Your search keyword '"Dhandapani Raju"' showing total 39 results

1. Calmodulin: Coping with biotic and abiotic stresses in soybean (Glycine max (L.) Merr.)

Author

Ayyagari Ramlal, Amooru Harika, V Jayasri, Sreeramanan Subramaniam, Bingi Pujari Mallikarjuna, Dhandapani Raju, S K Lal, and Ambika Rajendran

Subjects

Abiotic stress, Biotic stress, Calcium, Calmodulin, Secondary messenger and soybean, Plant ecology, QK900-989

Abstract

Calcium is a ubiquitous and versatile secondary messenger that enables plant growth through various processes in response to abiotic and biotic stress factors. Plants are immobile and therefore constantly exposed to various environmental stimuli (drought, waterlogging, etc.) and microorganisms such as bacteria, fungi, and viruses resulting in large crop losses. Calmodulin (CaM) is an evolutionarily conserved calcium-binding protein and sensor that occurs in all eukaryotes and performs various functions under stress. CaM-binding proteins (CBPs) such as transcription factors, enzymes and channels are involved in responses to environmental stress. Plants have evolved a sophisticated innate immune system to fight infections, commonly referred to as pathogen-associated molecular pattern (PAMP)-triggered immunity (PTI) and effector-triggered immunity (ETI). Soybean is an economically important legume crop that is constantly confronted with various pests and pathogens, resulting in significant yield and production losses. The article highlights the functions of calmodulin in soybean during biotic (soybean-microbe pathogenesis) and abiotic (soybean-environment) interactions in the light of currently available knowledge on the subject. It also describes the new paradigms in this field, emphasising the need for further investigation and providing up-to-date information on the most plausible approaches to combat this challenge for commercial use.

Published

2024

2. Autofluorescence−spectral imaging for rapid and invasive characterization of soybean for pre-germination anaerobic stress tolerance

Author

Ambika Rajendran, Ayyagari Ramlal, Subham Sarkar, Sarit S. Agasti, K. Rajarajan, S. K. Lal, Dhandapani Raju, and Sreeramanan Subramaniam

Subjects

autofluorescence, spectral markers, soybean, susceptible, tolerant, imaging, Plant culture, SB1-1110

Abstract

The autofluorescence-spectral imaging (ASI) technique is based on the light-emitting ability of natural fluorophores. Soybean genotypes showing contrasting tolerance to pre-germination anaerobic stress can be characterized using the photon absorption and fluorescence emission of natural fluorophores occurring in seed coats. In this study, tolerant seeds were efficiently distinguished from susceptible genotypes at 405 nm and 638 nm excitation wavelengths. ASI approach can be employed as a new marker for the detection of photon-emitting compounds in the tolerant and susceptible soybean seed coats. Furthermore, the accuracy of rapid characterization of genotypes using this technique can provide novel insights into soybean breeding.

Published

2024

3. Image-based phenotyping of seed architectural traits and prediction of seed weight using machine learning models in soybean

Author

Nguyen Trung Duc, Ayyagari Ramlal, Ambika Rajendran, Dhandapani Raju, S. K. Lal, Sudhir Kumar, Rabi Narayan Sahoo, and Viswanathan Chinnusamy

Subjects

soybean, RGB image, machine learning, hundred-seed weight prediction, superior donor identification, Plant culture, SB1-1110

Abstract

Among seed attributes, weight is one of the main factors determining the soybean harvest index. Recently, the focus of soybean breeding has shifted to improving seed size and weight for crop optimization in terms of seed and oil yield. With recent technological advancements, there is an increasing application of imaging sensors that provide simple, real-time, non-destructive, and inexpensive image data for rapid image-based prediction of seed traits in plant breeding programs. The present work is related to digital image analysis of seed traits for the prediction of hundred-seed weight (HSW) in soybean. The image-based seed architectural traits (i-traits) measured were area size (AS), perimeter length (PL), length (L), width (W), length-to-width ratio (LWR), intersection of length and width (IS), seed circularity (CS), and distance between IS and CG (DS). The phenotypic investigation revealed significant genetic variability among 164 soybean genotypes for both i-traits and manually measured seed weight. Seven popular machine learning (ML) algorithms, namely Simple Linear Regression (SLR), Multiple Linear Regression (MLR), Random Forest (RF), Support Vector Regression (SVR), LASSO Regression (LR), Ridge Regression (RR), and Elastic Net Regression (EN), were used to create models that can predict the weight of soybean seeds based on the image-based novel features derived from the Red-Green-Blue (RGB)/visual image. Among the models, random forest and multiple linear regression models that use multiple explanatory variables related to seed size traits (AS, L, W, and DS) were identified as the best models for predicting seed weight with the highest prediction accuracy (coefficient of determination, R2=0.98 and 0.94, respectively) and the lowest prediction error, i.e., root mean square error (RMSE) and mean absolute error (MAE). Finally, principal components analysis (PCA) and a hierarchical clustering approach were used to identify IC538070 as a superior genotype with a larger seed size and weight. The identified donors/traits can potentially be used in soybean improvement programs

Published

2023

4. Phenomics based prediction of plant biomass and leaf area in wheat using machine learning approaches

Author

Biswabiplab Singh, Sudhir Kumar, Allimuthu Elangovan, Devendra Vasht, Sunny Arya, Nguyen Trung Duc, Pooja Swami, Godawari Shivaji Pawar, Dhandapani Raju, Hari Krishna, Lekshmy Sathee, Monika Dalal, Rabi Narayan Sahoo, and Viswanathan Chinnusamy

Subjects

high-throughput phenotyping (HTP), RGB image, NIR image, machine learning, i-traits, wheat, Plant culture, SB1-1110

Abstract

IntroductionPhenomics has emerged as important tool to bridge the genotype-phenotype gap. To dissect complex traits such as highly dynamic plant growth, and quantification of its component traits over a different growth phase of plant will immensely help dissect genetic basis of biomass production. Based on RGB images, models have been developed to predict biomass recently. However, it is very challenging to find a model performing stable across experiments. In this study, we recorded RGB and NIR images of wheat germplasm and Recombinant Inbred Lines (RILs) of Raj3765xHD2329, and examined the use of multimodal images from RGB, NIR sensors and machine learning models to predict biomass and leaf area non-invasively.ResultsThe image-based traits (i-Traits) containing geometric features, RGB based indices, RGB colour classes and NIR features were categorized into architectural traits and physiological traits. Total 77 i-Traits were selected for prediction of biomass and leaf area consisting of 35 architectural and 42 physiological traits. We have shown that different biomass related traits such as fresh weight, dry weight and shoot area can be predicted accurately from RGB and NIR images using 16 machine learning models. We applied the models on two consecutive years of experiments and found that measurement accuracies were similar suggesting the generalized nature of models. Results showed that all biomass-related traits could be estimated with about 90% accuracy but the performance of model BLASSO was relatively stable and high in all the traits and experiments. The R2 of BLASSO for fresh weight prediction was 0.96 (both year experiments), for dry weight prediction was 0.90 (Experiment 1) and 0.93 (Experiment 2) and for shoot area prediction 0.96 (Experiment 1) and 0.93 (Experiment 2). Also, the RMSRE of BLASSO for fresh weight prediction was 0.53 (Experiment 1) and 0.24 (Experiment 2), for dry weight prediction was 0.85 (Experiment 1) and 0.25 (Experiment 2) and for shoot area prediction 0.59 (Experiment 1) and 0.53 (Experiment 2).DiscussionBased on the quantification power analysis of i-Traits, the determinants of biomass accumulation were found which contains both architectural and physiological traits. The best predictor i-Trait for fresh weight and dry weight prediction was Area_SV and for shoot area prediction was projected shoot area. These results will be helpful for identification and genetic basis dissection of major determinants of biomass accumulation and also non-invasive high throughput estimation of plant growth during different phenological stages can identify hitherto uncovered genes for biomass production and its deployment in crop improvement for breaking the yield plateau.

