A cânula para rizotomia expansível Nimbus muda a maneira de como os procedimentos de Radiofrequência são realizados. Incorporando um design inovador, a Nimbus expansível proporciona uma ação consistentemente maior em um menor tempo de procedimento.
Por que Nimbus Expansível?
A cânula de Radiofrequência expansível Nimbus irradia a energia por meio pontas de trabalho que se projetam, resultando um tratamento esférico previsível e reproduzível.
Extensivos testes de segurança e confiabilidade demonstram que a densidade e calor da corrente se concentram próximas das pontas de trabalho.
Mapeamento in vivo de temperatura confirma que a Nimbus entrega um seguro e eficiente perfil térmico com temperaturas neuro destrutivas apenas nos tecidos alvo, preservando nervos espinhais adjacentes.
A cânula para rizotomia expansível Nimbus se adapta a um ampla variedade de tratamentos por ablação. Por entregar um resultado maior e previsível, o dispositivo Nimbus permite aos médicos trabalharem com maior eficiência.
Quando utilizada em procedimentos de abordagem bipolar socroilíaca, a Nimbus é capaz de produzir uma faixa de tratamento contínua de até 20mm, diminuindo o tempo do procedimento.
Diferentemente de técnicas convencionais, a Nimbus emprega uma simples abordagem "down-the-beam" lombar que permite o posicionamento perpendicular aos nervo alvo, realizando um eficiente procedimento de neurotomia. Resultando em menor tempo de procedimento, portanto, menos custo, além de menor tempo de exposição as raios X.
Abordagem da Nimbus
Abordagem perpendicular em direção ao "eye of the Scotty dog" facilita o tratamento do nervo em uma passada.
Registro Anvisa - 81420890008
NIM-050-10BB - Kit Cânula expansível para radiofrequência 50 mm, 17 Gauge e ponta reta
NIM-100-10BB - Kit Cânula expansível para radiofrequência 100 mm, 17 Gauge e ponta reta
NIM-150-10BB - Kit Cânula expansível para radiofrequência 150 mm, 17 Gauge e ponta reta
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The Nimbus radiofrequency multi-tined expandable electrode aims to improve radiofrequency neurotomy outcomes. Radiofrequency thermal neurotomy (RTN) is recognized as a highly effective intervention for patients suffering from intractable pain. RTN relieves pain by inducing thermal coagulation of a segment of the afferent nociceptive pathway, effectively interrupting transmission of sensory information from a pain generator to the central nervous system and brain.
There is widespread support for the use of RTN in the treatment of a wide range of spinal and non-spinal pain syndromes in the medical literature. Indications range from sacroiliac (SIJ) zygapophyseal facet joint pain and trigeminal neuralgia to pain associated with metastatic disease.
RTN is the neuroablative procedure of choice because:
To achieve optimal pain relief, the pain specialist performing RTN must produce the ideal lesion, parallel and adjacent to the target neural pathway. The efficacy of pain relief following RTN hinges on complete destruction of the afferent nociceptive pathway, and the duration of relief is considered proportional to the length of nerve ablated.
Experience suggests that a 10mm interruption of the pain-transmitting pathways is desired. Although various techniques have been developed for delivering the ideal lesion to the target neural pathway, it is often technically challenging to produce an RF lesion of optimal volume and orientation. This is because the lesion resulting from the RF technique not only must be large enough to encompass anatomic variation in the afferent nociceptive pathway but also oriented to optimize the length of the neural pathway coagulated.
Following proof-of-concept testing the initial aim was to estimate the size and reproducibility of the lesion shape based on visible coagulation of raw tissue Electrodes were placed in surface contact with tissue samples and inserted into other tissue samples after all were equilibrated in a 37°C water bath. More than 100 lesions were created in muscle tissue and organ tissue.
Heating cycles intended to closely reproduce clinical practice were performed using commonly available RF generators (range 60 seconds -240 seconds / 65°-90°C) and lesion size was measured.
There was no evidence of anomalous heating such as boiling, charring, or cavitation. Data compiled for all heating cycles revealed minimal variation in lesion size beyond a 75°C/80 second threshold. The lesion produced was highly reproducible and consistently directional with an average volume of 467 +/- 71 mm3/ lesion.The lesions assumed an elongate spheroid shape and were offset from the central axis toward tines. A graphic showing the size and orientation of the lesion was created.
Visible coagulation and thermal imaging studies documented the formation of consistent lesion geometry with a predictable thermal signature. In-vivo thermal mapping method was performed by placing the Nimbus large-field directional RF electrode at the base of the superior articular process (SAP) of L4 and L5 to target the course of the medial branch. A "down-the-beam" or "gun barrel" technique was used and consistently produced an optimally shaped 10 mm lesion, indicating that this technique will likely result in a technically superior lumbar medial branch neurotomy.
The in-vivo temperature mapping confirmed a safe and technically effective thermal profile consistent with the ex-vivo results. Importantly, neurodestructive temperatures were achieved in the target tissue without undesirable heating of collateral structures or adjacent spinal nerves. In addition, thermal bias toward the direction of the tines the directional nature of the lesion was reconfirmed.
The Nimbus, a novel RF electrode, was developed to produce a larger volume, optimally shaped lesion approximately 8-10 mm in diameter, to enable pain management specialists to more predictably target ablation, including anatomic variation, using technically simple, easily mastered electrode placement techniques. The Nimbus RF electrode increases the functional electrode surface area, spreads electrical current density and increases the volume of tissue heated resulting in a larger ablation zone.
The Nimbus RF electrode design specifications include:
The device uses expandable metal tines to diffuse the RF current density in the target tissue thereby increasing the functional electrode surface area. Increased functional electrode surface area proportionately increases the volume of tissue heated producing a larger ablation zone compared to results from a standard monopolar cannula. The tines are deployed and retracted with a simple helical rotation of the hub.
When deployed, the tines function as antennae, expanding and concentrating the current density and predictably enlarging the lesion.
Because they are unilaterally offset from the axis of the central cannula they create a directional lesion that enables selective targeting of the nociceptive pathway with decreased collateral tissue damage.
Moreover, the distance the lesion propagates from any active electrode surface is limited and predictable. This attribute of the lesion is vitally important because it allows meaningful sensory and motor stimulation. To further ensure patient safety, the internal design of the device couples the tines and the central cannula with the inserted thermocouple permitting real-time monitoring of critical temperatures in the ablation zone. A central lumen allows insertion of a standard thermocouple and/ or anesthetic or medication injection prior to lesion.
The Nimbus multi-tined, expandable RF electrode was developed using dual deployable tines for electrical field diffusion and increased functional electrode surface area. The lesion it produces is geometrically predictable and thermally stable.
The innovative design of the electrode and the geometry and stability of the tissue lesion it produces are uniquely suited to safe, technically efficient and effective interruption of nociceptive pathways. Based on detailed anatomical research into afferent pain pathways, the innovative electrode design enables practitioners to consistently achieve appropriate tissue ablation with fewer heat cycles and less global tissue trauma compared to the current technology.
The advent of a technologically advanced RF electrode that creates directional and optimally-sized lesions for neurotomy holds great promise for interventional pain management. The design simplifies technique and readily adapts to various RF ablation targets including the cervical, thoracic and lumbar zygapophyseal joints, the sacroiliac joint, and other targets along the spinal sympathetic chain