Sea Cage farming India

 

Sea cage culture involves growing fishes in the sea while being enclosed in a net cage which allows free flow of water. It is a production system comprising of a floating frame of varying dimensions and shape, net materials and mooring system, to hold and culture a large number of fishes.

Advantages of Sea Cage Farming

• 
  Cage farming can be undertaken in open seas, sheltered bays or lagoons having suitable water quality and with prior permission from concerned government authorities. Thus, the vast unutilized areas in the sea can be brought under mariculture practices.
• Production per unit (m³) in cage culture is 50 times more than shore based systems.
• Recurring expenditure associated with development and maintenance of infrastructure are lower in cage farming compared to shore based farming practices.
• Stock monitoring is simple in cage farming, facilitating regular observation of behavior, feeding and growth that are critical in avoiding problems related to stress and disease outbreak.
• Harvesting is easy and can be planned as per the demand, offering better quality product at higher price.

Quality of fish seed is of vital importance for the success of grow-out culture in cages. Uniform size seeds appropriate for the mesh size of the fish net cage should be stocked to prevent their escape. This will also help in selecting the correct sized feed for fishes, avoid wastage of feed and reduce cannibalism. Seeds should be healthy, free from diseases and deformities.

The most vital issue for the expansion of the sea cage farming in India is the shortage of fish seeds. Presently seed of Cobia, Pompano, Seabass and Groupers are being produced in a few hatcheries in the country. Apart from these species, seeds of fishes like Mullets, Snappers, Milkfish, etc. collected from the wild can also be used for cage farming. To meet the growing demand from farmers, there is an urgent need to produce sufficient quantity of seed either through commercial hatchery production or by importing till we achieve self-sufficiency in seed production.

List of Marine Fish Hatcheries

• CMFRI, Mandapam, Tamil Nadu  - Cobia, Pompano
• CMFRI, Visakhapatnam, Andhra Pradesh - Grouper, Pompano
• RGCA (MPEDA), Pozhiyoor, Kerala - Seabass, Cobia, Pompano
• CIBA, Chennai, Tamil Nadu - Seabass  

 Document-https://en.vikaspedia.in/viewcontent/agriculture/fisheries/marine-fisheries/culture-fisheries/guidelines-for-sea-cage-farming-in-india#section4

Rural Technology Action Group (RuTAG) Progress report

 

The Rural Technology Action Group (RuTAG) was conceptualized in 2003-04 by the Office of the Principal Scientific Adviser (OPSA) to the Government of India and formally established in 2004. RuTAG functions as a demand-driven mechanism with a focus on identifying grass-root needs through field-level engagement, and on the development and dissemination of appropriate technologies that are locally relevant, affordable, and sustainable.

The Fine Madurkathi grass mat weaving sector faces persistent issues of low productivity, physical strain, and limited design flexibility due to manual weaving practices. To address these challenges, RuTAG IIT Madras is developing an Electronic Jacquard Handloom (EJH) - a semi-automated, ergonomically designed loom that enables digital pattern control and improved working posture to support traditional weavers, ensuring sustainable and inclusive growth in the craft sector.

Manual planting of rhizomes such as ginger and turmeric is labor-intensive, time-consuming, and prone to uneven spacing, affecting crop yield and overall productivity. RuTAG IIT Guwahati is developing a compact, low-cost rhizome planter suited for small and hilly farms of the northeastern region. Designed for power tiller or power weeder operation, the machine aims to improve planting uniformity, reduce drudgery, and increase mechanization among small and marginal farmers.

Pottery clusters in Rajasthan, particularly Poonchhari village near Bharatpur, rely on traditional manual methods for producing earthen tawas (griddles). Artisans shape and sun-dry the tawas before firing them using layers of mustard husk and dung cakes- a slow and physically demanding process. The Manual Press for Earthen Tawa Making, developed by RuTAG IIT Delhi, aims to assist these artisans by enabling uniform shaping, improving productivity, and enhancing the quality of the finished tawas.

