Mobile Potato Leaf Disease Detection Using Ensemble Learning | InformativeBD

Karen W. Cantilang, and Laarni M. Ladiao, from the institute of Philippines . wrote a Research article about, Mobile Potato Leaf Disease Detection Using Ensemble Learning. Entitled, Mobile-based potato leaf disease identifier using ensemble modeling. This research paper published by the International Journal of Biosciences | IJB. an open access scholarly research journal Biosciences. under the affiliation of the International Network For Natural Sciences| INNSpub. an open access multidisciplinary research journal publisher.

Abstract

Potato leaf diseases pose a significant threat to crop productivity, necessitating accurate, accessible, and real-time diagnostic solutions. This study proposes a mobile-based potato leaf disease identification system using ensemble modeling to improve classification accuracy and support early disease detection in agricultural environments. The system classifies seven categories, including six disease types—bacteria, fungi, nematode, pest, Phytophthora, and virus—and one healthy (normal) class. A dataset of 3,000 potato leaf images was utilized following the Knowledge Discovery in Databases (KDD) framework, including data selection, preprocessing, transformation, data mining, and evaluation. Deep feature extraction was performed using the Inception v3 convolutional neural network to generate high-dimensional image embeddings. These features were classified using Support Vector Machines (SVM) and further enhanced through a stacking-based ensemble approach to improve predictive performance. Experimental results show that the proposed model achieved an overall classification accuracy of 88% and a macro-averaged Area Under the Curve (AUC) of 0.92, demonstrating strong discriminative capability across all classes. The ensemble model outperformed individual classifiers, particularly in distinguishing visually similar disease categories. The system is designed for mobile deployment with both online and offline functionality, making it suitable for real-world agricultural applications, especially in resource-limited settings. This study highlights the effectiveness of integrating deep learning-based feature extraction with ensemble learning techniques for robust plant disease detection and scalable precision agriculture solutions.

Read more : Curry Leaf (Murrayakoenigii): A Rich Source of Beneficial Fatty Acids | InformativeBD 

Introduction

Potatoes are one of the most important food crops globally, providing sustenance and economic benefits to millions of people (Dolničar, 2021). However, their productivity is often threatened by various leaf diseases, such as early blight, late blight, and bacterial wilt, which can significantly reduce yield quality and quantity. These diseases spread rapidly if not detected and treated promptly, resulting in substantial losses for farmers (Muzammil Khan et al., 2024). Traditional methods of disease identification rely heavily on visual inspection by farmers or agricultural experts, which can be time-consuming, prone to human error, and inaccessible to many smallholder farmers, particularly in remote areas. Recent research highlights the potential of deep learning and computer vision techniques for automated potato leaf disease detection, addressing limitations of traditional visual inspection.

Recent advancements in artificial intelligence (AI) and machine learning (ML) have revolutionized plant disease detection by enabling automated image-based diagnosis. A mobile-based potato leaf diseases identifier using ensemble modeling offers a promising solution by combining the strengths of multiple machine learning algorithms to analyze leaf images captured through a smartphone camera. Ensemble modeling, which integrates models such as convolutional neural networks (CNNs), random forests, and support vector machines (SVMs), improves prediction accuracy by aggregating predictions from different models. This approach minimizes errors, enhances reliability, and ensures consistent disease identification across various environmental conditions, empowering farmers to take timely and appropriate action (Ahmed and Reddy, 2021).

Despite the potential of AI-based disease detection systems, most existing models are limited by their reliance on a single algorithm, which often results in lower accuracy and susceptibility to variations in environmental factors, such as lighting and leaf orientation. While CNNs excel at feature extraction, their performance may be compromised when dealing with noisy data, making it essential to incorporate additional models to improve overall classification performance. Ensemble modeling addresses this limitation by combining the strengths of diverse algorithms, ensuring a more robust and accurate disease identification system. However, the application of ensemble modeling in mobile-based disease identification for potato plants remains underexplored, highlighting a critical research gap.

Moreover, most current mobile-based disease detection applications focus primarily on highvalue crops, such as tomatoes and apples, with limited attention given to potato plants, despite their economic significance. Existing studies often neglect the unique characteristics and challenges associated with identifying potato leaf diseases, including overlapping symptoms and variations in disease progression.

Furthermore, many available solutions are designed for laboratory or controlled environments, limiting their practicality for realworld deployment in agricultural settings (Jafar et al., 2024). Addressing this gap by developing a mobile-based potato disease identifier that utilizes ensemble modeling can significantly enhance disease management practices for potato farmers, particularly in developing regions.

This study aims to fill this research gap by developing a mobile-based potato leaf diseases identifier that leverages ensemble modeling to improve classification accuracy and provide real-time, actionable insights to farmers. By combining the predictive power of CNNs, random forests, and SVMs, the system will offer a more reliable, cost-effective, and user-friendly solution for detecting and managing potato leaf diseases. The successful implementation of this technology has the potential to improve potato yield, reduce crop losses, and contribute to the overall sustainability of agricultural practices.

The main objective of this study is to develop a mobilebased potato leaf disease identification system using ensemble modeling to enhance classification accuracy and support early disease detection. To achieve this goal, the study is guided by the following specific objectives:

1. To collect and pre-process a dataset of potato leaf images, including six disease categories—bacteria, fungi, nematode, pest, Phytophthora, and virus— along with a healthy (normal) class.

