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Antimicrobial plastic products are in increasing demand across healthcare, consumer products, and industrial sectors to reduce the spread of harmful microbes while maintaining material performance. However, conventional antimicrobial additives often rely on pre-formed nanoparticles, which are prone to aggregation and can complicate handling and processing, particularly in thin films, fibres, and transparent components. This technology enables the in-process formation and uniform dispersion of silver (Ag) nanoparticles within thermoplastic resins during standard polymer processing, such as extrusion and injection moulding. By incorporating silver fatty acid salts into the resin formulation, nanosized silver particles are generated during thermal processing and stabilised within the polymer matrix, ensuring consistent dispersion under typical shear and thermal conditions. The resulting silver nanoparticles, with sizes on the order of several tens of nanometres, deliver reliable antimicrobial performance at very low additive loadings (as low as 0.01 wt%), while preserving optical clarity and mechanical properties. Accordingly, this technology is particularly well suited for incorporating antimicrobial agents into thin films and fibres, where optical clarity and defect-free moulding are critical. When used in fibres, it helps prevent filament breakage during melt spinning. A resin-compounded antimicrobial masterbatch based on this technology has already been commercialised in products such as face masks and waste bags, demonstrating scalability and real-world applicability. The technology owner is seeking test bedding and pilot deployment partners in resin processing, polymer manufacturing, and end-product sectors to validate performance, scale production, ensure regulatory compliance, and expand application portfolios. In parallel, dispersion methods for solvent-based systems are under development, and partners in surface coatings and film manufacturing are welcomed for co-development and scale-up opportunities. This technology enables in-process formation and dispersion of silver nanoparticles within thermoplastic resin, such as polypropylene (PP), polyethylene (PE) and polystyrene (PS), ensuring consistent antimicrobial efficacy without compromising processability and final product quality in terms of transparency and mechanical performance. Key technical features include: Nanoparticle size: several tens of nanometres, enabling preservation of material properties Low active silver loading: effective at ~0.01 wt% without performance loss Antibacterial performance: verified in accordance with ISO 20743 and 22196, effective against a broad spectrum of bacteria, including both Gram-positive and Gram-negative species (e.g., Staphylococcus aureus and Escherichia coli) Process compatibility: compatible with standard extrusion and injection moulding processes Optical clarity: high transparency retained even in thin films and fibres, without haze or whitening Safety validation: confirmed through acute oral toxicity, skin irritation, mutagenicity, and skin sensitisation tests Adaptability: available as an antimicrobial masterbatch with industrial supply capability; solvent-based dispersions under development for coating applications This technology enables antimicrobial functionality across a wide range of polymer-based products and multiple industries, including but not limited to:   Hygiene & Personal Care: antibacterial seals, labels, hygiene items Home Care & Household Goods: garbage bags, antibacterial packaging, kitchen products Textiles & Apparel: masks, underwear, towels, sheets, medical linens, gowns Healthcare & Medical: medical gowns, bed linens, instrument covers, antimicrobial components Commercial & Institutional Coatings: high-touch surfaces such as handrails and doorknobs Consumer Electronics & Accessories: phone cases, remotes, keyboards Building Materials & Interiors: panels, wall and floor coverings, furniture surfaces Industrial Applications: antibacterial packaging, workwear, industrial components The technology is particularly suitable for moulded parts, thin films and coated surfaces where both antimicrobial performance and visual quality are critical. Achieve high antimicrobial efficacy with very low silver content, reducing material usage and cost while maintaining consistent performance In-process formation of silver nanoparticle ensures uniform dispersion, preserving transparency and mechanical integrity Integrate seamlessly into polymer processing workflows, eliminating nanoparticle handling and reducing operational complexity, safety risks, and regulatory burden Masterbatch format enables easy, reproducible and industrial-scale deployment without major equipment modifications In-situ formatio, Silver nanoparticles, Uniform dispersion, High transparency, Antimicrobial performance Materials, Plastics & Elastomers, Chemicals, Polymers, Environment, Clean Air & Water, Sanitisation, Manufacturing, Chemical Processes, Additives