Millets such as finger millet, foxtail millet, and barnyard millet are staple crops among small and marginal farmers in India, especially in Uttarakhand and Himachal Pradesh. However, traditional de-husking practices using hand tools like Okhli are labor-intensive, time-consuming, and yield inconsistent quality. To address these challenges, RuTAG IIT Roorkee has designed and developed a low-cost, compact multi-millet de-husking machine aimed at improving efficiency, reducing drudgery, and enhancing the livelihood of rural millet growers and processors.
The Solar Hydro Distiller (SHD) developed by RuTAG IIT Bombay is an innovative solar-thermal technology designed to convert perishable agricultural and floral waste into valuable natural products such as rose water and herbal hydrosols. 

From NAARM-The ColdEasy system is an affordable, energyefficient cold storage solution designed to extend the shelf life of fruits and vegetables in rural and semiurban areas. It converts any regular room into a cold room, ensuring better preservation, reduced wastage, and enhanced farmer income while consuming minimal power.

Report-https://psa.gov.in/CMS/web/sites/default/files/publication/RuTAG%20Annual%20Progress%20Report_2024-25.pdf

Niti Aayog report for "Transforming India into a Quantum-Powered Economy"

 

On Thursday Dec 4, Niti Aayog unveiled their roadmap report for "Transforming India into a Quantum-Powered Economy" as part of their Frontier Tech Hub initiative. The report identifies five ambitious 2035 endpoints for the 10 year roadmap for India:

• Incubating at least 10 globally competitive quantum startups, each surpassing USD 100 million in revenue,
• Capturing over 50% of the value in the global quantum software and services market by harnessing our software and engineering strength,
• Achieving meaningful, scaled deployment of quantum technologies—home-grown and global—in strategic sectors3 across India,
• Commanding critical positions in the global quantum supply chain for both hardware and software, creating strategic dependencies and value, and
• Becoming a source of foundational scientific breakthroughs, with world-class research.
• Report-https://niti.gov.in/sites/default/files/2025-11/Roadmap_for_Transforming_India_into_a_Leading_Quantum_Powered_Economy.pdf

Key developments of breeding tools and techniques over time (EC Report)

 In order to develop new varieties which for example respond to changing biotic and abiotic pressures, or have a commercial value such as improved nutritious values or new colours, the tools breeders use developed over time: 

• Traditionally, breeding is based on the principle of crossing and selecting the naturally existing diversity of plants. Since the rediscovery of Mendel’s rules around 1900, breeders experimented with intentional crossing between selected parent plants to obtain desirable traits. If offspring had a highly beneficial trait, it was preserved and propagated for further breeding over generations. 

• Tissue culture is among the earliest techniques used for growing plant cells (Haberlandt 1902). Further developments led to the application of tissue culture to five broad areas, namely, cell behaviour, plant modification and improvement, pathogen-free plants angermplasm storage, clonal propagation, and product formation, starting in the mid-1960s.

• In the mid 20th century, the development of hybrid varieties led to dramatic increases in yield in maize, followed by a range of crops. A hybrid variety is comprised of a population originating from a cross and is directly used as the commercial variety to be cultivated. Hybrids present enhanced performance and uniformity compared to either parent. Due to their hybrid nature, their offspring will segregate and result in a heterogenous population that will not perform as well as the hybrid parents. 

• Internationally coordinated mutation breeding became popular in the 1960s, mainly radiation and the use of chemicals created genetic variation. It led to numerous new cultivated varieties of many species such as broccoli, nectarines, or rapeseed. 

• The discovery of molecular markers since the early 1980s enabled breeders to track traits at the genetic level without waiting for the plant to mature. This marker assisted selection (MAS) technique made selection faster, cheaper and more precise. 