Published

2023

5. Elucidating the role of key physio-biochemical traits and molecular network conferring heat stress tolerance in cucumber

Author

Dhananjay A. Hongal, Dhandapani Raju, Sudhir Kumar, Akshay Talukdar, Anjan Das, Khushboo Kumari, Prasanta K. Dash, Viswanathan Chinnusamy, Anilabha Das Munshi, Tusar Kanti Behera, and Shyam Sundar Dey

Subjects

cucumber, heat stress, physiological and biochemical traits, antioxidant enzymes, RT-PCR, HSPs, Plant culture, SB1-1110

Abstract

Cucumber is an important vegetable crop grown worldwide and highly sensitive to prevailing temperature condition. The physiological, biochemical and molecular basis of high temperature stress tolerance is poorly understood in this model vegetable crop. In the present study, a set of genotypes with contrasting response under two different temperature stress (35/30°C and 40/35°C) were evaluated for important physiological and biochemical traits. Besides, expression of the important heat shock proteins (HSPs), aquaporins (AQPs), photosynthesis related genes was conducted in two selected contrasting genotypes at different stress conditions. It was established that tolerant genotypes were able to maintain high chlorophyll retention, stable membrane stability index, higher retention of water content, stability in net photosynthesis, high stomatal conductance and transpiration in combination with less canopy temperatures under high temperature stress conditions compared to susceptible genotypes and were considered as the key physiological traits associated with heat tolerance in cucumber. Accumulation of biochemicals like proline, protein and antioxidants like SOD, catalase and peroxidase was the underlying biochemical mechanisms for high temperature tolerance. Upregulation of photosynthesis related genes, signal transduction genes and heat responsive genes (HSPs) in tolerant genotypes indicate the molecular network associated with heat tolerance in cucumber. Among the HSPs, higher accumulation of HSP70 and HSP90 were recorded in the tolerant genotype, WBC-13 under heat stress condition indicating their critical role. Besides, Rubisco S, Rubisco L and CsTIP1b were upregulated in the tolerant genotypes under heat stress condition. Therefore, the HSPs in combination with photosynthetic and aquaporin genes were the underlying important molecular network associated with heat stress tolerance in cucumber. The findings of the present study also indicated negative feedback of G-protein alpha unit and oxygen evolving complex in relation to heat stress tolerance in cucumber. These results indicate that the thermotolerant cucumber genotypes enhanced physio-biochemical and molecular adaptation under high-temperature stress condition. This study provides foundation to design climate smart genotypes in cucumber through integration of favorable physio-biochemical traits and understanding the detailed molecular network associated with heat stress tolerance in cucumber.

Published

2023

6. Angiotensin-converting enzyme inhibitory peptides and isoflavonoids from soybean [Glycine max (L.) Merr.]

Author

Ayyagari Ramlal, Aparna Nautiyal, Pooja Baweja, Vikash Kumar, Sahil Mehta, Rohit Kumar Mahto, Shikha Tripathi, Aravindam Shanmugam, Bingi Pujari Mallikarjuna, Pushpa Raman, S. K. Lal, Dhandapani Raju, and Ambika Rajendran

Subjects

soy products, angiotensin-converting enzyme I (ACE I), cardiovascular diseases (CVDs), natural drugs, renin-angiotensin-aldosterone system (RAAS), Nutrition. Foods and food supply, TX341-641

Abstract

Angiotensin-converting enzyme I (ACE I) is a zinc-containing metallopeptidase involved in the renin-angiotensin system (RAAS) that helps in the regulation of hypertension and maintains fluid balance otherwise, which results in cardiovascular diseases (CVDs). One of the leading reasons of global deaths is due to CVDs. RAAS also plays a central role in maintaining homeostasis of the CV system. The commercial drugs available to treat CVDs possess several fatal side effects. Hence, phytochemicals like peptides having plant-based origin should be explored and utilized as alternative therapies. Soybean is an important leguminous crop that simultaneously possesses medicinal properties. Soybean extracts are used in many drug formulations for treating diabetes and other disorders and ailments. Soy proteins and its edible products such as tofu have shown potential inhibitory activity against ACE. Thus, this review briefly describes various soy proteins and products that can be used to inhibit ACE thereby providing new scope for the identification of potential candidates that can help in the design of safer and natural treatments for CVDs.

Published

2022

7. Harnessing heterosis and male sterility in soybean [Glycine max (L.) Merrill]: A critical revisit

Author

Ayyagari Ramlal, Aparna Nautiyal, Pooja Baweja, Rohit Kumar Mahto, Sahil Mehta, Bingi Pujari Mallikarunja, Roshni Vijayan, Shukla Saluja, Vijay Kumar, Sunil Kumar Dhiman, S. K. Lal, Dhandapani Raju, and Ambika Rajendran

Subjects

heterosis, soybean, male sterility, genetic diversity, self-pollination, seed yield, Plant culture, SB1-1110

Abstract

Soybean is a predominantly self-pollinated crop. It is also one of the important oilseed legumes. Soybean is an excellent crop having industrial, traditional, culinary, feeding, and cultural roles. Genetic diversity in breeding programs is of prime importance as it ensures the success of any breeding by enhancing the outcomes and results of the plants. The phenomenon wherein the progeny exhibits greater biomass (yield) and a faster rate of development and fertility than its parents is referred to as heterosis. As of now, heterosis is mainly limited to the trait of seed yield and is considered the basis for the development of better (superior) varieties. Male sterility (MS) is extensively used for the production of seeds and the improvement of crops coupled with the traditional breeding programs and molecular technology. Therefore, deployment of MS and heterosis in breeding soybean could yield better outcomes. This review aims to focus on two aspects, namely, MS and heterosis in soybean with its scope for crop improvement.