With global warming intensifying, cooling demands for buildings, equipment, vehicles, and outdoor infrastructure are rising rapidly. Conventional cooling solutions—such as air conditioning, mechanical ventilation, and electrically powered thermal management—are energy-intensive and contribute significantly to operational costs and greenhouse gas emissions.  As countries seek to reduce energy consumption while maintaining thermal comfort and system reliability, passive radiative cooling solutions are gaining traction to lower operational energy use while improving thermal stability in heat-exposed environments. This technology is a film-based radiative cooling material with a reflective layer engineered for passive outdoor thermal management.  Designed with high solar reflectivity and efficient thermal emission, the film incorporates silver within the reflective layer to maximise reflection of near-infrared solar radiation, thereby reducing heat absorption. At the same time, it enables effective radiation of infrared heat through the atmospheric window to the environment, allowing the applied surfaces to remain cooler than the surrounding air even under direct sunlight. The combined effect is a reduction of temperature rise on applied surfaces, lowering heat stress for buildings, machinery, and cargo spaces. The film is applicable across different sectors, including the built environment, industrial facilities, logistics and transportation, and public infrastructure. The technology owner is seeking co-development and pilot collaboration partners to conduct test-bedding and performance optimisation in tropical operating environments such as Singapore, supporting energy efficiency, heat resilience, and decarbonisation objectives across diverse sectors.  Partners with film manufacturing capabilities are also welcomed for joint development and scale-up opportunities. This technology is a polymeric passive radiative cooling film material designed for outdoor thermal management. Key technical features include: Enhanced solar reflectivity through integration of silver within the reflective layer to maximise near-infrared solar reflection High solar heat reflectance, with measured solar heat reflection in the range of approximately 88–95% Designed for long-term outdoor use, with durability under continuous exposure to direct sunlight for up to 7 years through an internal evaluation method on accelerated weathering test. Substrate compatibility with common materials such as steel and resin-based surfaces Flexible supply formats, available in sheet or roll form with an adhesive layer for ease of installation, with options for basic surface customisation e.g., markings or text on the top layer Performance validation:The film has been evaluated through pilot deployments in Japan. When applied to the external façade of a residential building, the film demonstrated surface temperature reductions of up to 25°C under summer conditions, alongside energy savings of up to 40%. In a separate pilot involving application on a refrigerated truck, the film achieved approximately 20% reduction in fuel consumption over a two-month summer period compared to the previous year. The radiative cooling film can be applied across a wide range of heat-exposed surfaces and assets where passive temperature reduction can improve energy efficiency, operational reliability, and user comfort. Potential applications of the film include (but not limited to): Built environment e.g., roofs, façades, and external walls of buildings Logistics, transportation and storage e.g., shipping containers, reefer trucks, storage facilities for temperature-sensitive goods Public infrastructure and urban assets e.g., outdoor public facilities and urban installations Energy-free heat mitigation – provides passive cooling without electricity or active systems, helping to reduce energy consumption, operating costs, and carbon emissions in heat-exposed environments. Simple retrofit for existing assets – film-based form factor enables easy integration onto existing buildings, equipment, and infrastructure without major redesign or disruption. Designed for outdoor and tropical conditions – Engineered for continuous exposure to direct sunlight, supporting improved thermal stability and asset protection in hot and humid climates such as Singapore. passive, cooling, radiative, film, silver, heat reflective, heat resilience, surface reduction, thermal emission, thermal management, solar reflectivity, sustainability, sustainable living, urban heat island effect, global warming Materials, Composites, Green Building, Façade & Envelope, Logistics, Transportation, Sustainability, Sustainable Living

