In tests for waste water treatment, the Zn/ZnO-5 min electrode demonstrated the highly efficient degradation of methylene blue (MB) dye, with a reaction rate constant of 0.4211 min-1 when exposed to light and a 1.0 V applied voltage significantly faster than using light or voltage alone. Electrochemical analyses, including impedance spectroscopy and voltammetry, further confirmed the superior charge transfer properties of the electrode under illumination, making it an excellent candidate for both energy conversion and pollutant removal. This study highlights the potential of using simple anodic oxidation to produce scalable and efficient ZnO-based photocatalysts. The dual-function capability of this material could pave the way for large-scale applications in renewable hydrogen production and advanced waste water treatment, offering a promising solution to some of today's most pressing environmental and energy challenges.

Potensi Limbah Hasil Pertanian Padi menjadi Sumber Bioenergi melalui Konsep Biorefineri dengan Pendekatan P-Graph dan Analisis Ekonomi Teknik di Kabupaten Sleman, Yogyakarta

Agricultural waste, especially from rice such as straw, husks, and bran, is one of the abundant biomasses in Indonesia, particularly in Sleman Regency, DI Yogyakarta, which is one of the regions with the highest rice productivity. The potential of rice waste can be used as a source of bioenergy using a biorefinery approach. The concept of a biorefinery is the processing of biomass that produces various products and by-products to achieve sustainability. The analysis of the potential of this biomass waste was conducted using p-graph and techno-economics. Based on the optimization analysis with the p-graph, the optimal and maximal solutions were obtained after running the superstructure flow. The optimal solution indicates that the transesterification process of rice bran into biodiesel is more feasible with a profit of 9000 USD/year. For the maximal solution, an economic analysis was conducted because the products generated are more numerous, allowing for the implementation of a biorefinery approach. The results of the techno-economic analysis show that the production of several bioenergy products will fully recoup the initial investment by the 8th year. The IRR value obtained is 21.7%, while the MARR (Minimum Attractive Rate of Return) is 15%, indicating that the investment is viable for funding. Additionally, from an environmental perspective, the use of biomass waste for bioenergy production has a positive impact by reducing greenhouse gas emissions and pollution, as well as enhancing soil fertility through the application of biochar. From a social perspective, community-based bioenergy production can increase income, improve community welfare, enhance bioenergy production, and support energy independence and sustainability.

Reducing product waste within the retail industry: a post-COVID-19 era study on enhancing demand prediction with hybrid prediction models

ABSTRACT The retail sector faces growing challenges, particularly aligning with the European Union’s sustainable policies to minimize waste. This paper proposes a framework to address two pivotal goals: i) Introducing cutting-edge machine learning models to forecast demand within the context of a post-COVID environment. ii) Evaluating the benefits of integrating these predictive into operational strategies by measuring the reduction in overstock levels compared to traditional business practices. The hybrid Prophet-XGBoost model consistently outperformed classical and other hybridization models in terms of accuracy (lowest MAPE and WAPE), when predicting demand. This study uses data from 2019 to 2023 but excludes 2020 and 2021 due to the disruptions caused by COVID-19. Our findings reveal that relying solely on recent data from 2022 to 2023 results in lower model accuracy compared to historical imputation methods. Notably, substituting 2019 values for 2021 outperforms interpolating with data from 2022. Beyond its methodological advancements, this research introduces a novel approach to quantifying overstock reduction, contributing to both academic literature and retail practice. In this case, we observed a significant overstock issue with non-food products, likely tied to agreements between retailers and suppliers. As these products are non-perishable, retailers appear to have been less cautious in managing stock levels.