 2. To develop a classification model using deep feature extraction (Inception v3) combined with Support Vector Machines (SVM) and a stacking-based ensemble learning approach.

 3. To evaluate the performance of the proposed model using standard metrics, including accuracy, precision, recall, F1-score, and Area Under the Curve (AUC), based on a labeled image dataset.

The scope of this study to develop a mobile-based potato leaf disease identifier using ensemble modeling to enhance disease detection accuracy. The system will allow farmers and agricultural experts to capture images of potato leaves and identify six pre-defined disease categories: bacteria, fungi, nematode, pest, Phytophthora, and virus. The model will integrate multiple machine learning algorithms for improved classification accuracy and will be evaluated based on metrics such as accuracy and precision. The mobile application will function in both online and offline modes to ensure accessibility in areas with limited internet connectivity. The study is delimited to identifying potato disease visible on the leaves. The model’s accuracy depends on the quality and diversity of the dataset, and underrepresented diseases may be harder to detect. Image quality, environmental factors, and overlapping disease symptoms could also affect classification performance. Despite these limitations, the research aims to provide an accessible and effective tool for early disease detection in potato farming.

Article source : Mobile-based potato leaf disease identifier using ensemble modeling 

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Curry Leaf (Murraya koenigii): A Rich Source of Beneficial Fatty Acids | InformativeBD

 

Shahin Aziz, from the institute of Bangladesh. wrote a Research article about, Curry Leaf (Murraya koenigii): A Rich Source of Beneficial Fatty Acids. Entitled, Murraya koenigii (Linn.) Spreng.: An opulent source of fatty acid. This research paper published by the International Journal of Biosciences | IJB. an open access scholarly research journal Biosciences. under the affiliation of the International Network For Natural Sciences| INNSpub. an open access multidisciplinary research journal publisher.

Abstract

Murraya koenigii L., a medicinal plant utilized in traditional folk medicine, possesses anti-diabetic, anti-microbial, anti-inflammatory attributes and also is widely used for the treatment of hemorrhoids, itching, leukoderma, and hematological disorders. From the present work, total 8 fatty acids were identified by Gas Chromatography–Mass PSpectrometry (GC-MS) technique where the level of saturation in the fatty acid derived from the petroleum ether extract of the aerial section of Murraya koenigii L. is significantly higher compared to unsaturated part. The saturated portion includes capric acid, myristic acid, palmitic acid, stearic acid and arachidic acid while palmitic acid is obtained at higher concentration (35.07%). Conversely the unsaturated portion comprises oleic acid, linoleic acid, α-linoleic acid where oleic acid covers a significant concentration (17.31%). In connection to the above findings, the current study indicates that the significant presence of fatty acids such as palmitic acid, oleic acid, α-Linolenic acid may contribute to the recognition of the potential pharmacological significance of this plant in the treatment of illnesses.

Read more : Temperature Effects on Melon Fly Development in Senegal Watermelon Crops | InformativeBD 

Introduction

Plant parts such as the flower, leave, root; bark, seed, and fruit have been used in herbal and ayurvedic medicine since time immemorial (Basit et al., 2023; Shahin et al., 2016). Continuous and extensive research revealed that medicinal plants are the prime source of new bioactive compounds and healthcare products with therapeutic qualities (Banso et al., 2007; Ivanova et al., 2005; Shahin et al, 2019). Through the successive extraction and characterization of numerous phytochemicals from the vast natural repository, several drugs with high activity profiles were identified and industrially synthesized (Mandal et al., 2007, Misra et al., 2009).

Murraya koenigii L., a member of the Rutaceae family, is frequently referred to as "kamini, Kariaphuli, Gandhal, Curry Pata" in Bangladesh. It is strongly aromatic deciduous shrub or small tree having clusters of small white flowers, small ovoid black fruits, and fragrant leaves grown across the different regions of Bangladesh as well as tropical and sub-tropical areas in the world (Abdelwahab et al., 2023). The leaves of M. koenigii are used as spice to season a variety of meals, though they are most frequently employed in curries. Curry leaves are exceptionally abundant in chemical constituents such as essential oil, tannins, resin and crystalline glucoside, koenigin (Ghani, 1998) with a variety of pharmacological and biological activities, for an instance, antidiabetic (Arulselvan and Subramanian, 2007), antioxidant (Baliga et al., 2003), antimicrobial (Abhishek et al., 2010), hepatoprotective (Pande et al., 2009), antiinflamatory (Muthumani et al., 2009), antihyper cholesterolemic (Iyer et al., 1990), effective action against colon carcinogenesis (Iyer et al., 1990), increasing of digestive secretions, relief from nausea, indigestion, vomiting, diarrhea, dysentery, fever and snakebite as well as nutritional and fragrant properties (Ghani, 1998; Abdelwahab et al., 2023, Shashank et al., 2020). Furthermore, girinimbin was obtained from the stem-bark part while the flowers contain a significant quantity of mono- and sesquiterpenoids.

