论文信息 - Assessment of penetrating thermal tissue damage/spread associated with PhotonBlade™, Valleylab™ Pencil, Valleylab™ EDGE™ Coated Pencil, PlasmaBlade® 3.0S and PlasmaBlade® 4.0 for intraoperative tissue dissection using the fresh extirpated porcine muscle model

Assessment of penetrating thermal tissue damage/spread associated with PhotonBlade™, Valleylab™ Pencil, Valleylab™ EDGE™ Coated Pencil, PlasmaBlade® 3.0S and PlasmaBlade® 4.0 for intraoperative tissue dissection using the fresh extirpated porcine muscle model

Penetrating thermal tissue damage/spread is an important aspect of many electrosurgical devices and correlates with effective tissue cutting, hemostasis, preservation of adjacent critical structures and tissue healing. This study compared the thermal damage/spread associated with the PhotonBlade, Valleylab Pencil, Valleylab EDGE Coated Pencil, PlasmaBlade 3.0S and PlasmaBlade 4.0, when performing a single pass dynamic tissue cut in fresh extirpated porcine longissimus muscle. These devices were used in a fashion that emulated their use in the clinical setting. Each device’s thermal damage/spread, at Minimum, Median and Maximum power input settings, was assessed with nitroblue tetrazolium viability staining in the WVU Pathology Laboratory for Translational Medicine. The thermal damage/spread associated with the PhotonBlade was compared with the other devices tested based on the individual treatment results (n=179 cuts combined). In summary, the PhotonBlade overall demonstrated the least penetrating thermal tissue damage/spread, followed by the PlasmaBlade 4.0, then Valleylab Pencil and PlasmaBlade 3.0S and then Valleylab EDGE Coated Pencil in order of increasing thermal damage/spread depths.

[1] James E. Coad,et al. Evolution of pathology techniques for evaluating energy-based tissue effects , 2013, Photonics West - Biomedical Optics.

[2] James E. Coad,et al. Comparison of four energy-based vascular sealing and cutting instruments: A porcine model , 2008, Surgical Endoscopy.

[3] Jeffrey A. Vos,et al. Hyperthermic tissue sealing devices: a proposed histopathologic protocol for standardizing the evaluation of thermally sealed vessels , 2011, BiOS.

[4] James E. Coad,et al. Practical pathology for thermal tissue applications , 2015, Photonics West - Biomedical Optics.

[5] James E. Coad,et al. Histologic differences between cryothermic and hyperthermic therapies , 2003, SPIE BiOS.

[6] James E. Coad. Thermal fixation: a central outcome of hyperthermic therapies (Invited Paper) , 2005, SPIE BiOS.

[7] James E. Coad,et al. Tissue sealing device associated thermal spread: a comparison of histologic methods for detecting adventitial collagen denaturation , 2013, Photonics West - Biomedical Optics.

[8] James E. Coad. Practical pathology perspectives for minimally invasive hyperthermic medical devices , 2011, BiOS.

[9] James E. Coad,et al. Healing responses following cryothermic and hyperthermic tissue ablation , 2009, BiOS.

[10] James E. Coad,et al. Developing clinically successful biomedical devices by understanding the pathophysiology of the target tissue: insights from over 25 years at the microscope , 2007, SPIE BiOS.