Social issues such as labor shortages are becoming more apparent, making it urgent to utilize digital technology to transform workflows and work styles. In particular, there has been increasing demand for spatial digitalization to manage buildings and streamline renovation processes across various fields. When digitalizing buildings, offices, factories, and other spaces, it is necessary to measure dimensions and create floor plans, which often involves manual work. However, measuring all dimensions and generating floor plans or 3D models manually takes a significant amount of time. Moreover, overlooked measurements often require additional site visits, further delaying the process. Recently, spatial digitalization using sensors such as cameras has been introduced to address these challenges. By sensing spaces and generating point clouds, which are then converted into 3D models, efficiency can be improved. However, existing methods still present issues. Creating point clouds with desktop devices is costly and time-consuming. When using general mobile devices, the accuracy is low and results depend heavily on the operator. Furthermore, transforming point clouds into 3D models often requires extensive manual work and considerable time. This method addresses these challenges. Using low-cost mobile devices, anyone can quickly and accurately acquire point clouds, which can then be automatically transformed into 3D models within just a few hours. Assistance System – Data capture is completed in a single scan with the assistance system, which enables even beginners to obtain high-precision point clouds. This eliminates the need for repeated measurements and significantly improves workflow efficiency. Automatic BIM Transformation – Point clouds are automatically converted into BIM models on the spot, allowing immediate sharing of results. This not only reduces processing time but also accelerates decision-making by enabling discussion on building management at an early stage. Realistic 3D Representation – High-accuracy point clouds combined with realistic 3D visualization enable remote space inspection. This simplifies spatial review, accelerates consensus-building, and reduces travel costs. The technology owner is seeking collaboration with Digital Twin developers, BIM/CAD 3D platformers, IoT solution providers, system integrators, and IT consultants who can co-develop the technology to enhance functionality and differentiation, as well as develop and implement systems that support commercialization and market deployment. Spatial information with high speed and high accuracy during renovation can reduce costs, enable high-quality proposals, and be applied across various use cases: Digital Twin Building management: Manage energy and facilities through a unified digital model. Construction inspection: Inspect by comparing the digital twin with actual construction progress. Design & Planning Office renovation: Design comfortable and productive office environments. Store design: Create retail layouts optimized to attract customers. Digital Twin Reduces digitization time and accelerates the realization of digital building management Streamlined spatial digitization leads to lower labor costs and facilitates scalable deployment across multiple locations Provides real-time visibility into physical spaces for better operational control. Design & Planning Immediate spatial digitalization allows execution without interrupting on-site operations Accelerates decision-making through clear, shared spatial understanding. Enhances collaboration among stakeholders with a common digital reference. Simultaneous Localization and Mapping (SLAM), 3D Reconstruction, Modelling, Digitalizing Buildings, CAD, BIM Infocomm, Video/Image Analysis & Computer Vision, Artificial Intelligence

In manufacturing there are many instances where there is a need for low production runs of parts. These could be for parts of an equipment, tools, small volume runs for trials or customised parts. However, traditional manufacturing techniques are usually not cost-effective for such low volume runs, while current additive manufacturing suffers from low strength, long print times and poor surface finish needing post-processing. Additionally, for techniques using powder and filaments, considerations have to be given to the storage and operational set-up due to oxidation, degradation, flammability and toxicity of these precursor materials. The tech owner has developed a hybrid manufacturing technique that involves both additive and subtractive manufacturing methods. Instead of powder or filaments, sheets and foils are used as precursor materials, thereby alleviating cost, safety and performance concerns that were outlined. A laser is used to cut and fuse the different layers of the build.   