The primary terpenoids found in the flowers are beta-caryophyllene, beta-ocimene, and linalool (Ghani et al., 1998). In addition, both free and complex lipid-bound fatty acids are essential for metabolism because they function as a metabolic fuel, storing and transferring energy, as a building block of all membranes, and as a gene regulator. Fatty acids are essential for mechanical protection, electrical and thermal insulation, and complex lipids. Fatty acids' amphipathic qualities and ability to form micelles additionally provide them a variety of industrial uses as soaps and detergents (Furuhashi et al., 2008). Three most abundant unsaturated fatty acids (UFAs) in plants are oleic acid (918:1), linoleic acid (918:2), and α-linoleic acid (18:3), all of which consist of 18 carbon atoms. These relatively simple compounds serve as constituents and regulators of glycerolipids, triacylglycerols as a carbon and energy reservoir, stores of constituents of the extracellular barrier such as cutin and suberin, predecessors of different biologically molecules like nitro alkenes and jasmonates, and regulators of stress signaling. However, they have the ability to cause oxidative stress (He et al., 2020).

According to literature study, M. koenigii has been subjected to numerous investigations. Many of the chemical components of M. koenigii show signs of pharmacokinetic response. As per plant science, different geographic locations, climatic circumstances and environmental influences produce non-identical plant secondary metabolites linked to physiological variances in plants.

For this reason, a number of thorough scientific investigations on the effectiveness of the entire plant or specific parts in various extract have been accomplished for medical purposes. However, fatty acid profiling by GC-MS analysis of aerial sections of M. koenigii has not been reported at all. Therefore the current study focuses a comprehensive GC-MS assessment of the fatty acid compositions in the aerial sections of the petroleum ether extract of M. koenigii, a species native to Bangladesh.

Reference

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Arulselvan P, Subramanian SP. 2007. Beneficial effects of Murraya koenigii leaves on antioxidant defense system and ultrastructural changes of pancreatic β-cells in experimental diabetes in rats. Chemico-Biological Interactions 165(2), 155–164. https://doi.org/10.1016/j.cbi.2006.10.014

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Banso A, Adeyemo SO. 2007. Evaluation of antibacterial properties of tannins isolated from Dichrostachys cinerea. African Journal of Biotechnology 6(15), 1785–1787. https://doi.org/10.5897/AJB2007.000-2262

Basit MA, Arifah AK, Chwen LT, Salleh A, Kaka U, Idris SB, Farooq AA, Javid MA, Murtaza S. 2023. Qualitative and quantitative phytochemical analysis, antioxidant activity and antimicrobial potential of selected herbs Piper betle and Persicaria odorata leaf extracts. Asian Journal of Agriculture and Biology 3. https://doi.org/10.35495/ajab.2023.038

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Article source : Murraya koenigii(Linn.) Spreng.: An opulent source of fatty acid  

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Temperature Effects on Melon Fly Development in Senegal Watermelon Crops | InformativeBD

Madeleine Ivonne Mendy, Toffène Diome,  Mamecor Faye, and Mbacké Sembène, from the institute of Sénégal. wrote a Research article about, Temperature Effects on Melon Fly Development in Senegal Watermelon Crops. entitled, Effect of temperature on the development of immature stages of Zeugodacus cucurbitae (Diptera: Tephritidae), Coquillett, 1899, A major watermelon pest in Senegal. This research paper published by the International Journal of Biosciences | IJB. an open access scholarly research journal Biosciences. under the affiliation of the International Network For Natural Sciences| INNSpub. an open access multidisciplinary research journal publisher.

Abstract

Global warming strongly influences the development of Zeugodacus cucurbitae, a major pest of cucurbit crops; however, the effects of certain intermediate and high temperatures, as well as natural conditions particularly on watermelon remain insufficiently documented. The present study assessed the effect of a thermal gradient, including ambient temperature and constant temperatures of 25, 27, 30, and 33°C, on the development of the immature stages (egg-larva-pupa) of Z. cucurbitae. The results indicate that preimaginal development time exhibits a non-linear thermal response. The duration of the pupal stage decreases with increasing temperature, whereas pupal survival and total developmental time follow a unimodal pattern, characterized by accelerated development up to a thermal optimum (27°C), beyond which biological performance declines and variability increases. These findings confirm the existence of an optimal thermal window (25-27°C) for the development of Z. cucurbitae and reveal stage-specific thermal plasticity. This sensitivity to temperature fluctuations has important implication for phenological modeling, population dynamics forecasting, and the adaptation of integrated pest management strategies under climate change scenarios.

 Read more : Paddy Straw Cultivation of Volvariella volvacea: Spawn Preparation and Growth Techniques | InformativeBD 