Published

2022

8. Imaging Sensor-Based High-Throughput Measurement of Biomass Using Machine Learning Models in Rice

Author

Allimuthu Elangovan, Nguyen Trung Duc, Dhandapani Raju, Sudhir Kumar, Biswabiplab Singh, Chandrapal Vishwakarma, Subbaiyan Gopala Krishnan, Ranjith Kumar Ellur, Monika Dalal, Padmini Swain, Sushanta Kumar Dash, Madan Pal Singh, Rabi Narayan Sahoo, Govindaraj Kamalam Dinesh, Poonam Gupta, and Viswanathan Chinnusamy

Subjects

Phenomics, machine learning models, Near Infrared Sensor, projected shoot area, RGB, Agriculture (General), S1-972

Abstract

Phenomics technologies have advanced rapidly in the recent past for precision phenotyping of diverse crop plants. High-throughput phenotyping using imaging sensors has been proven to fetch more informative data from a large population of genotypes than the traditional destructive phenotyping methodologies. It provides accurate, high-dimensional phenome-wide big data at an ultra-super spatial and temporal resolution. Biomass is an important plant phenotypic trait that can reflect the agronomic performance of crop plants in terms of growth and yield. Several image-derived features such as area, projected shoot area, projected shoot area with height constant, estimated bio-volume, etc., and machine learning models (single or multivariate analysis) are reported in the literature for use in the non-invasive prediction of biomass in diverse crop plants. However, no studies have reported the best suitable image-derived features for accurate biomass prediction, particularly for fully grown rice plants (70DAS). In this present study, we analyzed a subset of rice recombinant inbred lines (RILs) which were developed from a cross between rice varieties BVD109 × IR20 and grown in sufficient (control) and deficient soil nitrogen (N stress) conditions. Images of plants were acquired using three different sensors (RGB, IR, and NIR) just before destructive plant sampling for the quantitative estimation of fresh (FW) and dry weight (DW). A total of 67 image-derived traits were extracted and classified into four groups, viz., geometric-, color-, IR- and NIR-related traits. We identified a multimodal trait feature, the ratio of PSA and NIR grey intensity as estimated from RGB and NIR sensors, as a novel trait for predicting biomass in rice. Among the 16 machine learning models tested for predicting biomass, the Bayesian regularized neural network (BRNN) model showed the maximum predictive power (R2 = 0.96 and 0.95 for FW and DW of biomass, respectively) with the lowest prediction error (RMSE and bias value) in both control and N stress environments. Thus, biomass can be accurately predicted by measuring novel image-based parameters and neural network-based machine learning models in rice.

Published

2023

9. SpikeSegNet-a deep learning approach utilizing encoder-decoder network with hourglass for spike segmentation and counting in wheat plant from visual imaging

Author

Tanuj Misra, Alka Arora, Sudeep Marwaha, Viswanathan Chinnusamy, Atmakuri Ramakrishna Rao, Rajni Jain, Rabi Narayan Sahoo, Mrinmoy Ray, Sudhir Kumar, Dhandapani Raju, Ranjeet Ranjan Jha, Aditya Nigam, and Swati Goel

Subjects

Deep learning, Encoder-decoder deep network, Image analysis, Non-destructive plant phenotyping, Wheat spikes identification and count, Plant culture, SB1-1110, Biology (General), QH301-705.5

Abstract

Abstract Background High throughput non-destructive phenotyping is emerging as a significant approach for phenotyping germplasm and breeding populations for the identification of superior donors, elite lines, and QTLs. Detection and counting of spikes, the grain bearing organs of wheat, is critical for phenomics of a large set of germplasm and breeding lines in controlled and field conditions. It is also required for precision agriculture where the application of nitrogen, water, and other inputs at this critical stage is necessary. Further, counting of spikes is an important measure to determine yield. Digital image analysis and machine learning techniques play an essential role in non-destructive plant phenotyping analysis. Results In this study, an approach based on computer vision, particularly object detection, to recognize and count the number of spikes of the wheat plant from the digital images is proposed. For spike identification, a novel deep-learning network, SpikeSegNet, has been developed by combining two proposed feature networks: Local Patch extraction Network (LPNet) and Global Mask refinement Network (GMRNet). In LPNet, the contextual and spatial features are learned at the local patch level. The output of LPNet is a segmented mask image, which is further refined at the global level using GMRNet. Visual (RGB) images of 200 wheat plants were captured using LemnaTec imaging system installed at Nanaji Deshmukh Plant Phenomics Centre, ICAR-IARI, New Delhi. The precision, accuracy, and robustness (F1 score) of the proposed approach for spike segmentation are found to be 99.93%, 99.91%, and 99.91%, respectively. For counting the number of spikes, “analyse particles”—function of imageJ was applied on the output image of the proposed SpikeSegNet model. For spike counting, the average precision, accuracy, and robustness are 99%, 95%, and 97%, respectively. SpikeSegNet approach is tested for robustness with illuminated image dataset, and no significant difference is observed in the segmentation performance. Conclusion In this study, a new approach called as SpikeSegNet has been proposed based on combined digital image analysis and deep learning techniques. A dedicated deep learning approach has been developed to identify and count spikes in the wheat plants. The performance of the approach demonstrates that SpikeSegNet is an effective and robust approach for spike detection and counting. As detection and counting of wheat spikes are closely related to the crop yield, and the proposed approach is also non-destructive, it is a significant step forward in the area of non-destructive and high-throughput phenotyping of wheat.

Published

2020

10. Drought Tolerant Near Isogenic Lines of Pusa 44 Pyramided With qDTY2.1 and qDTY3.1, Show Accelerated Recovery Response in a High Throughput Phenomics Based Phenotyping

Author

Priyanka Dwivedi, Naleeni Ramawat, Dhandapani Raju, Gaurav Dhawan, S. Gopala Krishnan, Viswanathan Chinnusamy, Prolay Kumar Bhowmick, K. K. Vinod, Madan Pal, Mariappan Nagarajan, Ranjith Kumar Ellur, Haritha Bollinedi, and Ashok K. Singh

Subjects

phenomics, controlled environment, image-based phenotyping, drought tolerance, rice, Plant culture, SB1-1110

Abstract

Reproductive stage drought stress (RSDS) is a major challenge in rice production worldwide. Cultivar development with drought tolerance has been slow due to the lack of precise high throughput phenotyping tools to quantify drought stress-induced effects. Most of the available techniques are based on destructive sampling and do not assess the progress of the plant’s response to drought. In this study, we have used state-of-the-art image-based phenotyping in a phenomics platform that offers a controlled environment, non-invasive phenotyping, high accuracy, speed, and continuity. In rice, several quantitative trait loci (QTLs) which govern grain yield under drought determine RSDS tolerance. Among these, qDTY2.1 and qDTY3.1 were used for marker-assisted breeding. A set of 35 near-isogenic lines (NILs), introgressed with these QTLs in the popular variety, Pusa 44 were used to assess the efficiency of image-based phenotyping for RSDS tolerance. NILs offered the most reliable contrast since they differed from Pusa 44 only for the QTLs. Four traits, namely, the projected shoot area (PSA), water use (WU), transpiration rate (TR), and red-green-blue (RGB) and near-infrared (NIR) values were used. Differential temporal responses could be seen under drought, but not under unstressed conditions. NILs showed significant level of RSDS tolerance as compared to Pusa 44. Among the traits, PSA showed strong association with yield (80%) as well as with two drought tolerances indices, stress susceptibility index (SSI) and tolerance index (TOL), establishing its ability in identifying the best drought tolerant NILs. The results revealed that the introgression of QTLs helped minimize the mean WU per unit of biomass per day, suggesting the potential role of these QTLs in improving WU-efficiency (WUE). We identified 11 NILs based on phenomics traits as well as performance under imposed drought in the field. The study emphasizes the use of phenomics traits as selection criteria for RSDS tolerance at an early stage, and is the first report of using phenomics parameters in RSDS selection in rice.