Circular Economy and Water Resources Management

Objective: Present the Circular Economy of water as a regenerative system that maintains the value of the water resource in the economy for as long as possible, minimizing losses and the production of waste. Theoretical Framework: The research is based on the concepts of Circular Economy applied to water resources, highlighting the role of efficient and regenerative management in the context of a global problem of water scarcity. Method: A narrative review of the literature was carried out with research in databases such as Science Direct, Capes and Research Gate. Relevant articles on the topics of circular economy and water resources were selected. Results and Discussion: Significant interactions between water systems and all sectors of society were identified, as well as major opportunities to create additional value through the application of Circular Economy principles. The benefits observed include environmental factors such as water protection; social factors such as ensuring the supply of drinking water; and economic factors from strategic decision-making for implementation in the water sector. Research Implications: The adoption of the Circular Economy in water resources provides a viable model to meet the growing demand for water while promoting environmental sustainability, social equity and economic viability. Originality/Value: This study highlights the Circular Economy as an innovative and sustainable solution for water resource management, offering insights on how to apply its principles to maximize value and minimize environmental impacts.

Mechanical Performance of rPET Filament Obtained by Thermal Drawing for FFF Additive Manufacturing

The growing production of plastic waste and its recycling, from a circular economy perspective, faces challenges in finding solutions that are easy to implement, cheap in labor and energy during recycling, and locally implementable to avoid transportation. This work developed and validated a methodology to address these challenges. Designed for small-scale use at home or in schools following a Do It Yourself (DIY) approach, it transforms water bottles into plastic strips, which, after passing through an extruder nozzle, become filaments with a diameter of 1.75 mm. These can replace commercially available thermoplastic filaments. Specimens produced by additive manufacturing with recycled PET (rPET) and commercial PETG showed similar mechanical properties and can serve as alternatives to commercial PETG. PETG shows higher strength (30 MPa) compared to rPET (24 MPa), a slightly higher Young’s modulus of 1.44 GPa versus 1.43 GPa, and greater strain at failure with 0.03 mm/mm against 0.02 mm/mm, making it stiffer and more ductile. This simple and widely applicable local solution may absorb a considerable amount of bottle waste, offering an economical, sustainable alternative to commercial filaments.

Pharmaceutical Waste Products and its Management

Pharmaceutical Waste Products and its Management

Leaves to Lifestyle: Raising Awareness of Responsible Production Through Eco-Print Training in Yosowilangun, Gresik

The dimension of Responsible Consumption and Production encompasses the conscientious manufacturing process of a product, with a focus on minimizing waste and residues that may pose environmental risks. Strategically situated within an industrial region, Gresik plays a pivotal role in advancing Sustainable Development Goal 12: Responsible Consumption and Production. This research endeavors to achieve a dual objective. Firstly, it aims to raise awareness about the significance of responsible production in Yosowilangun, Gresik, one of the busiest villages in the area. Additionally, the research seeks to economically empower women residing in this village. The Eco-Print fabrication employed in this study goes beyond utilizing random waste materials; instead, it leverages the recycling of dried leaves waste, a readily available resource in Gresik. Acknowledging certain limitations, such as the scale of prototype production and the ongoing nature of the study due to the gradual nature of awareness-raising efforts, this research introduces a novel aspect by uniquely applying recycled leaf waste in textile production. This approach, not extensively explored in the industry, opens a new avenue for sustainable manufacturing and women's empowerment in developing regions. The product resulting from this research is not only environmentally friendly but also holds the potential to improve the socio-economic well-being of women in Yosowilangun Village.

Mining and industrial processing wastes of phosphate rocks in Egypt: potentiality of rare earth elements

Abstract Globally, Egypt ranked the eighth position in the production of phosphorus with about 5 million tons annually. Phosphate ore is considered one of the commonest sources of rare earth elements (REEs). Mining and industrial processes (beneficiation) of phosphate ore produce huge amounts of wastes in different sizes. The present study aims to evaluate the potentiality of the phosphate ore wastes as a source of rare earth elements (REEs). The study targeted some phosphate production sites in Egypt, including: Abu Tartur, West and East El-Sebaiya phosphate mines, in addition to the fertilizers factory in Assiut. The collected waste samples, during 2023, were analyzed in terms of mineralogical composition using XRD (X-Ray Diffraction) and chemical composition using XRF (X-Ray Fluorescence). The results of chemical analysis recorded the highest concentrations of Y, Ce, La, Nd, Sc, Sm, U, and Th in Abu Tartur waste samples, while the lowest concentrations were recorded in the fertilizers factory waste samples. These wastes contain higher concentrations of REEs than the Algerian and USA wastes. Furthermore, an enrichment of the mostly environmental hazardous elements As, Cr, Cd, Pb, and Se are detected in Abu Tartur and West and East El-Sebaiya. Thus, the wastes from the industry and mining processing of phosphate represented a vital economic source for the production of REEs. The use of wastes for production of trace and rare earth elements represents an economic and environmental add value for phosphate industry.