Numerous tests conducted by the team have consistently yielded parts that are dense and displayed high strength. The system is able to work with different materials, including highly reflective ones such as stainless steel, aluminium, copper. Based on initial estimates, this technique offers up to 30% - 50% cost advantage over powder bed systems. The tech owner is seeking partners to collaborate in test bedding the system for manufacturing of complex, customised and/or high strength / high thermal conductivity parts for applications in the healthcare, semiconductor, aerospace, automotive, telecoms or marine & offshore sectors. Print performance specifications: Smallest feature that can be printed - 50um Highly dense structure <= 0.5% porosity Surface finish of Ra <4 μm Complex structures with overhangs Powder free, enables fully-enclosed spaces and channels without need to powder removal Printer specifications:  Build Area – 125 mm x 125 mm Desktop printer to plug-and-play Compact footprint of 1m x 1m x 1m  Energy deposition module that is based on commercially available laser source In-house proprietary slicer software and printer controller software  In-house developed precursor material handling module Heat exchangers – micro cooling channels   Semiconductor equipment Dental/bone implants; prosthetics; surgical tools Aerospace parts Automobile parts Mobile Device parts (e.g. Smartphone, laptop, smartwatch shells and casings) Unlike powder bed system, there is no need for expensive environment controlled chambers Safer and cheaper precursors (sheets and foils vs powder and filaments) Printed parts are higher strength (Example – Stainless Steel SS304L, up to 1 GPa yield strength) Printed parts are fully dense (<= 0.5% porosity) Lead time is significantly reduced for fully solid designs Can fabricate enclosed channels Surface roughness is 3 times smoother than powder bed techniques Minimal post-processing (e.g. sand-blasting) is necessary Compatible with different material classes (composites, metals, polymers, ceramics)   3D printing, Additive manufacturing, Subtractive manufacturing, Laser, Laser system, Powder bed, Low volume manufacturing Manufacturing, Additive Manufacturing, Subtractive Machining

Managing contracts and legal documents efficiently remains a core challenge for enterprises across functions including legal, procurement, sales, HR, finance, and compliance. Manual processes, fragmented tools, and siloed teams often lead to delays, compliance gaps, and unnecessary operational costs. This technology is a comprehensive AI-powered contract lifecycle management (CLM) and document management platform that automates and centralises all stages of contract handling — from creation, collaboration and negotiation to approvals, execution, storage, tracking, analytics, and renewals. By combining workflow automation, secure repositories, analytics and collaboration features in a single user-centric platform, organisations can achieve higher productivity, stronger governance, and reduced legal and operational risk. With multi-jurisdictional support, multi-language interfaces, and a suite of secure cloud-based tools, this platform delivers enterprise-grade contract management that is scalable across teams and regions while ensuring compliance with regulatory requirements. End-to-End Contract Lifecycle Management Enables organisations to manage each phase of the contract lifecycle — template creation, clause libraries, drafting, negotiation, approvals, signing, performance tracking, renewals and expirations — within a unified environment. Workflow Automation & Approval Routing Customisable no-code workflow builder that automates contract review and approval processes, reducing bottlenecks and ensuring compliance with internal policies. Secure Centralised Repository A searchable, cloud-based document vault with access control, version history, and audit trails to maintain transparency and facilitate secure collaboration. Collaboration & Negotiation Tools In-platform communication, real-time versioning, automated redlining, and task assignment streamline cross-team and external stakeholder interactions. eSignature & Compliance Built-in electronic signatures and compliance-oriented workflows eliminate the need for third-party tools and help meet regulatory standards across multiple jurisdictions.   Legal & Compliance Accelerate legal review and negotiation Maintain audit-ready records of contract changes and approvals Reduce compliance risk through automated checks Procurement & Vendor Management Streamlined procurement contracts and vendor agreements Real-time visibility into vendor obligations and performance Sales & Revenue Teams Faster contract drafting and approval processes Built-in eSignature to accelerate deal closures HR & Admin Functions Standardise employment contracts, NDAs and internal policies Centralised storage with access control and versioning Enterprise Governance & Risk Analytics and obligation tracking to mitigate organisational risk Cross-departmental insights into contractual bottlenecks This technology consolidates disparate contract and document processes into a single, secure, AI-enhanced platform tailored for enterprise needs. By automating repetitive tasks (e.g., drafting, approvals, tracking) and centralising documentation and workflows, the platform delivers clear productivity gains, enhanced compliance posture, reduced cycle times, and deeper visibility into contractual performance — unlocking significant operational and financial value. Infocomm, Artificial Intelligence