Published

2022

11. Leaf Count Aided Novel Framework for Rice (Oryza sativa L.) Genotypes Discrimination in Phenomics: Leveraging Computer Vision and Deep Learning Applications

Author

Mukesh Kumar Vishal, Rohit Saluja, Devarshi Aggrawal, Biplab Banerjee, Dhandapani Raju, Sudhir Kumar, Viswanathan Chinnusamy, Rabi Narayan Sahoo, and Jagarlapudi Adinarayana

Subjects

number of leaves, biomass, deep learning, genome wide association study (GWAS), high throughput plant phenotyping (HTPP), leaf counting, Botany, QK1-989

Abstract

Drought is a detrimental factor to gaining higher yields in rice (Oryza sativa L.), especially amid the rising occurrence of drought across the globe. To combat this situation, it is essential to develop novel drought-resilient varieties. Therefore, screening of drought-adaptive genotypes is required with high precision and high throughput. In contemporary emerging science, high throughput plant phenotyping (HTPP) is a crucial technology that attempts to break the bottleneck of traditional phenotyping. In traditional phenotyping, screening significant genotypes is a tedious task and prone to human error while measuring various plant traits. In contrast, owing to the potential advantage of HTPP over traditional phenotyping, image-based traits, also known as i-traits, were used in our study to discriminate 110 genotypes grown for genome-wide association study experiments under controlled (well-watered), and drought-stress (limited water) conditions, under a phenomics experiment in a controlled environment with RGB images. Our proposed framework non-destructively estimated drought-adaptive plant traits from the images, such as the number of leaves, convex hull, plant–aspect ratio (plant spread), and similarly associated geometrical and morphological traits for analyzing and discriminating genotypes. The results showed that a single trait, the number of leaves, can also be used for discriminating genotypes. This critical drought-adaptive trait was associated with plant size, architecture, and biomass. In this work, the number of leaves and other characteristics were estimated non-destructively from top view images of the rice plant for each genotype. The estimation of the number of leaves for each rice plant was conducted with the deep learning model, YOLO (You Only Look Once). The leaves were counted by detecting corresponding visible leaf tips in the rice plant. The detection accuracy was 86–92% for dense to moderate spread large plants, and 98% for sparse spread small plants. With this framework, the susceptible genotypes (MTU1010, PUSA-1121 and similar genotypes) and drought-resistant genotypes (Heera, Anjali, Dular and similar genotypes) were grouped in the core set with a respective group of drought-susceptible and drought-tolerant genotypes based on the number of leaves, and the leaves’ emergence during the peak drought-stress period. Moreover, it was found that the number of leaves was significantly associated with other pertinent morphological, physiological and geometrical traits. Other geometrical traits were measured from the RGB images with the help of computer vision.

Published

2022

12. Artificial neural network for estimating leaf fresh weight of rice plant through visual-nir imaging

Author

TANUJ MISRA, ALKA ARORA, SUDEEP MARWAHA, MRINMOY RAY, DHANDAPANI RAJU, SUDHIR KUMAR, SWATI GOEL, RABI NARAYAN SAHOO, and VISWANATHAN CHINNUSAMY

Subjects

Artificial neural network, Green leaf proportion, Image analysis, LFW, Non-destructive phenotyping, Rice, Agriculture

Abstract

Prediction of fresh biomass is the key for evaluation of the response of crop genotypes to diverse input and stress conditions, and forms basis for calculating net primary production. Hence, accurate and high throughput estimation of fresh biomass is critical for plant phenotyping. As conventional phenotyping approaches for measuring fresh biomass is time consuming, laborious and destructive, image based phenotyping methods are being widely used now in plant phenotyping. However, current approaches for estimating fresh biomass of plants are based on projected shoot area estimated from the visual (VIS) image. These approaches do not consider the water content of the plant tissues which are about 70-80% in leafy vegetation. Since water absorbs radiation in the Near Infra-Red (NIR) (900–1700 nm) region, it has been hypothesized that combined use of VIS and NIR imaging can predict the fresh biomass more accurately that the VIS image alone. In this study, VIS and NIR imaging were captured for rice leaves with different moisture content as a test case. For background subtraction from NIR image, PlantCV v2 NIR imaging algorithm was implemented in MATLAB software (version 2015b). The proposed image derived parameter, viz. Green Leaf Proportion (GLP) from VIS image and mean gray value/intensity (NIR_MGI) from NIR image were used as input to develop Artificial Neural Network (ANN) model to estimate the Leaf Fresh Weight (LFW). This proposed approach significantly enhanced the fresh biomass prediction as compared to the conventional regression technique based on projected shoot area derived from VIS image.

Published

2019

13. Phenotypic characterization of the novel seedling stage zebra leaf mutant, Pusa Zebra 18 in rice

Author

Amaresh, Subbaiyan, Gopala Krishnan, Vinod, Kunnummal Kurungara, Chinnusamy, Viswanathan, Sevanthi, Amitha Charu Rama Mithra Viyasamurthy, Dhandapani, Raju, Ellur, Ranjith Kumar, Bhowmick, Prolay Kumar, Bollinedi, Haritha, Umadevi, Palaniyandi, Senapati, Manoranjan, Verma, Rakesh Kumar, Nagarajan, Mariappan, Dhawan, Gaurav, Kumar, Pankaj, and Singh, Ashok Kumar

Published

2023

14. Estimation of wheat biophysical variables through UAV hyperspectral remote sensing using machine learning and radiative transfer models

Author

Sahoo, Rabi N., Rejith, R.G., Gakhar, Shalini, Verrelst, Jochem, Ranjan, Rajeev, Kondraju, Tarun, Meena, Mahesh C., Mukherjee, Joydeep, Dass, Anchal, Kumar, Sudhir, Kumar, Mahesh, Dhandapani, Raju, and Chinnusamy, Viswanathan

Published

2024

15. Co-cultivation Approach to Decipher the Influence of Nitrogen-Fixing Cyanobacterium on Growth and N Uptake in Rice Crop