• Genetic engineering tools were developed in the 1980s and 1990s. The decision in the U.S. to allow patents on genetically modified microorganisms (Chakrabarty vs Diamond 1980) and the patent on the rDNA technology (Stanford University and the University of California System) led to an uptake of genetic engineering. The available technique allows introducing transgenes into crops to obtain traits such as herbicide tolerance or insect resistance. Bt maize and Bt cotton, which are resistant to certain pests, are primary examples. In 1987, the U.S. start-up Calgene obtained a patent in the U.S. on a tomato with a trait for longer shelf life.

• The genomic sequencing of crop genomes provides understanding complex traits. The first full genome sequencing of the model plant Arabidopsis thaliana in the year 2000, is hailed as the turning point for the modern plant breeding research. Since then, hundreds of plant species, including all major agronomically relevant crops (such as rice (2002/2005), maize (2009), soybean (2010), millet (2017), wheat (2018), and oat (2022)), root crops (potato (2011)), vegetables (chickpea (2013), brassica (2014), cassava (2016), pea (2019)), or fruits (papaya (2005), apple (2010), peach (2013)), have been sequenced.

• Since around 2010, CRISPR/Cas and other genome editing technologies allow breeders to target modifications without introducing foreign genes. In particular CRISPR/Cas9 has been in the focus and is a key patented technology with applications in plants since 2014. The system has been continuously developed since its discovery and a broader range of tools are available such as base editing or prime editing. These use different tools such as Cpf1 (now called Cas12a). 

• Speed breeding – combination of techniques used under controlled environments to accelerate the plant growth cycle while machine learning and genomic data analysis provides breeders with tools to optimise breeding decisions (precision breeding). Various companies – in particular in the U.S. - offer platforms to develop the envisaged plant as service providers (e.g. GreenVenus, Pairwise). 

• Integrated approaches for ‘next-generation plant breeding’ – increasingly breeders can use integrated pipelines (platforms) that offer convergence of multiple advanced methods to optimise the development of improved plant varieties. Genomic selection, speed breeding, genome editing and pangenomics, high-throughput phenotyping are combined with machine learning and the integration of -omics – to name currently available tools. • Other tools including high-throughput phenotyping and genotyping expanded the array of tools and enabled the rapid analysis of large numbers of plants and their genomes.

(https://webgate.ec.europa.eu/circabc-ewpp/d/d/workspace/SpacesStore/e374dbb4-9cf9-4799-8d18-98a459a08c34/download)

European Commission publishes study on IP and agricultural biotechnology

 

European Commission published its "NGT patent study" . In 2023, the Commission requested an evidence-based analysis of how patents related to new genomic techniques (NGTs) affect innovation in plant breeding, as well as breeders' access to genetic material and availability of seeds to farmers. 

This study examines how the current intellectual property (IP) framework affects breeders, farmers, and plant biotechnology actors, with a particular focus on the use of new genomic techniques (NGTs) in developing new plants. The analysis combines legal, economic, and market perspectives using a multi-method approach, allowing the study to offer both quantitative indicators and qualitative insights reflecting stakeholders’ practical experiences. The report emphasises the interplay between IP rules and market realities, and highlights how this interaction shapes opportunities and constraints in the sector. The European plant breeding sector is technologically sophisticated yet structurally diverse, with many SMEs operating alongside a small number of large international firms. Breeding is highly research-intensive. The study identifies potential legal and economic impacts arising from patents on NGT plants. The increasing complexity of the patent landscape may pose challenges for smaller breeders to access plant genetic material in terms of licensing costs and freedom-to-operate constraints. The study highlights multiple opportunities to strengthen transparency, support SMEs, and facilitate licensing. Overall, the study concludes that a balanced, coherent, and transparent IP system remains essential for ensuring that the benefits of NGTs are realised across Europe’s plant breeding and farming sectors while maintaining diversity, competition, and long-term resilience.

Report-https://webgate.ec.europa.eu/circabc-ewpp/d/d/workspace/SpacesStore/e374dbb4-9cf9-4799-8d18-98a459a08c34/download

ipkat analysis-https://groups.google.com/g/ipkat_readers/c/KFTacG976GE/m/ZSAbQ0urCQAJ?utm_medium=email&utm_source=footer