While generative AI presents significant opportunities for productivity gains and innovation, many organisations face challenges in adoption due to limited AI expertise, complex system integration requirements, and concerns around security and governance. This technology is an enterprise-grade, low-code/no-code generative AI application platform that enables organisations to rapidly design, deploy, and manage customised AI-powered applications without extensive software development or machine learning expertise. The platform supports multi-agent AI orchestration, integrates with a wide range of pretrained and proprietary models, and offers flexible deployment options including secure cloud, private cloud, and on-premise environments. By abstracting the complexity of AI development and providing built-in governance, monitoring, and workflow orchestration capabilities, the platform allows organisations to accelerate AI adoption while maintaining control, security, and compliance. Low-Code AI Application Builder Enables rapid creation of AI-powered applications such as conversational agents, intelligent assistants, automated report generators, and document processing tools without writing code. Multi-Agent Workflow Orchestration Supports the design and coordination of multiple AI agents to automate complex, multi-step business processes (e.g. information retrieval, validation, analysis, and response generation). Model-Agnostic Architecture Allows users to access a curated library of pretrained models or integrate proprietary and third-party models via APIs, providing flexibility and avoiding vendor lock-in. Flexible & Secure Deployment Supports deployment across public cloud, private cloud, or on-premise environments, with enterprise-grade security controls, access management, and data protection. Monitoring, Analytics & Governance Provides real-time visibility into AI usage, performance, and behaviour, enabling optimisation, auditability, and responsible AI governance. Enterprise Process Automation Automation of administrative and operational workflows Intelligent assistants for internal knowledge management and decision support Customer Engagement & Support AI-powered chatbots and virtual agents for customer enquiries Automated classification and analysis of customer feedback Data & Document Intelligence Extraction and structuring of information from unstructured documents such as contracts, invoices, and reports Automated summarisation and compliance checks AI-as-a-Service & System Integration Packaging AI workflows as APIs for integration with existing enterprise systems (e.g. CRM, ERP, analytics platforms) Unlike conventional AI development approaches that require specialised technical teams and long development cycles, this technology enables organisations to rapidly prototype, deploy, and scale customised generative AI applications through a configurable, modular, and secure platform. This significantly reduces time-to-value while empowering business users to actively participate in AI-driven transformation. Infocomm, Artificial Intelligence

Concrete production is a major contributor to carbon emissions due to its high cement content and intensive resource use. In Singapore, the challenge is amplified by reliance on imported materials and increasing pressure to meet Green Mark and national decarbonisation targets, while maintaining cost and performance requirements. Biochar Concrete integrates biochar, a carbon-negative material derived from biomass into conventional concrete mixes. Biochar permanently sequesters carbon and enhances the concrete’s microstructure, while remaining compatible with existing batching and construction processes. By reducing embodied carbon and reliance on high-carbon cement, Biochar Concrete enables more resource-efficient and sustainable construction without compromising durability or performance. This scalable solution supports Singapore’s Green Building goals and advances the transition towards a low-carbon built environment. The technology is suitable for collaboration with concrete producers, precast manufacturers, construction and engineering firms, property developers, research institutions, biomass suppliers, and government for R&D collaboration, licensing, IP acquisition and test-bedding.  