Author

Priya, Himani, Dhar, Dolly W., Singh, Ranjit, Kumar, Sudhir, Dhandapani, Raju, Pandey, Renu, Govindasamy, Venkadasamy, and Kumar, Arun

Published

2022

16. UAV-Based Retrieval Of Wheat Canopy Chlorophyll Content Using A Hybrid Machine Learning Approach

Author

Rejith, R. G., primary, Sahoo, Rabi N., additional, Verrelst, Jochem, additional, Ranjan, Rajeev, additional, Gakhar, Shalini, additional, Anand, Amrita, additional, Kondraju, Tarun, additional, Kumar, Sudhir, additional, Kumar, Mahesh, additional, and Dhandapani, Raju, additional

Published

2023

17. Optimizing the Retrieval of Wheat Crop Traits from UAV-Borne Hyperspectral Image with Radiative Transfer Modelling Using Gaussian Process Regression

Author

Sahoo, Rabi N., primary, Gakhar, Shalini, additional, Rejith, Rajan G., additional, Verrelst, Jochem, additional, Ranjan, Rajeev, additional, Kondraju, Tarun, additional, Meena, Mahesh C., additional, Mukherjee, Joydeep, additional, Daas, Anchal, additional, Kumar, Sudhir, additional, Kumar, Mahesh, additional, Dhandapani, Raju, additional, and Chinnusamy, Viswanathan, additional

Published

2023

18. First report of ovary-derived calli induction in soybean [Glycine max (L.) Merr.]

Author

Ayyagari Ramlal, Deepshikha Sharma, Sanjay Kumar Lal, Dhandapani Raju, null Shivam, and Ambika Rajendran

Subjects

Horticulture

Published

2023

19. Associations of direct and indirect selection for pregermination anaerobic stress tolerance in soybean ( Glycine max )

Author

Ambika Rajendran, Sanjay Kumar Lal, Dhandapani Raju, and Ayyagari Ramlal

Subjects

Genetics, Plant Science, Agronomy and Crop Science

Published

2022

20. Concurrent Overexpression of Rice GS1;1 and GS2 Genes to Enhance the Nitrogen Use Efficiency (NUE) in Transgenic Rice

Author

Shambhu Krishan Lal, Sahil Mehta, Dhandapani Raju, V. Mohan Murali Achary, Ajay Kumar Venkatapuram, Shashank Kumar Yadav, Hemangini Parmar, Rakesh Pandey, Varakumar Panditi, Vijay Sheri, Anil Kumar Singh, Viswanathan Chinnusamy, and Malireddy K. Reddy

Subjects

Plant Science, Agronomy and Crop Science

Published

2023

21. Image Based High throughput Phenotyping for Fusarium Wilt Resistance in Pigeon Pea (Cajanus cajan)

Author

Rudrappa K. Bannihatti, Parimal Sinha, Dhandapani Raju, Shubhajyoti Das, S. N. Mandal, R. S. Raje, C. Viswanathan, Sudhir Kumar, K. Gaikwad, and R. Aggarwal

Subjects

Insect Science, Plant Science

Published

2022

22. SpikeSegNet-a deep learning approach utilizing encoder-decoder network with hourglass for spike segmentation and counting in wheat plant from visual imaging

Author

Aditya Nigam, Rabi Narayan Sahoo, Rajni Jain, Swati Goel, Atmakuri Ramakrishna Rao, Dhandapani Raju, Sudeep Marwaha, Mrinmoy Ray, Viswanathan Chinnusamy, Sudhir Kumar, Tanuj Misra, Ranjeet Ranjan Jha, and Alka Arora

Subjects

0106 biological sciences, 0301 basic medicine, Computer science, Plant Science, lcsh:Plant culture, 01 natural sciences, Image analysis, 03 medical and health sciences, Digital image, Phenomics, Genetics, Segmentation, lcsh:SB1-1110, lcsh:QH301-705.5, business.industry, Deep learning, Methodology, Encoder-decoder deep network, Pattern recognition, Object detection, 030104 developmental biology, lcsh:Biology (General), Wheat spikes identification and count, RGB color model, Artificial intelligence, Precision agriculture, business, F1 score, Non-destructive plant phenotyping, 010606 plant biology & botany, Biotechnology

Abstract

BackgroundHigh throughput non-destructive phenotyping is emerging as a significant approach for phenotyping germplasm and breeding populations for the identification of superior donors, elite lines, and QTLs. Detection and counting of spikes, the grain bearing organs of wheat, is critical for phenomics of a large set of germplasm and breeding lines in controlled and field conditions. It is also required for precision agriculture where the application of nitrogen, water, and other inputs at this critical stage is necessary. Further, counting of spikes is an important measure to determine yield. Digital image analysis and machine learning techniques play an essential role in non-destructive plant phenotyping analysis.ResultsIn this study, an approach based on computer vision, particularly object detection, to recognize and count the number of spikes of the wheat plant from the digital images is proposed. For spike identification, a novel deep-learning network, SpikeSegNet, has been developed by combining two proposed feature networks: Local Patch extraction Network (LPNet) and Global Mask refinement Network (GMRNet). In LPNet, the contextual and spatial features are learned at the local patch level. The output of LPNet is a segmented mask image, which is further refined at the global level using GMRNet. Visual (RGB) images of 200 wheat plants were captured using LemnaTec imaging system installed at Nanaji Deshmukh Plant Phenomics Centre, ICAR-IARI, New Delhi. The precision, accuracy, and robustness (F1score) of the proposed approach for spike segmentation are found to be 99.93%, 99.91%, and 99.91%, respectively. For counting the number of spikes, “analyse particles”—function of imageJ was applied on the output image of the proposed SpikeSegNet model. For spike counting, the average precision, accuracy, and robustness are 99%, 95%, and 97%, respectively. SpikeSegNet approach is tested for robustness with illuminated image dataset, and no significant difference is observed in the segmentation performance.ConclusionIn this study, a new approach called as SpikeSegNet has been proposed based on combined digital image analysis and deep learning techniques. A dedicated deep learning approach has been developed to identify and count spikes in the wheat plants. The performance of the approach demonstrates that SpikeSegNet is an effective and robust approach for spike detection and counting. As detection and counting of wheat spikes are closely related to the crop yield, and the proposed approach is also non-destructive, it is a significant step forward in the area of non-destructive and high-throughput phenotyping of wheat.