Imprint of ancestral and modern threats in human mind – experience of fear, disgust, and anger

IntroductionThreats to our survival are often posed by the environment in which humans have evolved or live today. Animal and human ancestors developed complex physiological and behavioral response systems to cope with two types of threats: immediate physical harm from predators or conspecifics, triggering fear, and the risk of infections from parasites and pathogens leading to the evolution of the behavioral immune system (BIS) with disgust as the key emotion. Here we ask whether the BIS has adapted to protect us from pandemic risks or poisoning by modern toxic substances.MethodsWe have developed a survey comprised of 60 vignettes describing threats evoking fear and disgust belonging to one of the three main categories of threats: (1) ancestral, (2) modern, and (3) pandemic of airborne disease. Each vignette was evaluated on a 7-point Likert scale based on fear, disgust, and anger. Respondents also completed an assessment battery.ResultsThe results show that the strongest fear is triggered by modern threats (electricity, car accidents), while the highest disgust is evoked by ancient threats (body waste products, worms). Disgust does not respond to modern threat stimuli such as toxic substances or radioactivity as these evoke mainly fear and anger. A discriminant factor analysis classified nine out of 10 pandemic disgust vignettes into the ancestral disgust category, convincingly assigning the pandemic disgust threats to the ancestral type. Gender, age, and type of education were significant moderators of emotional responses across all threat categories.DiscussionOur study reveals that while fear is more context-dependent, particularly triggered by modern threats, disgust operates on an evolutionarily hardwired basis, making it less effective against contemporary risks. Furthermore, disgust experienced during a pandemic outbreak is more closely aligned with ancestral disgust-related threats tapping into evolutionary ancient survival circuits of the BIS. However, as disgust declines with age, the brain must adaptatively shift the emotional processing from disgust to fear to protect older adults from contamination risks. Finally, our study reveals that pandemic fear is better predicted by specific behaviors rather than general anxiety, suggesting a need for new assessments.

Chemical and Enzymatic Mechanosynthesis of Organocatalytic Peptide Materials Based on Proline and Phenylalanine.

In recent years, mechanosynthesis of peptides through either chemical or enzymatic routes has been accomplished. In part, this advancement has been driven due to the organocatalytic properties of peptide-based biomaterials. In this work, we report the merging of chemical and enzymatic protocols under mechanochemical conditions to synthesize peptide materials based on L-proline and L-phenylalanine. Compared to traditional step-by-step peptide synthesis in solution, our mechanochemical approach combining peptide coupling reagents with the proteolytic enzyme papain offers a more sustainable route by reducing the number of synthetic steps, shortening reaction times, increasing chemical yields, and minimizing waste production. Notably, the mechanosynthesized peptides exhibited organocatalytic activity in the asymmetric aldol reaction between cyclohexanone and 4-nitrobenzaldehyde.