The project of innovation in concrete enhancement technology redefines sustainability by directly integrating biochar produced from upcycled local wood waste in Singapore. This approach converts biomass waste into a valuable resource, Biochar to support a circular economy and significantly reduce landfill use. It was remarkably improved over conventional concrete, which typically relies on resource-intensive materials. A core advantage of this technology is its enhanced carbon sequestration capability. The biochar acts as a stable, long-term carbon sink, effectively preventing CO₂ from re-entering the atmosphere for centuries. This leads to significantly lower embodied carbon in our concrete. By enabling partial replacement of cement with biochar, the technology reduces CO₂ emissions compared to traditional concrete formulations. For users, this interprets projects with a significantly reduced environmental footprint, aligning with global sustainability goals. Importantly, technology ensures performance comparable to traditional concrete. It maintains similar physical and chemical properties, demonstrating reliable compressive strengths (e.g., 52 MPa at 28 days) and adhering to BS EN 197-1 standards. This seamless compatibility means it integrates effortlessly into existing construction practices without requiring costly retrofits or changes in methodology, offering a diverse and practical advantage over other sustainable concrete solutions. Green building projects requiring low-carbon construction materials Sustainable infrastructure development initiatives Commercial and residential construction projects Precast concrete manufacturing Ready-mix concrete production Environmental construction projects Eco-friendly and low-carbon alternative Turns waste into a high-value material for construction Similar physical and chemical properties to conventional concrete Does not compromise structural performance in construction, making it a viable and sustainable alternative. Biochar, Concrete, Sustainability Materials, Bio Materials

Modern robots are highly capable in structured environments but struggle to handle unstructured tasks that require delicate touch, such as grasping irregular objects or performing fine manipulations. Traditional robotic grippers rely primarily on vision, which are insufficient for dynamic or contact-rich interactions. This technology introduces an AI-driven tactile intelligence platform coupled with tactile-sensing robotic fingers that can perceive and interpret contact pressure, texture, and shape in real time. By integrating advanced tactile sensors with a foundation model trained on tactile data, the platform enables robots to feel and adapt their actions with human-like precision. The technology owner is seeking adopters and collaborators such as robotics OEMs, automation system integrators, healthcare robotics developers, and deep-tech companies working on sensors, embedded systems, or AI analytics. Institutes of Higher Learning and research centres specializing in robotics or tactile perception are also key partners. These groups can leverage the platform to enhance robotic dexterity, precision, and safety across industrial, service, assistive, and manufacturing applications—particularly where delicate handling and high-fidelity tactile sensing are critical. The platform combines compact, non-optical tactile sensors with an AI foundation model for real-time interpretation and autonomous adaptation. This technology provides faster response, greater durability, and AI-driven tactile analytics (rather than fixed feedback) that continuously learn across objects and tasks—delivering smarter, more adaptable robotic manipulation. Key Components Tactile Sensor Array: Embedded multi-array tactile sensors can capture high-resolution tactile maps across each robotic fingertip. Robotic Finger Module: Compact, compliant, and modular finger design that can be mounted onto robotic hands or grippers; supports variable stiffness and sensitive touch. AI Processing Layer: Foundation model trained on large-scale tactile and kinematic datasets to interpret surface properties, object geometry, and grip stability. Industrial Robotics Applications in industrial robotics include automated assembly, sorting, and material handling of fragile or irregular objects. Relevant products: Smart robotic fingers and grippers; tactile AI control modules for industrial robotic arms. Healthcare & Assistive Robotics In healthcare and assistive robotics, the technology supports surgical aids, rehabilitation robots, and prosthetic devices that require safe, compliant, and highly sensitive touch. It enhances patient safety, dexterity, and human–robot interaction in medical environments. Relevant products: Adaptive prosthetic or rehabilitation devices; smart robotic fingers integrated into assistive tools. Service Robotics Service robotics—such as food handling, retail assistance, and hospitality robots—benefit from adaptive gripping capabilities and tactile sensing for safe interaction with diverse objects and customers. Relevant products: Smart robotic fingers and grippers for food-service robots; tactile AI modules for autonomous service systems. Logistics & Warehousing In logistics and warehousing, tactile-enabled manipulation supports efficient pick-and-place automation for e-commerce fulfilment and packaging. The technology improves accuracy when handling varied packaging