Our Tumor Micro Wave Ablation (MWA) systems deliver precise, predictable thermal coagulation for solid tumors. They combine advanced energy control, real‑time feedback, and imaging‑guided workflows. Built for interventional oncology teams, the platform supports percutaneous, laparoscopic, and open procedures. It offers consistent lesion formation and a streamlined setup for liver, lung, kidney, bone, and thyroid cases.
Microwave energy at medical frequencies produces rapid, uniform tissue heating that is less affected by impedance. This supports reliable margins and consistent zones. Clinicians can adjust power, time, and antenna position to match target volume under CT or ultrasound guidance. These controls support intent‑to‑treat approaches in early disease and symptom relief or debulking in metastatic settings.
Fast coagulation with larger, more spherical zones versus impedance‑limited modalities
Shorter procedure times and fewer repositionings in suitable cases
Stable performance near vessels to support margin control in perfused organs
Compatibility with imaging suites and sterile workflow accessories
Generators provide stable output, intuitive interfaces, and thermal safety interlocks to promote consistent results across operators and sites. Predictable heating profiles support planning and execution across varied tumor morphologies.
Systems are configured around medical microwave bands (e.g., 2.45 GHz where regionally applicable) with adjustable power levels. Settings can be matched to lesion size, proximity to critical structures, and antenna type. Power delivery curves are tuned for steady tissue heating with minimal overshoot.
Integrated timers, output stability indicators, and optional temperature or impedance feedback help predict diameters and depths. Real‑time visualization with CT or ultrasound confirms trajectory and completion of planned margins.
Cooled‑shaft antenna designs limit shaft heating and surface charring. Built‑in fault detection and an emergency stop support safe operation throughout the procedure.
Antenna options include single and multi‑antenna configurations to address diverse tumor shapes. Low‑profile shafts and multiple insertion lengths support precise targeting with minimal trauma and reliable trackability.
Single antennas simplify setup and reduce punctures. Multi‑antenna arrays enable larger, contiguous zones for bulky lesions and complex geometries.
Several outer diameters and lengths accommodate superficial, deep, and hard‑to‑reach targets while maintaining access and stability.
Echogenic markings and radiopaque features aid visualization under ultrasound and CT. These cues improve trajectory planning and final margin confirmation.
Kits include coaxial introducers, sterile drapes, connectors, and optional temperature probes to reduce setup time and support consistent sterile technique.
Coaxial introducers enhance pathway stability and can reduce parenchymal trauma. Temperature probes provide intra‑procedural feedback when required by protocol.
Pre‑validated sterile components support efficient room turnover and consistent cable management.
Consistent margins in perfused liver tissue support local control. Protocols can be adapted for solitary lesions or oligometastatic disease.
Precise energy delivery supports treatment of peripheral nodules under CT guidance, with attention to airway and pleura safety.
Heat‑controlled profiles allow nephron‑sparing approaches in select cases, with planning near collecting systems.
Targeted treatment of lytic lesions can reduce pain and stabilize local disease. It can complement cementoplasty when indicated.
Outpatient treatment of benign symptomatic nodules can reduce volume and symptoms with minimal scarring when used appropriately.
Devices are developed and manufactured under ISO 13485. CE and CFDA approvals are available where applicable. Blockchain‑based traceability tracks components from assembly to shipment. Production controls are designed to support reliable performance across installations.
End‑to‑end records capture batch genealogy, component sourcing, and QA checkpoints to support audits and post‑market surveillance. Documentation aligns with regional requirements to facilitate installation.
Quality programs across the interventional portfolio have achieved low observed defect rates. This supports confidence in generator stability, antenna performance, and accessories in clinical environments.
Design practices draw on environmental stress screening and high‑altitude deployment testing. These measures support consistent output and antenna performance in varied conditions.
Systems integrate with CT and ultrasound suites through compact footprints, intuitive controls, and clear cable routing. Quick‑start protocols and checklists help reduce training time and standardize room setup.
Antenna trajectory planning, skin marking, and incremental advancement under imaging minimize repositioning. These steps improve margin accuracy and reproducibility.
Training materials, case protocols, and reprocessing guidance for reusable accessories support consistent practice across teams and help reduce variability.
For deployments in Central and West Asia, routes via the Khorgos SEZ enable deliveries to Kazakhstan and Uzbekistan in approximately 72 hours. Documentation is available in multiple languages. Regulatory preparation can support EAEU standards and Turkey Ministry of Health requirements.
Multilingual IFUs, labeling translations, and dossier preparation can help streamline approvals and clinical adoption through regional distribution partners.
Private labeling is available with defined territories, co‑funded marketing, and emergency air shipments for critical replenishment to maintain service levels.
Design choices emphasize predictable zones and planned margins for intent‑to‑treat lesions. They also support palliative goals such as pain reduction and timely recovery when used in appropriate indications.
Stable power delivery and antenna geometry support planned diameters. Consistent zones help reduce the risk of residual disease at lesion edges.
Minimally invasive techniques can shorten hospital stays and support faster return to daily activities. Standardized protocols and streamlined room workflows contribute to efficiency.
Select antenna types, cable lengths, and interface languages to match procedural preferences, imaging constraints, and team workflows. Bundled kits are available for Turkic‑speaking markets to support regional adoption.
Choose echogenic or radiopaque features, flexible cable lengths for CT gantry clearance, and localized interfaces to improve usability and reduce setup variability.
Preconfigured sets align with common liver and lung protocols. Kits include introducers, drapes, and consumables tailored to local preferences.
Compared with impedance‑dependent modalities, this therapy can produce larger, more uniform zones and is less sensitive to tissue charring. These attributes support time‑efficient workflows and margin control in perfused organs.
Ready to configure a system for your team? Contact us to request a quote or schedule a technical consultation.