Polyphenolic compounds in Sauvignon Blanc - from grapes to wine

At harvest, the metabolic composition of wine grapes reflects the accumulated effect of the environmental conditions, the stresses endured, and viticultural manipulations applied during the growing season. The role of the winemaker is to extract and nurture this “metabolite potential” throughout the winemaking process. However, it is typically difficult to relate this grape potential to that of the eventual wines. In this study, a holistic view of Sauvignon Blanc grape and wine polyphenolic compounds was attempted by measuring these compounds from different matrices, from ripe grape tissues up to the final wine, including the submatrices, such as juice, pomace and sediment. Sauvignon Blanc vines from one vineyard block were manipulated to yield berries with distinctly different phenolic potentials by creating a high light (HL) or a low light (LL) microclimate in the fruiting zone of the canopy during the growing season. The analyses of the HL and LL berries and wines, as well as concomitant analyses of the phenolic compounds in the submatrices, allowed their tracing as they were (i) transferred from one matrix to another, (ii) lost as waste products, or (iii) affected by different winemaking practices (skin contact and/or fermentation in contact with the juice sediment) implemented in the experimental design. In berries, flavonols showed the largest increase due to sun exposure (HL treatment) but were absent from the juice samples at all juice processing stages. They were however detected in the juice sediment, together with high concentrations of organic acids and sugars. Juice processing was noted for dramatic fluctuations in metabolite concentrations suggesting intense metabolic activity in this pre-fermentation matrix. Both skin contact and sediment contact treatments delivered wines with higher concentrations of coutaric acid (the ester formed from coumaric and tartaric acid) and the flavanol catechin while epicatechin concentrations was unaffected. The higher catechin concentrations did not lead to increased perceived bitterness in the wines, except in the sediment contact treatments. The total phenolic compound concentration of wine from LL (low phenolic potential) grapes was comparable to wine from HL (high phenolic potential) grapes, when skin contact, or sediment contact treatments were employed. From a sensory perspective, the sediment contact decreased the fruity aromas of Sauvignon Blanc, while the skin contact treatment enhanced the sensorial properties of the wines made from the LL grapes, allowing increased extraction from the skin-accumulated impact compounds.

Comparative analysis of torrefaction and hydrothermal carbonization of kitchen waste for sustainable biofuel production

Comparative analysis of torrefaction and hydrothermal carbonization of kitchen waste for sustainable biofuel production

Interpretable Intelligent Fault Diagnosis for Heat Exchangers Based on SHAP and XGBoost

Heat exchangers play an important role in offshore oil and gas production and offshore low-temperature waste heat power generation. Heat exchanger health management mainly relies on performance parameter monitoring; however, accurate fault mode identification remains a challenge and the diagnostic results are difficult to interpret. This paper proposed an interpretable intelligent diagnosis method for heat exchangers based on Shapley Additive exPlanation and eXtreme Gradient Boosting. Firstly, secondary parameters characterizing the health state of heat exchangers are constructed based on online monitored data such as pressure and temperature. Then, the multi-dimensional feature vector is constructed by integrating the online monitored data and secondary parameters. The XGBoost fault diagnosis model for leakage and scaling faults is established with the multi-dimensional feature vector as the input. To improve the model performance on diagnosis, a grid search optimization algorithm is adopted. After the fault diagnosis of a heat exchanger is completed, the SHAP method is introduced to analyze the contribution of features by quantifying their influence on the fault diagnosis results. Finally, the effectiveness of the proposed method is verified by the heat exchanger fault simulation experiment. The proposed method achieved a diagnosis accuracy of 99.79%, which has better performance than the traditional fault diagnosis method.

Cost-Effective Production of Bacterial Cellulose and Tubular Materials by Cultivating Komagataeibacter sucrofermentans B-11267 on a Molasses Medium.

An original design of a simple bioreactor was used to fabricate two tubular, 200 cm long BC structures by culturing Komagataeibacter sucrofermentans B-11267 on a molasses medium. In addition, a tubular BC-based biocomposite with improved mechanical properties was obtained by combining cultivation on the molasses medium with in situ chemical modification by polyvinyl alcohol (PVA). Moreover, the present study investigated the BC production by the K. sucrofermentans B-11267 strain on the media with different molasses concentrations under agitated culture conditions. The dynamics of sugar consumption during the cultivation were studied by HPLC. The structure and physicochemical properties of BC and tubular BC structures were characterized by FTIR spectroscopy and X-ray diffraction (XRD). Thus, the findings indicate that K. sucrofermentans B-11267, when cultivated in a molasses medium, which is such a cheap waste product in the sugar industry, forms a significant amount of BC with a high crystallinity degree. The BC tubular structures demonstrated great potential for their application in biomedicine as artificial blood vessels and conduits for nerve regeneration.