materials and irregular items. Relevant products: Smart robotic grippers for parcel handling; tactile AI control modules for automated picking systems. Research and Education For research and education, the technology provides tactile perception tools and AI training datasets valuable for advancing human–robot interaction, manipulation research, and foundation model development. Relevant products: Tactile data foundation model licensing for robotics OEMs; research-grade tactile sensor modules and datasets. Unlike conventional robotic grippers that rely mainly on vision, this technology provides true tactile sensing and AI-driven interpretation of touch. It allows robots to understand what they are holding — not just detect that they are touching something. This technology offers real-time tactile feedback for adaptive grasping and slip prevention, powered by an AI foundation model that learns transferable tactile representations across objects and tasks. It is compatible with both rigid and soft robotic systems and operates reliably in any lighting or environment without the need for cameras or external sensors. The scalable data platform further enhances performance by continuously improving model accuracy across deployments. Tactile AI, Robotic Fingers, Smart Grippers, Soft Robotics, Tactile Sensing, Industrial Automation Electronics, Sensors & Instrumentation, Infocomm, Artificial Intelligence, Manufacturing, Assembly, Automation & Robotics, Robotics & Automation

This on-site molecular diagnostic platform enables rapid detection of pathogens in livestock, empowering farmers to identify infections early, before visible symptoms appear. Designed for field conditions, the kits are robust, cost-effective, and user-friendly. By enabling proactive disease surveillance at the farm level, the technology supports timely intervention, reduces antibiotic dependence, and enhances profitability through improved livestock health and reduced mortality losses. This technology combines a DNA extraction method that helps to preserve sample DNA and inactivate pathogens, together with lyophilised reaction beads. The system produces qualitative and semi-quantitative results and is compatible with downstream analyses such as qPCR and sequencing. The technology provider is seeking partnerships across the aquaculture and livestock value chain including research institutions, industry players, and government agencies to scale on-site disease detection and promote sustainable, biosecure food production globally.  ​​Nucleic Acid Extraction system  ​Pathogen-specific nucleic acid amplification reagents  ​All reagents are room-temperature stable and do not require cold-chain transport or special ​storage conditions  ​Built using Loop-Mediated Isothermal Amplification (LAMP) technology, the system delivers lab-grade diagnostic results within 60 minutes  ​DNA is preserved in lysis buffer; pathogens are inactivated  ​Devices for sample processing (Quantitative/Qualitative Readouts)  ​Ideal collaborators include aquaculture and livestock labs, feed mills, hatcheries, animal health companies, and government agencies seeking scalable disease detection tools.  ​The technology strengthens early warning and response mechanisms, supports biosecurity programs, and enables data-driven farm management across multiple segments of the animal health industry, including:  ​Aquaculture: Facilitates routine pond-side monitoring of major shrimp diseases (e.g., WSSV, EHP, AHPND). Farmers currently use it for weekly pathogen surveillance to detect infections early and prevent severe outbreaks  ​Livestock and marine species: Adaptable for detection of pathogens such as TiLV and ASF in both marine and terrestrial species  ​Integrated programs: Can be incorporated into hatchery screening, feed mill quality control, and government surveillance schemes  The global veterinary diagnostics market is projected to exceed USD 7.3 billion by 2030, driven by rising protein demand, increasing disease outbreaks, and the growing adoption of precision livestock farming. In shrimp aquaculture alone, annual disease losses exceed USD 5.9 billion globally. ​Point-of-care convenience: Performs lab-grade diagnostic on-site  ​Rapid and cost-effective: Faster and cheaper than traditional PCR  ​Field-deployable: Operates without a laboratory, cold-chain logistics, or experienced technicians  ​High accuracy: Sensitivity and specificity comparable to PCR, validated in field trials  ​Scalable hardware: Modular design suitable for both smallholder and commercial farms  ​Versatile: Compatible with multiple pathogens across different species  ​Facilitates export compliance: Provides reliable on-site testing data to verify product safety and minimize antibiotic residues  Aquaculture, Diagnostics, Agritech, Molecular Diagnostics, Disease Surveillance, Farm Productivity, Disease Management, Point of Care Technologies Life Sciences, Agriculture & Aquaculture, Biotech Research Reagents & Tools