Introduction

Climate warming is now an unequivocal scientific reality. According to Legg (2021), the global mean temperature has increased by approximately 1.1°C relative to pre-industrial levels, primarily due to anthropogenic activities, with a marked intensification of heatwaves and thermal extremes. Recent years rank among the warmest ever recorded, reflecting a persistent upward temperature trend (WMO, 2026). Beyond physical alterations, these changes directly affect biological systems by modifying the distribution, phenology, physiology, and population dynamics of living organisms (Trisos et al., 2022). Temperature is a fundamental abiotic factor governing the distribution and functioning of organisms within ecosystems (Odum, 1971; Ricklefs, 2008). Teder et al. (2022) reported that it strongly influences the growth and development of ectothermic animals. Insects are typical ectotherms, characterized by high taxonomic diversity, large population sizes, and rapid reproductive rates (Chapman, 1998; Grimaldi and Engel, 2005). Their small body size, thin cuticle, rapid heat exchange with the surrounding environment, and limited capacity to maintain a stable body temperature make them particularly sensitive to environmental fluctuations (Zeng et al., 2022). In agroecosystems, climate change regulates the geographic distribution of pests, the number of generations per year, survival rates, and synchronization with host plants (Britannica, 2026). Zeugodacus cucurbitae (Coquillett, 1899) (Diptera : Tephritidae), commonly known as the melon fly, is a major pest of tropical and subtropical cucurbit crops, causing substantial agricultural losses when populations reach high densities (Dhillon et al., 2005; Meyer et al., 2015; Zeng et al., 2022). Like other poikilothermic insects, its development is strongly influenced by ambient temperature, which affects both the duration of the immature stages (egg, larva, and pupa) and their survival (Vayssières et al., 2008; Mkiga and Mwatawala, 2015). Although several studies (Vayssières et al., 2008; Mkiga and Mwatawala, 2015; Ahn et al., 2022; Zeng et al., 2022) have examined the effects of temperature on the development of Z. cucurbitae, they rarely include watermelon-one of the fly’s principal host plants-and are generally restricted to a limited range of constant temperatures (20, 25, and 30°C). Moreover, these studies predominantly focus on populations from East Africa or Asia. According to Mwatawala et al. (2016), watermelon is the preferred host of Z. cucurbitae. In addition, intermediate temperatures (27°C) and those approaching the upper thermal tolerance limit (≈33°C) remain poorly documented in the scientific literature. The effects of natural ambient conditions, incorporating daily thermal fluctuations, have also not been directly compared with controlled constant temperatures.

Therefore, evaluating the development of Z. cucurbitae under a thermal gradient including ambient temperature and constant temperatures of 25, 27, 30, and 33°C an approach not previously implemented in Senegal helps fill a critical knowledge gap. This framework enables a more precise determination of the thermal optimum and sublethal thresholds, improves understanding of the species’ thermal plasticity, and strengthens predictive tools for population management. The objective of this study is to compare the thermal responses of the different immature stages and to identify the optimal temperature ranges for their development.

Reference

Ahn JJ, Choi K, Huang YB. 2022. Thermal effects on the development of Zeugodacus cucurbitae (Coquillett) (Diptera: Tephritidae) and model validation. Phytoparasitica 50, 1–12. https://doi.org/10.1007/s12600-022-00985-5

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Costaz TPM, Gols R, de Jong PW, van Loon JJA, Dicke M. 2022. Effects of extreme temperature events on the parasitism performance of Diadegma semiclausum, an endoparasitoid of Plutella xylostella. Entomologia Experimentalis et Applicata 170(8), 656–665. https://doi.org/10.1111/eea.13197

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Dhillon MK, Singh R, Naresh JS, Sharma HC. 2005. The melon fruit fly, Bactrocera cucurbitae: a review of its biology and management. Journal of Insect Science 5(1), 40. https://doi.org/10.1093/jis/5.1.40

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Mendy MI, Diome T, Faye M, Sembene M. 2026. A simple rearing technique for Zeugodacus cucurbitae Coquillett, 1899 (Diptera: Tephritidae), a melon pest in Senegal. Journal of Entomology and Zoology Studies 14(1), 1-5. https://doi.org/10.22271/j.ento.2026.v14.i1a.9666

Meyer MD, Delatte H, Mwatawala M, Quilici S, Vayssières JF, Virgilio M. 2015. A review of the current knowledge on Zeugodacus cucurbitae (Coquillett) (Diptera: Tephritidae) in Africa, with a list of species included in Zeugodacus. ZooKeys 540, 539-557. https://doi.org/10.3897/zookeys.540.9672

Mkiga AM, Mwatawala MW. 2015. Developmental biology of Zeugodacus cucurbitae (Diptera: Tephritidae) in three cucurbitaceous hosts at different temperature regimes. Journal of Insect Science 15(1), 160. https://doi.org/10.1093/jisesa/iev141

Mwatawala M, Kudra A, Mkiga A, Godfrey E, Jeremiah S, Virgilio M, De Meyer M. 2016. Preference of Zeugodacus cucurbitae (Coquillett) for three commercial fruit vegetable hosts in natural and semi-natural conditions. Fruits. https://doi.org/10.1051/fruits/2015034

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Teder T, Taits K, Kaasik A, Tammaru T. 2022. Limited sex differences in plastic responses suggest evolutionary conservatism of thermal reaction norms: A meta-analysis in insects. Evolution Letters 6(6), 394–411. https://doi.org/10.1002/evl3.299

Trisos CH, Adelekan IO, Totin E, Ayanlade A, Efitre J, Gemeda A, Kalaba FK, Lennard C, Masao C, Mgaya YD, Ngaruiya G, Olago D, Simpson NP, Zakieldeen SA. 2022. Africa. In: Pörtner HO, Roberts DC, Tignor MMB, Poloczanska ES, Mintenbeck K, Alegría A, Craig M, Langsdorf S, Löschke S, Möller V, Okem A, Rama B. Climate change 2022: impacts, adaptation and vulnerability. Cambridge University Press.

Vayssières JF, Carel Y, Coubes M, Duyck PF. 2008. Development of immature stages and comparative demography of two cucurbit-attacking fruit flies in Reunion Island: Bactrocera cucurbitae and Dacus ciliatus (Diptera: Tephritidae).