Published

2020

23. Phytohormones in Abiotic Stress

Author

Dhandapani Raju, R Ambika Rajendran, Ayyagari Ramlal, Virendra Pal Singh, Dhandapani Raju, R Ambika Rajendran, Ayyagari Ramlal, and Virendra Pal Singh

Subjects

Plants--Effect of stress on--Molecular aspects, Plant hormones, Plant cellular signal transduction

Abstract

Plants are continuously exposed to different environmental stresses that negatively impact their physiology and morphology, resulting in production reduction. As a result of constant pressure, plants evolve different mechanisms for sustenance and survival. Hormones play a major role in defences against the stresses and stimulate regulatory mechanisms. One of the ways through which they mitigate stress is via the production of hormones like auxins, ethylene, jasmonic acid, etc. The phytohormones help in signaling and enhance the chances of their survival. Plant hormones play many vital roles from integrating developmental events, physiological and biochemical processes to mediating both abiotic and biotic stresses. This book aims to highlight these issues and provide scope for the development of tolerance in crops against abiotic stresses to maximize yield for the growing population. There is an urgent need for the development of strategies, methods and tools for the broad-spectrum tolerance in plants supporting sustainable crop production under hostile environmental conditions.The salient features are as follows:• It includes both traditional and non-traditional phytohormones and focuses on the latest progress emphasizing the roles of different hormones under abiotic stresses.• It provides a scope of the best plausible and suitable options for overcoming these stresses and puts forward the methods for crop improvement.• It is an amalgamation of the biosynthesis of phytohormones and also provides molecular intricacies and signalling mechanisms in different abiotic stresses.• This book serves as a reference book for scientific investigators from recent graduates, academicians and researchers working on phytohormones and abiotic stresses.

Published

2024

24. Leaf Counting in Rice (Oryza Sativa L.) Using Object Detection: A Deep Learning Approach

Author

J. Adinarayana, Rohit Saluja, Biplab Banerjee, Mukesh Kumar Vishal, Dhandapani Raju, Viswanathan Chinnusamy, Rabi Narayan Sahoo, and Sudhir Kumar

Subjects

Oryza sativa, biology, 010401 analytical chemistry, 02 engineering and technology, Sorghum, biology.organism_classification, Plant phenotyping, Photosynthesis, 01 natural sciences, Object detection, 0104 chemical sciences, Crop, Horticulture, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Hordeum vulgare, Rice plant, Mathematics

Abstract

Leaf count is one of the crucial tasks in plant phenotyping, and leaves are the basic unit of plant architecture involved in photosynthesis, growth, and yield of a plant. Therefore, the total number of leaves per plant is considered as one of the essential physio-morphological plant traits for phenotyping. The current work proposes to estimate the total number of leaves of a rice plant by detecting their leaves tips. A rice plant has a single tip for a single leaf. Hence, this proposed framework counts the total number of leaves by counting the number of leaves tips equal to the number of leaves. You Only Look Once (YOLO) algorithm is used for the detection of the leaves tips as an object. This hypothesis builds a basis for counting the total number of leaves in a plant like rice, and similar field crops such as wheat (Triticum aestivum L), maize (Zea mays L.), sorghum (Sorghum bicolor), barley (Hordeum vulgare L.). The model detected leaves of a rice plant (RGB images) by detecting corresponding leaves tips with YOLO having average accuracy up to 82% and IOU around 0.53-0.60 and estimates the number of leaves in a plant by counting predicted bounding boxes around tips. The model also performed well with the wheat crop.

Published

2020

25. Additional file 2 of SpikeSegNet-a deep learning approach utilizing encoder-decoder network with hourglass for spike segmentation and counting in wheat plant from visual imaging

Author

Tanuj Misra, Arora, Alka, Sudeep Marwaha, Viswanathan Chinnusamy, Atmakuri Ramakrishna Rao, Jain, Rajni, Sahoo, Rabi Narayan, Mrinmoy Ray, Kumar, Sudhir, Dhandapani Raju, Jha, Ranjeet Ranjan, Nigam, Aditya, and Goel, Swati

Abstract

Additional file 2. Pseudocode of the segmented mask image preparation.

Published

2020

26. Plants Stress Response Detection by Selecting Minimal Bands of Hyperspectral Images

Author

Milton Mondal, Dhandapani Raju, Manish Edida, Naman Sharma, and Brejesh Lall

Subjects

Stress (mechanics), Discriminative model, business.industry, Hyperspectral imaging, Pattern recognition, Feature selection, Spectral bands, Vegetation, Artificial intelligence, business, Conditional variance, Mathematics, Random forest

Abstract

It is an important task in the agricultural domain to determine the stress levels in plants. Drought conditions can have an adverse effect on crop yield. Hyperspectral Imaging (HSI) combined with classical Machine Learning algorithms are in current use to determine the stress levels. Every spectral band in an HSI does not contain useful information regarding the stress levels. For this reason, some vegetation indices are selected by agricultural researchers, based on reflectance ratios where a significant change in reflectance was observed because of stress. These indices do not always contain significant information because of changes in temperature, humidity or other atmospheric variations in different trials. There is no fixed set of vegetation indices which can be used to estimate stress levels accurately. In this paper, we demonstrated the working of Conditional Covariance Operator (CCM) which is used to select the most significant spectral bands from the collected Hyperspectral data itself. CCM is the most recent of the feature selection methods. This efficient feature selection method is used for the first time in this paper for plant stress analysis in rapid manner. It selects consistent discriminative spectral bands even when training examples per class are less than what other feature selection methods need. It can be seen that the Random Forest classifier model can classify the stress level into three categories (i) normal (ii) mild and (iii) severe stress with an accuracy of 99.7% when only 10 spectral bands are selected.

Published

2019

27. Phenomics: unlocking the hidden genetic variation for breaking the barriers in yield and stress tolerance

Author

Viswanathan Chinnusamy, Sudhir Kumar, Rabi Narayan Sahoo, and Dhandapani Raju

Subjects

0106 biological sciences, 0301 basic medicine, business.industry, media_common.quotation_subject, Genomics, Ideotype, Plant Science, Biology, Quantitative trait locus, Phenome, 01 natural sciences, Adaptability, Biotechnology, 03 medical and health sciences, 030104 developmental biology, Phenomics, Genetic gain, business, Agronomy and Crop Science, Genotyping, 010606 plant biology & botany, media_common

Abstract

The rate of genetic gain in yield, quality, input use efficiency and adaptability of crops to biotic and abiotic stresses must be improved significantly to achieve global food and nutritional security by 2050. To achieve this goal, deciphering the physiological genetic basis and assembly of component traits through analytical breeding is necessary. The two pillars of analytical breeding are genotyping and phenotyping. Advances in genotyping technologies such as single-nucleotide polymorphism genotyping and genotyping by sequencing have made deep genotyping cheaper and quicker, while phenotyping has lagged behind and thus remains a rate limiting step. Recently, phenomics has emerged as a new way of accurately phenotyping large set of genotypes. Phenomics employ non-invasive sensors and advanced computational platforms for non-destructive and high-throughput phenotyping. The depth of component phenotypic traits and the spatio-temporal dynamic phenotypic data generated in phenomics are enormous and unparallel to the conventional phenotyping. The utility of phenomics in QTL mapping and genome-wide association studies has already been demonstrated in important food crops. Phenomics has high potential for phenome-wide association studies, genomics selection models for enhancing selection efficiency, and genetic-ecophysiological crop simulation models for prediction of genotype-phenotypes relationship, in silico phenotyping and ideotype design. With the advancement in the depth of phenome data acquisition and analyses capabilities of phenomics, phenome assisted breeding and phenomic selection is anticipated to be a reality in near future. Complementary use of conventional phenotyping and advanced phenomics is suggested to assist in fundamental discoveries and analytical crop breeding.

