GEC’s 24-hour composting technology is an advanced system designed to convert organic waste into high-quality compost within a single day. Using a unique combination of heat, aeration, and microbial activity, this composting machine accelerates the decomposition process, producing nutrient-rich compost much faster than traditional methods. The machine operates with controlled temperature settings and automated mixing, creating the optimal environment for microbes to break down waste efficiently. GEC’s technology is versatile, handling a wide range of organic waste including food scraps, garden clippings, and certain biodegradable plastics that meet specific compostable standards. The advantages of GEC’s 24-hour composting technology are substantial. First, the rapid processing time significantly reduces the space and logistical demands associated with waste storage and disposal, making it ideal for urban areas and high-waste generating sectors like hospitality and food processing. Additionally, the compact design and automation minimize manual handling and require limited operational oversight, reducing labor costs. Environmentally, it contributes to waste diversion from landfills, reducing greenhouse gas emissions and supporting sustainable waste management practices. Furthermore, the output compost can be used to enrich soil in landscaping, agriculture, or home gardening, promoting a circular economy model. Overall, GEC’s technology provides an efficient, eco-friendly solution for waste management that aligns with both environmental goals and operational efficiency.

FATIn (Femoral Access Training Intervention) is a portable, anatomically accurate femoral access simulator designed for ultrasound-guided training in vascular access procedures. Its non-complicated design features a replaceable puncture site, enabling repeated practice while maintaining cost-efficiency. The model includes realistic femoral anatomical structures, such as the femoral bone, femoral artery, and femoral vein, ensuring lifelike tactile feedback and visual accuracy during procedures. The simulator supports ultrasound-guided femoral access management, offering a mobile femoral casing for use in various training environments, including classrooms, clinical workshops, and field simulations. Its real-time ultrasound compatibility enables trainees to practice locating and accessing vascular structures, performing needle insertion, and advancing catheters under ultrasound guidance. Replaceable Puncture Sites allow for repetitive use while ensuring hygienic and effective training. This feature minimizes downtime and maintenance costs, making FATIN ideal for high-volume training programs. Its compact, mobile design eliminates the need for extensive setup, allowing on-the-go training sessions and easy transport. FATIN addresses critical challenges in clinical training, including skill development gaps in vascular access procedures, limited access to advanced simulators, and the need for portable, cost-effective solutions. It enhances procedural confidence while reducing learning curves, enabling trainees to gain essential skills in a realistic, risk-free environment. In summary, FATIn is a highly portable, ultrasound-compatible femoral access training solution, offering anatomical accuracy, realistic tactile feedback, and cost-effective replaceable components. It empowers clinicians to build procedural expertise, ensuring safe and accurate femoral access management.

The Arthro Shoulder is a custom-designed, patient-specific 3D model that simulates musculoskeletal interventional procedures, specifically focusing on shoulder arthrograms. This advanced training tool provides healthcare professionals with a realistic, hands-on experience that closely mimics real-life procedures, from planning and working with image-guided projections to performing injections and gaining access to the joint space. The model features anatomically accurate structures, including soft tissues, bones, and joint cavities, offering a lifelike tactile experience. Its realistic tissue resistance allows users to feel the precise feedback experienced during needle insertion and joint penetration, enhancing procedural accuracy and confidence. Image-Guided Training Integration supports the use of real fluoroscopic or ultrasound guidance, enabling clinicians to develop essential skills such as needle placement, contrast injection, and joint visualization. This interactive training environment improves clinical decision-making and procedural proficiency. The use of real needle sets identical to those employed in arthrogram procedures further enhances training authenticity. Trainees gain valuable hands-on experience while familiarizing themselves with procedural techniques in a risk-free environment, reducing learning curves and enhancing patient safety in clinical practice. In summary, Arthro Shoulder bridges the gap between theoretical learning and clinical application by offering a comprehensive, lifelike simulation environment tailored to shoulder arthrogram procedures. Its patient-specific design, tactile realism, and integration with real procedural tools ensure a superior training experience for clinicians and trainees alike.