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Zeng B, Lian Y, Jia J, Liu Y, Wang A, Yang H, Li J, Yang S, Peng S, Zhou S. 2022. Multigenerational effects of short-term high temperature on the development and reproduction of Zeugodacus cucurbitae (Coquillett, 1899). Agriculture 12(7). https://doi.org/10.3390/agriculture12070954

Article source : Effect of temperature on the development of immature stages of Zeugodacus cucurbitae (Diptera:Tephritidae), Coquillett, 1899, A major watermelon pest in Senegal  

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Paddy Straw Cultivation of Volvariella volvacea: Spawn Preparation and Growth Techniques | InformativeBD

A. Anees Fathima, and J. Jayasree, from the institute of India. wrote a Research article about, Paddy Straw Cultivation of Volvariella volvacea: Spawn Preparation and Growth Techniques. Entitled, Spawn preparation and cultivation of Volvariella volvacea (Bull. ex Fr.) Singer on paddy straw substrate. This research paper published by the International Journal of Biosciences | IJB. an open access scholarly research journal Biosciences. under the affiliation of the International Network For Natural Sciences| INNSpub. an open access multidisciplinary research journal publisher.

Abstract 

Volvariella volvacea (paddy straw mushroom) is an important edible mushroom cultivated widely in tropical and subtropical regions due to its rapid growth, nutritional value, and medicinal properties. The present study investigated spawn preparation and cultivation of V. volvacea using paddy straw as the primary substrate. Pure cultures were established under controlled laboratory conditions, followed by spawn production and indoor cultivation. Growth characteristics, fruiting behavior, yield, and biological efficiency were evaluated. The results showed that pinhead formation occurred within 15 days, and a yield of 2.05 kg per 10 kg of substrate with a biological efficiency of 20.5% was obtained. The findings indicate that appropriate substrate preparation, environmental conditions, and spawn quality are important factors associated with successful cultivation. Despite its commercial importance, production of V. volvacea remains limited by suboptimal practices. This study provides practical insights into spawn preparation and cultivation techniques that may support improved and sustainable mushroom production.

Read more : Major Cucumber Diseases and Their Pathogens in Azerbaijan | InformativeBD

Introduction

Mushrooms are classified as macro fungi, characterized by their fleshy and distinct sporebearing fruiting bodies. They belong to the Pluteaceae family (Kotl. and Pouz) within the class Basidiomycetes (Singer, 1961) and are typically found growing above ground, in soil, or on other food substrates. Among the 12,000 known species of mushrooms, over 2,000 have been identified as edible. However, only about 35 species are widely accepted for consumption, with a limited number being commercially cultivated. Additionally, nearly 200 wild species are utilized for medicinal purposes (Chen et al., 2019). Mushrooms are regarded as a delicacy, offering high nutritional and functional value, and are acknowledged as nutraceutical products. Their appeal has increased due to various advantages, including organoleptic qualities, medicinal properties, and economic importance. Furthermore, mushrooms are being explored as a potential alternative to muscle protein, owing to their high digestibility (Vinay et al., 2021)

Mushroom sporocarps are rich in minerals such as potassium, iron, copper, zinc, and manganese. Additionally, mushrooms serve as a significant source of vitamin D, which is absent in other dietary supplements, alongside these proteins and minerals. (Pehrsson et al., 2003). The unique bioactive compounds found in mushrooms possess immunemodulating effects and enhance human immune function, thereby lowering the risk of cancer and tumor development. Nonetheless, mushroom cultivation in Asian nations commenced over 1000 years ago, with scientific cultivation beginning only in the early 20th century when pure cultures of mushrooms were developed from spores and tissues. Volvariella volvacea is the most widely cultivated edible mushroom species (Walde et al., 2006) and due to its delightful flavor, it ranks third among essential mushrooms (Ramkumar et al., 2012; Thiribhuvanamala et al., 2012) also noted for its rapid growth rate compared to other species (Rajapakse, 2011). This mushroom is also commonly referred to as paddy straw mushroom, straw mushroom, and Chinese mushroom. The first recorded cultivation occurred in China in 1822 (Chang, 1969).

The sporocarp of V. volvacea is characterized by a grayish to black, egg-shaped vulva in its juvenile stage, which ruptures to allow the pileus to expand to a nearly flat form. The straw mushroom is considered a nutritious food source (Feeney et al., 2014). It is rich in protein, phosphorus, and potassium (Ahlawat and Tewari, 2007), while being low in alkalinity, cholesterol, and fat, and is free of salt. This mushroom contains bioactive metabolites that contribute to its rich taste, flavor, and pleasant aroma, as well as notable biological properties such as antioxidant (Hung and Nhi, 2012), antimicrobial (Chandra and Chaubey, 2017), anti-inflammatory, anti-coagulant, anti-hypersensitive, and anti-cancer effects.

Paddy straw mushroom, also known as grass mushroom, derives its name from its cultivation on rice straw. This mushroom is a significant dietary component due to its rich flavor, aroma, and nutritional benefits. Scientifically classified as Volvariella volvacea, it is a Holobasidiomycete that belongs to the Plutaceae family (Mond et al., 2021). This species accounts for 6% of the global mushroom production, predominantly utilized in the South Asian region. Over 100 species of Volvariella volvacea (Bull.ex.Fr) Singh have been documented worldwide (Kurtzman and Yang, 1982). The paddy straw mushroom thrives in high temperatures, making it primarily cultivated in the tropical and sub-tropical areas of Asia, including countries such as China, Taiwan, Thailand, Indonesia, India, and Madagascar. The life cycle of Volvariella volvacea consists of six maturity stages: pinhead, tiny, button, egg, elongation, and mature stages (Najmu et al., 2022).