Composting Urban Biowaste: A Potential Solution for Waste Management and Soil Fertility Improvement in Dolisie, Congo

Population growth, urbanization, and changing consumption patterns are contributing to an increase in household waste production, particularly in sub-Saharan Africa. Composting of biowaste presents a sustainable solution by reducing the volume of waste sent to landfills while enriching the soil. The main objective of this study was to evaluate the suitability of solid household biowaste for composting in market garden crops in Dolisie (the Republic of Congo). Specifically, the study aimed to (i) assess the production and management practices of solid household waste in relation to socio-economic factors, (ii) analyze the chemical composition of solid household biowaste and its concentration of trace elements (TEs), and (iii) determine the potential phytotoxicity of solid household biowaste across different production seasons. In this study, wastes were collected from 40 households over a 60-day period, with daily sorting conducted during both the dry and wet seasons. Using a completely randomized design, various compost application rates were incorporated into the soil to conduct a germination test. The quality of the biowaste and compost was evaluated through physicochemical analyses. Results showed that approximately 90% of high-income households received regular waste collection services and practiced waste separation in contrast to middle- and low-income households. The composition of the biowaste was primarily composed of fruit and vegetable scraps, with slight contamination by chromium and cadmium. Temperature, pH, and humidity levels showed similar trends during compost formation in both the rainy and dry seasons. Germination rates were above 80% in all treatments across both seasons, indicating that the compost was mature. Overall, all physicochemical parameters of the compost met established quality standards, and trace element concentrations were below the recommended thresholds. The study concluded that biowaste, once converted into compost, can be safely applied to agricultural soils without posing any risk of phytotoxicity or contamination to crops.

Immobilization of Enzymes in Polymeric Materials Based on Polyamide: A Review

The immobilization of enzymes in polyamide-based polymeric materials through covalent bonding is an established technique to stabilize and reuse biocatalysts in industrial processes. Traditionally, enzymes are immobilized using crosslinking agents that activate functional groups on both the support and the enzyme, creating strong bonds that securely anchor the enzyme to the surface. While effective for maintaining enzyme activity over multiple cycles, this method can reduce catalytic efficiency due to rigid binding and involves complex activation steps. Recently, in situ immobilization approaches have emerged as promising alternatives. In this method, enzymes are directly entrapped within the polymer matrix during the synthesis of the polyamide support, such as nylon, simplifying the process and offering enhanced control over enzyme distribution. For instance, studies have demonstrated that in situ immobilization can improve enzyme stability by protecting it within the polymeric network, while reducing production costs and waste. This review explores the ability of polyamide as a support material for immobilization of enzymes, analyzing key techniques, performance across applications, and future strategies to optimize polymer-enzyme interactions for industrial use.

Scorpionism in the State of Bahia, Brazil: A More Neglected Problem During the Pandemic?

During the confinement in the COVID-19 pandemic, there was an increase in the production of urban waste, increasing the risk of accidents caused by scorpions. We sought to determine the clinical and epidemiologic aspects of scorpionism records in the 7 mesoregions of the State of Bahia, Brazil, examining differences in periods before and during the pandemic. Data were obtained from SINAN, Brazil's Notifiable Diseases Information System (January 2010-December 2021). Measures of morbidity (incidence and lethality) and mortality were evaluated, comparing the averages before (2018 and 2019) and during the pandemic (2020 and 2021). Sociodemographic data (ie, gender, age group, and race) and conditions of care (ie, time, classification, and evolution) were compared by mesoregion. A total of 159,982 cases of scorpionism were registered, with a higher proportion in the prepandemic period (P<0.05) and a higher average incidence in the Center South of Bahia (267.32; n=82,059; 51.29%). Most cases occurred in mixed-race individuals (61.73%), females (n=81,292; 51.22%), and individuals between 20 and 39 y of age (n=48,876; 30.55%) and most cases were classified as mild (n=136,816; 85.52%), were attended in <1 h (n=81,941; 51.22%), and progresses to cure (n=142,082; 88.81%). There were 263 deaths (0.16%), with a mortality rate of 1.77/100,000 inhabitants and a lethality of 0.16%. It is suggested that during the COVID-19 pandemic, despite the upward curve of accidents, social isolation measures and collective fear may have decreased the search for medical care after a scorpion sting, reducing notifications of the condition in the State of Bahia.