The BLICUT Spine Simulator is an advanced training platform designed to enhance clinical proficiency in minimally invasive spine procedures. Featuring replaceable 3D-printed bones, anatomically accurate structures, and a human-like casing, it provides a realistic environment for practicing essential skills such as puncture site identification, angiographic-guided insertion, and treatment planning. This comprehensive setup enables clinicians to experience lifelike tactile feedback while developing critical procedural accuracy. The simulator’s replaceable 3D bones replicate true bone density and anatomical landmarks, allowing repeated practice without wear and tear. Intervertebral discs are precisely modeled to simulate complex spinal procedures like vertebroplasty, kyphoplasty, and spinal fusion, offering real-time practice for device navigation, catheter insertion, and implant placement. Angiographic-guided insertion training enables clinicians to gain hands-on experience with fluoroscopy-guided procedures, improving their spatial awareness, accuracy, and decision-making during minimally invasive spine surgeries. The human-like casing ensures an authentic procedural environment, reinforcing hand-eye coordination, instrument handling, and anatomical recognition. The BLICUT Spine Simulator also supports treatment planning for spinal interventions, helping clinicians visualize and rehearse complex procedures before performing them on actual patients. This reduces procedural risks, enhances surgical confidence, and improves clinical outcomes through safe, hands-on learning. In summary, the BLICUT Spine Simulator bridges the gap between theoretical learning and real-life clinical practice by offering lifelike anatomical accuracy, replaceable components, and interactive procedure simulation tailored to minimally invasive spine procedures. Its unique design empowers clinicians to master essential skills, refine techniques, and improve patient safety in a realistic, controlled environment.

The Patient-Specific Artificial Respiratory Unit (PARU) is an advanced simulation platform designed for personalized respiratory management training. It replicates individual lung mechanics, enabling realistic procedural practice for conditions such as acute respiratory distress syndrome (ARDS), chronic obstructive pulmonary disease (COPD), and respiratory failure. PARU features a patient-specific respiratory system design, simulating lung compliance, resistance, and tidal volume, allowing clinicians to practice ventilation management using real ventilators. This supports hands-on training in intubation, mechanical ventilation adjustments, and respiratory therapy protocols with lifelike feedback. The system supports multi-level training, accommodating beginners learning respiratory basics and advanced practitioners performing complex procedures like extracorporeal membrane oxygenation (ECMO). Its modular design ensures seamless integration into clinical workshops, training labs, and classrooms. With real-time feedback on respiratory parameters, PARU enhances clinical decision-making by allowing users to adjust treatments and visualize outcomes. This interactive learning experience strengthens procedural skills while reducing real-life intervention risks. In summary, PARU offers a comprehensive, high-fidelity respiratory training solution, combining patient-specific simulation, advanced respiratory mechanics, and interactive feedback to improve clinical proficiency, enhance patient safety, and advance respiratory care education

Pulmonary Embolism Simulator (PEsim) is a specialized training platform designed for endovascular procedures related to pulmonary embolism management. It focuses on developing clinical expertise in treating lung-related vascular blockages through advanced catheter-based interventions. The simulator features a multimodality material design, enabling realistic simulations of various tissue responses, vessel elasticity, and dynamic blood flow. This allows clinicians to practice catheter navigation, clot retrieval, thrombolysis, and stent deployment with lifelike feedback, closely replicating real-life pulmonary embolism procedures. PEsim supports multi-level training for both beginners and advanced practitioners. New learners can master essential skills such as catheter handling and guidewire control, while experienced clinicians can rehearse complex interventions. Customizable training scenarios enable tailored learning experiences based on clinical needs, patient-specific anatomy, or specific institutional protocols. In summary, PEsim is a versatile, high-fidelity training tool designed for pulmonary embolism interventions, offering a unique combination of multimodality material technology, realistic anatomical modeling, and scalable training features. Its specialized design improves clinical proficiency, enhances patient safety, and supports advanced skill development for life-saving pulmonary embolism treatments.