Depending on the geographical area and climatic conditions, V. volvacea is grown either in outdoor settings or within controlled indoor environments. The choice of substrates for cultivating V. volvacea in a specific nation is primarily determined by the quantity of accessible free resources (Amir et al., 2023).

Mushroom cultivation is a significant and lucrative agribusiness that offers employment opportunities for rural women. The paddy straw mushroom grows rapidly allowing for harvest within two weeks of bed preparation. The demand for mushrooms is rising daily in Odisha. The agro-climatic conditions in Odisha are ideally suited for the cultivation of paddy straw mushrooms (Mijan, 2024). Nevertheless, most of the edible fungi that are presently cultivated belong to medium- and low-temperature varieties, while hightemperature varieties are quite scarce; this results in a limited availability of edible fungal varieties in the market during the high-temperature season (Ali et al., 2024). These circumstances also contribute to the consistently high price of V. volvacea throughout the year, potentially enhancing the profits for mushroom farmers in comparison to those of other edible fungal varieties (Wang et al., 2025). The present investigation was carried out to find out the spawn preparation, cultivation of Volvariella volvacea on paddy straw substrate and supplements for yield enhancement.

Reference

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Ali S, Yousaf N, Usman M, Javed MA, Nawaz M, Ali B, Azam M, Ercisli S, Tirasci S, Ahmed AE. 2024. Volvariella volvacea (paddy straw mushroom): A mushroom with exceptional medicinal and nutritional properties. Heliyon 10, e39747.

Amir NF, Mohd-Aris A, Mohamad A, Abdullah S, Yusof FZ, Umor NA. 2023. Spawn production and cultivation technology for Volvariella volvacea: A perspective. Food Research 7(4), 93–101.

Chandra O, Chaubey K. 2017. Volvariella volvacea: A paddy straw mushroom having some therapeutic and health prospective importance. World Journal of Pharmacy and Pharmaceutical Sciences 6(9), 1291–1300.

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Chen X, Zhang Z, Liu X, Cui B, Miao W, Cheng W, Zhao F. 2019. Characteristics analysis reveals the progress of Volvariella volvacea mycelium subculture degeneration. Frontiers in Microbiology 10, 2045.

Feeney MJ, Dwyer J, Hasler-Lewis CM, Milner JA, Noakes M, Rowe S. 2014. Mushrooms and health summit proceedings. The Journal of Nutrition 144(7), 1128S–1136S.

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Gurudevan T, Subbiah K, Karupannan M, Velappa P, Sakthivel K. 2012. Improved techniques to enhance the yield of paddy straw mushroom (Volvariella volvacea) for commercial cultivation. African Journal of Biotechnology 11(64), 12740–12748.

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Luu TTH, Bui DK, Huynh N, Le TL, Green ID. 2022. Effect of the cultivation technology on the yield of paddy straw mushroom (Volvariella volvacea). Korean Journal of Mycology 50, 161–171.

Mijan HMD. 2024. Evaluation of different substrates and supplements for growth and yield of paddy straw mushroom (Volvariella volvacea). The Pharma Innovation Journal 13(5), 96–99.

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Najmu S, Farahanaz R, Shaheen KJ, Amreena S. 2022. Cultivation of paddy straw mushroom (Volvariella volvacea) under Kashmir conditions. The Pharma Innovation Journal 11(4), 397–399.

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Thiribhuvanamala G, Krishnamoorthy S, Manoranjitham K, Prakasam V, Krishnan S. 2012. Improved techniques to enhance the yield of paddy straw mushroom (Volvariella volvacea) for commercial cultivation. African Journal of Biotechnology 11(64), 12740–12748.

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Vinay KY, Akhilesh C, Abhishek K, Ishani M, Anju AA, Shivam S. 2021. Cultivation technology and spawn production of Volvariella volvacea: Paddy straw mushroom. The Pharma Innovation Journal 10(5), 1184–1190.

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Wang L, Qin D, Qian G, Lei Z, Lin Y, Changxia Y, Yan Z. 2025. Dynamics of nutrient components and microbial communities in substrates during the development of the fruiting bodies of Volvariella volvacea. Journal of Fungi 11(7), 479.

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Zhu L, Jianhao W, Linzhi K, Yang P, Luyao Y, Hui Z, Ming L. 2024. Exploring the influence of culture environment on the yield of Volvariella volvacea based on microbiomics. Horticulturae 10(3), 204.

Article source : Spawn preparation and cultivation of Volvariella volvacea (Bull. ex Fr.) Singer on paddy straw substrate  

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Major Cucumber Diseases and Their Pathogens in Azerbaijan | InformativeBD

K. F. Bakhshaliyeva, A. Kh. Rajabli,  A. G. Eyvazov, G. A. Gasimova, and P. Z. Muradov, from the institute of Azerbaijan. wrote a Research article about, Major Cucumber Diseases and Their Pathogens in Azerbaijan. Entitled, The main diseases of cucumber (Cucumis sativus L.) grown in the Republic of Azerbaijan and the species composition of pathogens of these diseases. This research paper published by the International Journal of Biosciences | IJB. an open access scholarly research journal Biosciences. under the affiliation of the International Network For Natural Sciences| INNSpub. an open access multidisciplinary research journal publisher.