Published

2016

28. Comparative Protein Fraction Analysis for Commercial Hybrid Seed Purity Testing in Cotton (Gossypium HirsutumL.)

Author

Dhandapani Raju, G. Somasundaram, Ambika Rajendran, Sriram Natarajan, H. P. Vijayakumar, P. Avinash, and S Rajendra Prasad

Subjects

0106 biological sciences, 0301 basic medicine, biology, Globulin, Materials Science (miscellaneous), Albumin, food and beverages, Fraction (chemistry), 01 natural sciences, Gossypium hirsutum, Hybrid seed, Seed protein, 03 medical and health sciences, 030104 developmental biology, Botany, biology.protein, Food science, Prolamin, 010606 plant biology & botany, Hybrid

Abstract

An experiment was designed to find out the best suited seed protein fraction for identifying the genetic contaminants in seeds of two cotton hybrids viz., CSHH 198 and CSHH 238 where its morphological and genetic differences are meager. The electrophoretic comparison of albumin, globulin, and prolamin seed protein fractions revealed that both albumin and globulin fractions are able to differentiate the hybrids from its male and female parents. The analysis of seed proteins of two cotton hybrid revealed that, albumin fraction produced six different fingerprints with highest discrimination ability than globulin fraction (three). Due to this, albumin fraction showed the added advantage in assessment of genetic purity of CSHH 198 hybrid seed lot that are contaminated with its own parental (selfed female) seeds as well as CSHH 238 cotton hybrid. In contrast, globulin fraction can only be used for identification of off type contaminations due to its own parental seeds and prolamin was unable to differen...

Published

2016

29. Application of thermal imaging and hyperspectral remote sensing for crop water deficit stress monitoring

Author

Krishna, Gopal, primary, Sahoo, Rabi N., additional, Singh, Prafull, additional, Patra, Himesh, additional, Bajpai, Vaishangi, additional, Das, Bappa, additional, Kumar, Sudhir, additional, Dhandapani, Raju, additional, Vishwakarma, Chandrapal, additional, Pal, Madan, additional, and Chinnusamy, V., additional

Published

2019

30. Next generation phenotyping for developing climate resilient rice varieties

Author

Sahoo, Rabi N, primary, Viswanathan, C, additional, Krishna, Gopal, additional, Das, Bappa, additional, Goel, Swati, additional, Dhandapani, Raju, additional, Kumar, Sudhir, additional, Viswakarma, Chandrapal, additional, Swain, P, additional, and Dash, SK, additional

Published

2019

31. Application of thermal imaging and hyperspectral remote sensing for crop water deficit stress monitoring.

Author

Krishna, Gopal, Sahoo, Rabi N., Singh, Prafull, Patra, Himesh, Bajpai, Vaishangi, Das, Bappa, Kumar, Sudhir, Dhandapani, Raju, Vishwakarma, Chandrapal, Pal, Madan, and Chinnusamy, V.

Subjects

THERMOGRAPHY, REMOTE sensing, CROPS, WILD rice, LEAST squares, THERMAL imaging cameras

Abstract

Water deficit in crops induces a stress that may ultimately result in low production. Identification of response of genotypes towards water deficit stress is very crucial for plant phenotyping. The study was carried out with the objective to identify the response of different rice genotypes to water deficit stress. Ten rice genotypes were grown each under water deficit stress and well watered or nonstress conditions. Thermal images coupled with visible images were recorded to quantify the stress and response of genotypes towards stress, and relative water content (RWC) synchronized with image acquisition was also measured in the lab for rice leaves. Synced with thermal imaging, Canopy reflectance spectra from same genotype fields were also recorded. For quantification of water deficit stress, Crop Water Stress Index (CWSI) was computed and its mode values were extracted from processed thermal imageries. It was ascertained from observations that APO and Pusa Sugandha-5 genotypes exhibited the highest resistance to the water deficit stress or drought whereas CR-143, MTU-1010, and Pusa Basmati-1 genotypes ascertained the highest sensitiveness to the drought. The study reveals that there is an effectual relationship (R2 = 0.63) between RWC and CWSI. The relationship between canopy reflectance spectra and CWSI was also established through partial least square regression technique. A very efficient relationship (calibration R2 = 0.94 and cross-validation R2 = 0.71) was ascertained and 10 most optimal wavebands related to water deficit stress were evoked from hyperspectral data resampled at 5 nm wavelength gap. The identified ten most optimum wavebands can contribute in the quick detection of water deficit stress in crops. This study positively contributes towards the identification of drought tolerant and drought resistant genotypes of rice and may provide valuable input for the development of drought-tolerant rice genotypes in future. [ABSTRACT FROM AUTHOR]

Published

2021

32. Polyvinylpyrrolidone oral films of enrofloxacin: Film characterization and drug release

Author

K. Sandeep, G. S. Prabhakara, Jagadeesh S. Sanganal, Rashmi Ns, A.R. Phani, N. Manali, Dhandapani Raju, C. Paul Salins, R. G. S. V. Prasad, G. Prem Kumar, and R. Gupta

Subjects

Surface Properties, Administration, Oral, Pharmaceutical Science, Gram-Positive Bacteria, Gram-Negative Bacteria, Spectroscopy, Fourier Transform Infrared, medicine, Enrofloxacin, Organic chemistry, Solubility, Thin film, chemistry.chemical_classification, Drug Carriers, Calorimetry, Differential Scanning, Dose-Response Relationship, Drug, Polyvinylpyrrolidone, Povidone, Polymer, Anti-Bacterial Agents, Bioavailability, Drug Liberation, chemistry, Microscopy, Electron, Scanning, Swelling, medicine.symptom, Antibacterial activity, Fluoroquinolones, Nuclear chemistry, medicine.drug

Abstract

Enrofloxacin is a fluoroquinolone derivative used for treating urinary tract, respiratory and skin infections in animals. However, low solubility and low bioavailability prevented it from using on humans. Polyvinylpyrrolidone (PVP) is an inert, non toxic polymer with excellent hydrophilic properties, besides it can enhance bioavailability by forming drug polymer conjugates. With the aim of increasing solubility and bioavailability, enrofloxacin thin films were prepared using PVP as a polymer matrix. The obtained oral thin films exhibited excellent uniformity and mechanical properties. Swelling properties of the oral thin films revealed that the water uptake was enhanced by 21%. The surface pH has been found to be 6.8±0.1 indicating that these films will not cause any irritation to oral mucosa. FTIR data of the oral thin films indicated physical interaction between drug and polymer. SEM analysis revealed uniform distribution of drug in polymer matrix. In vitro drug release profiles showed enhanced release profiles (which are also pH dependant) for thin films compared to pure drug. Antibacterial activity was found to be dose dependent and maximum susceptibility was found on Klebsiella pneumonia making this preparation more suitable for respiratory infections.