Abstract

Cucumis sativus L. plant cultivated in open and covered conditions in the Republic of Azerbaijan, was studied for phytopathogenic fungal biota. It has been determined that a total of 15 fungal species are involved in the formation of the phytopathogenic mycobiota of cucumber plants. Although more than half of the recorded fungi showed phytopathogenic properties in both conditions, overall, covered conditions were more favorable for the development of fungal. The reason for this is that the parameters that are important for plants in covered conditions are favorable for fungi, and these parameters are relatively more stable in covered conditions. The species involved in the formation of the phytopathogenic mycobiota of cucumber plants had a certain specificity in terms of the prevalence of the diseases they caused, the forms of observation, and the effect of the effects. Although some of them cause diseases with the same name and have similar symptoms, it has been determined that each disease also has symptoms that arise from the biological characteristics of the fungus itself.

Read more : African Swine Fever Surveillance in Cagayan Abattoirs, Philippines | InformativeBD 

Introduction 

In modern times, providing people with plant-based food products is one of the important issues that any country plans to solve. The importance of this issue is necessitated by the increasing world population within the fixed territory of the Earth, the increasing burden of anthropogenic impact on the environment the decrease in useful land areas used by people for various purposes, the expansion of urbanization, and other processes. Thus, according to UNO forecasts, the world population is expected to reach 10.3 billion in 2084, which allows us to note a 1.5-fold increase (Choręziak et al., 2025; Australian Government, 2024) in population compared to 2024. This, in turn, will inevitably create additional problems in meeting the growing population's demand for various substances, primarily food. Therefore, conducting research aimed at solving these problems is currently one of the most relevant.

It should be noted that, against the background of the above, meeting people's needs for nutrients, especially those of plant origin with relatively high biological value, is one of the tasks that is in the focus of special attention (Choręziak et al., 2025). Research conducted to address these issues mainly covers two areas. The first direction is that it includes increasing the productivity of plants used for this purpose, eliminating conditions that cause crop losses, implementing cultivation with more efficient technologies, and so on. The second direction involves the creation of new varieties that are productive, disease-resistant, capable of growing under stressful conditions, and have other characteristics. Sometimes these two directions are carried out in a mixed manner.

Regardless of this, the purpose of conducted research in both directions is to improve both the quantity and quality of the products produced.

As in a number of countries around the world, the agricultural sector plays an important role in the economy of the Republic of Azerbaijan, so cereals, vegetables, melons, fruits, etc. are cultivated throughout the country, and hundreds of thousands of tons of crops are harvested every year (Babayeva et al., 2025). For example, about 50% of the country's 86.6 thousand km2 area is occupied by usable land in which, according to data from 2024, 1,685,734.0 tons of wheat, 22,206.6 tons of legumes, 490,558.2 tons of melons, 1,838,903.3 tons of vegetables, and 1,317,868.2 tons of fruit were grown (State Statistical Committee of Azerbaijan, 2025). Despite this, the volume of products produced does not fully meet the needs of the country's population even today, and therefore the issue of increasing productivity and reducing crop losses is of greater importance for the Republic of Azerbaijan.

Vegetables are among the plants widely cultivated in the Republic of Azerbaijan, as the cultivation of vegetable plants such as tomatoes, cucumbers, eggplants, etc. is found in all regions of the country (Huseynov et al., 2020). Sometimes the expected yield cannot be obtained from these plants, and one of the reasons for this is the result of diseases caused by various organisms, primarily fungi (Bakshaliyeva et al., 2023; Muradov et al., 2019). To prevent this, it is important to determine the species composition of these pathogens.

Therefore, the purpose of the presented work is to determine the species composition of diseases and their causative agents observed in cucumber plants cultivated under covered conditions in Azerbaijan.

Reference

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Babayeva LO, Jafarova KS, Ismayilova ES. 2025. The agricultural sector as a priority area of azerbaijan’s economic development. Economy and Business: Theory and Practice 4, 37–42. https://doi.org/10.24412/2411-0450-2025-4-37-42

Bakshaliyeva KF, Radjabli AX, Aliyeva GR, Arabova GQ, Muradov PZ. 2023. Characterization of the mycobiota of some cultivated plants in Azerbaijan according to species composition and diseases caused by pathogenic species. Advanced Studies in Biology 15(1), 163–171. https://doi.org/10.12988/asb.2023.91753

Balaji A. 2018. Handbook of plant disease identification and management. CRC Press, 620 p.

Chauhan A, Jindal T. 2020. Microbiological methods for environment, food and pharmaceutical analysis (1st ed.). Springer, 521 p.

Choręziak A, Rosiejka D, Michałowska J, Bogdański P. 2025. Nutritional quality, safety and environmental benefits of alternative protein sources-An overview. Nutrients 17(7), 1148. https://doi.org/10.3390/nu17071148

Hossain MM, Sultana F, Li W, Tran LP, Mostofa MG. 2023. Sclerotinia sclerotiorum (Lib.) de Bary: Insights into the pathogenomic features of a global pathogen. Cells 12(7), 1063. https://doi.org/10.3390/cells12071063

Hossain MM, Sultana F, Rubayet MT, Khan S, Mostafa M, Mishu NJ, Sabbir MAA, Akter N, Kabir A, Mostofa MG. 2025. White mold: A global threat to crops and key strategies for its sustainable management. Microorganisms 13(1), 4. https://doi.org/10.3390/microorganisms13010004

Huseynov HG, Jafarov IG, Vermeer M, Musaev FB. 2020. Vegetable growing in Azerbaijan in modern conditions. Vegetable Crops of Russia 4, 65–68. https://doi.org/10.18619/2072-9146-2020-4-65-68

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Article source :  The main diseases of cucumber (Cucumis sativus L.) grown in the Republic of Azerbaijan and the species composition of pathogens of these diseases

 

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African Swine Fever Surveillance in Cagayan Abattoirs, Philippines | InformativeBD

Maricel F. Campanano, Dennis M. Oyardo, and Mary Ann M. Santos, from the institute of Philippines. wrote a Research article about, African Swine Fever Surveillance in Cagayan Abattoirs, Philippines. Entitled, Surveillance and detection of the occurrence of African swine fever in abattoirs in the different municipalities of the second district of Cagayan, Philippines. This research paper published by the International Journal of Biosciences | IJB. an open access scholarly research journal Biosciences. under the affiliation of the International Network For Natural Sciences| INNSpub. an open access multidisciplinary research journal publisher.

Abstract

African swine fever (ASF) is a highly contagious hemorrhagic viral disease of domestic and wild pigs, which is responsible for serious economic and production losses. It is caused by a large DNA virus of the Asfarviridae family.  The study was conducted to determine positive   cases of African swine fever on pigs from different slaughterhouses in municipalities of second district in Cagayan. A total of 362 blood samples were collected in 6 municipal slaughterhouses. The samples were analyzed in the Regional Animal Disease Diagnostic Laboratory (RADDL). The viral DNA of ASF was extracted from the blood samples using the QIAamp Viral RNA Mini Kit (QIAGEN) and was identified through the RT-PCR (ASFV p72 gene-based real-time PCR assay). Two municipalities involve in the study resulted positive of African Swine Fever with a total of 60 out of 362 pigs. The municipality with the highest positive case and incidence rate is Sto. Nino with 41 out of 56 pigs are infected (incidence rate is 11.32%) followed by Piat with 19 pigs out of 96 pigs (incidence rate is 5.25%) and the rest no incidence of African Swine-Fever. The result obtained from the study indicates that out of 230 pooled samples (362 pigs), 35 (60 pigs) are showing 15.22% positivity rate and 16.57% incidence. 

Read more : Diversity of African Yam Bean in Yoruba Communities of Benin | InformativeBD 

Introduction

African swine fever (ASF) is a devastating haemorrhagic fever of pigs with mortality rates approaching 100 per cent. It causes major economic losses, threatens food security and limits pig production in affected countries. ASFV is a large DNA virus that replicates in the cytoplasm and is the only member of the Asfarviridae family. The virus encodes 150–165 proteins, which have „essential‟ functions in virus replication, as well as „non-essential‟ roles in host interactions, including evasion of host defences; for example, many proteins inhibit the early innate responses, including type I interferon and cell death pathways (Dixon et al., 2019).

African swine fever (ASF) was first identified in East Africa in the early 1900s as a disease causing high mortality in domestic pigs (Sus scrofa domesticus). It was quickly established that warthogs (Phacochoerus africanus) could be a source of infection (Montgomery, 1921) and that this host, along with a species of soft ticks (Ornithodoros spp.) which live in warthog burrows, could be persistently infected with ASF virus (ASFV) without showing signs of disease (Plowright et al., 1994).

ASF has a severe socio-economic impact, both in areas where it is newly introduced and where it is endemic. The high impact is most apparent in countries with a significant commercial pig industry. In Africa, ASF has potentially devastating effects on the commercial and subsistence pig production sectors, but the greatest losses are usually inflicted on the poorer pig producers who are less likely to implement effective prevention and control strategies (Edelsten and Chinombo, 1995) or basic biosecurity. The farmers also often lack financial resources to restart production in the absence of compensation schemes. In countries such as Cote d'Ivoire and Madagascar, the introduction of ASF resulted in the loss of between 30 and 50 per cent of the pig population (El Hicheri et al., 1998; Roger et al., 2001).

Although ASF was first described almost a century ago, controlling the disease has proven to be a challenge, in particular because no vaccine is available. Following introduction to ASFV-free countries, the only control measures available are strict quarantine and biosecurity, animal movement restrictions and slaughtering affected/exposed animals.

Reference

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Dixon LK, Stahl K, Jori F, Vial L, Pfeiffer DU. 2020. African swine fever epidemiology and control. Annual Review of Animal Biosciences 8(1), 221–246.

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King DP, Reid SM, Hutchings GH, Grierson SS, Wilkinson PJ, Dixon LK, Bastos ADS, Drew TW. 2003. Development of a TaqMan® PCR assay with internal amplification control for the detection of African swine fever virus. Journal of Virological Methods 107(1), 53–61.

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Roger F, Ratovonjato J, Vola P, Uilenberg G. 2001. Ornithodoros porcinus ticks, bushpigs and African swine fever in Madagascar. Experimental and Applied Acarology 25, 263–269.

Taylor RA, Condoleo R, Simons RRL, Gale P, Kelly LA, Snary EL. 2020. The risk of African swine fever virus introduction into disease-free regions via pork products. Transboundary and Emerging Diseases 67(2), 846–857. https://doi.org/10.1111/tbed.13429

Thomas LF, de Glanville WA, Cook EAJ, Fèvre EM. 2016. The spatial ecology of African swine fever in smallholder pig systems: the role of live pig markets in disease transmission. Transboundary and Emerging Diseases 63(5), 476–484. 

Article source : Surveillance and detection of the occurrence of African swine fever in abattoirs in the different municipalities of the second district of Cagayan, Philippines  

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