Published

2014

33. Cerium Oxide Nanoparticles Promotes Wound Healing Activity in In-Vivo Animal Model

Author

R. S. L. Aparna, Venkata Srinivas Jakka, Dhandapani Raju, Revathy Davan, R. G. S. V. Prasad, A.R. Phani, Paul C. Salins, and Biju Jacob

Subjects

Biomaterials, Cerium oxide, Chemistry, Biomedical Engineering, Biophysics, Nanoparticle, In vivo animal model, Wound healing, Biotechnology

Published

2012

34. Heterotic grouping and patterning of quality protein maize inbreds based on genetic and molecular marker studies

Author

Ambika Rajendran, John Joel, Dhandapani Raju, Arunachalam Muthiah, and Ponnusamy Shanmugasundaram

Subjects

Genetics, Heterotic string theory, Genetic diversity, Key words: Heterotic group,heterotic pattern,quality protein maize,genetic diversity, Physiology, Heterosis, Cell Biology, Biology, Microbiology, Diallel cross, chemistry.chemical_compound, chemistry, Genetic distance, Yield (chemistry), Molecular marker, Grain yield, General Agricultural and Biological Sciences, Molecular Biology

Abstract

An investigation was done to study the heterotic grouping and patterning in quality protein maize inbreds. Biochemical screening resulted in the choice of 3 inbreds each with high (UQPM 2, UQPM 4, and UQPM 21) and low (UQPM 18, UQPM 19, and UQPM 20) lysine and tryptophan contents respectively for genetic studies using diallel analysis. UQPM 20 × UQPM 18 was notable as it possessed high standard heterosis and specific combining (sca) effect for grain yield, protein, tryptophan, and lysine. Based on yield sca, the 6 parental inbreds were classified into 3 heterotic groups. Intergroup cross UQPM 20 × UQPM 18 was the best in yield and quality. The superior heterotic pattern was flint × dent. In genetic diversity analysis using simple sequence repeat markers, the inbreds of the best hybrid, UQPM 20 × UQPM 18, lay in same cluster but different subclusters. Correlations between genetic distance and sca effects were low for grain yield, which hampers the prediction of heterosis from molecular data alone.

Published

2014

35. Cerium Oxide Nanoparticles Protects Gastrointestinal Mucosa From Ethanol Induced Gastric Ulcers in In-Vivo Animal Model

Author

Dhandapani Raju, Rangabhatla Gunneswara Subramanya Vara Prasad, Shankar Jothi, Ayalasomayajula Ratna Phani, and Revathy Davan

Subjects

chemistry.chemical_compound, Cerium oxide, Ethanol, chemistry, Biomedical Engineering, Nanoparticle, In vivo animal model, Gastrointestinal mucosa, Pharmacology

Published

2013

36. Transport through liquid membranes generated by lecithin, cholesterol and lecithin-cholesterol mixtures in the presence of prostaglandins

Author

R.C. Srivastava, S. P. Upadhyay, V. Singh, and Dhandapani Raju

Subjects

food.ingredient, Chromatography, Passive transport, Cholesterol, Phospholipid, Filtration and Separation, Biological membrane, Membrane transport, Biochemistry, Lecithin, chemistry.chemical_compound, Membrane, food, chemistry, lipids (amino acids, peptides, and proteins), General Materials Science, Physical and Theoretical Chemistry, Lipid bilayer

Abstract

Transport through liquid membranes generated by lecithin, cholesterol and lecithin-cholesterol mixtures has been studied in the presence of prostaglandins. The data indicate that prostaglandins in association with cholesterol may be responsible for the aqueous pores present in the lipid bilayers controlling passive transport through biomembranes. The data further indicate that the presence of cholesterol in each of the two constituent monolayers of the lipid bilayer is essential for pore formation by prostaglandins.

Published

1991

37. Transport through liquid membrane bilayers generated by a lecithin—cholesterol mixture in the presence of insulin and vasopressin

Author

R.C. Srivastava, V. Singh, C Ravindran, and Dhandapani Raju

Subjects

Vasopressin, food.ingredient, Chromatography, Cholesterol, Insulin, medicine.medical_treatment, Bilayer, Lecithin, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Biomaterials, chemistry.chemical_compound, Colloid and Surface Chemistry, Membrane, food, chemistry, Mass transfer, Phosphatidylcholine, medicine

Abstract

Transport through liquid membrane bilayers generated by a lecithin-cholesterol mixture in the presence of insulin and vasopressin has been studied. The data indicate an increase in permeability when a pH gradient is imposed across the membrane such that insulin or vasopressin is present on the acidic side. It has been shown that reversing the pH gradient effectively blocks the change. These trends are consistent with trends reported in the case of channel formation by clostridial toxins in bilayer lipid membranes.

Published

1990

38. Physiological alteration in gladiolus flower during senescence as affected by abscisic acid

Author

Madan Kumar, V.P. Singh, Ajay Arora, Dhandapani Raju, and Akshay Sakhare

Subjects

Horticulture

Published

2015

39. Enhancement of dissolution rate of piroxicam by electrospinning technique

Author

A.R. Phani, S K Raziya Begum, M. Mohan Varma, Biju Jacob, Dhandapani Raju, R. G. S. V. Prasad, and Paul C. Salins

Subjects

chemistry.chemical_classification, Materials science, technology, industry, and agriculture, Polymer, Piroxicam, Biodegradable polymer, Industrial and Manufacturing Engineering, Electrospinning, chemistry, Chemical engineering, Polymer ratio, Nanofiber, Polymer chemistry, medicine, General Materials Science, Electrical and Electronic Engineering, Fourier transform infrared spectroscopy, Dissolution, medicine.drug

Abstract

The use of electrospun nanofibers to enhance dissolution of poorly soluble drugs could be a novel strategy in future for pharmaceutical applications. In the present work electrospun nanofibers were prepared as a novel system for enhancing the delivery of piroxicam, a non-steroidal anti-inflammatory drug (NSAID). These nanofibers were prepared from polyvinyl pyrrolidone (PVP) (pharmaceutical grade), a biodegradable polymer, to obtain a solution with drug:polymer ratio of 1:4. The release rate of the piroxicam nanofibers was studied in simulated gastric fluid. Fourier transform infrared (FTIR) and scanning electron microscopy (SEM) are used to evaluate the chemical and physical nature. The results showed that the release rates were twice increased in comparison with the pure drug. However, the blend of drug and polymer could be varied to optimize the release rates depending upon the need and formulation

Published

2012