67 research outputs found
Transoral robotic-assisted thyroidectomy with central neck dissection: preclinical cadaver feasibility study and proposed surgical technique
Recently, a transoral robotic-assisted technique to access the thyroid gland has been introduced. Despite the advantages this approach may have over other minimally invasive and robotic-assisted techniques, we found that the placement of the camera through the floor of mouth led to restricted freedom of movement. We describe our modification to this technique to overcome this problem. In a study using two fresh human cadavers, the camera port of the da Vinci robot was placed in the midline oral vestibule instead of the floor of the mouth. A transoral thyroidectomy and central neck dissection was successfully performed. Our modification led to an unfettered view of the central neck and allowed for a total thyroidectomy and central neck dissection. Our modification of transoral robotic-assisted thyroidectomy provides superior access to the central compartment of the neck over other robotic-assisted thyroidectomy techniques
Epidermal Growth Factor Receptor (EGFR) is overexpressed in anaplastic thyroid cancer and the EGFR inhibitor gefitinib inhibits the growth of anaplastic thyroid cancer
Purpose: No effective treatment options currently are available to patients with Anaplastic Thyroid Cancer (ATC), resulting in high mortality rates. Epidermal Growth Factor (EGF) has been shown to play a role in the pathogenesis of many types of cancer and its receptor (EGFR) provides an attractive target for molecular therapy. Experimental Design: The expression of EGFR was determined in ATC in vitro and in vivo and in human tissue arrays of ATC. We assessed the potential of the EGFR inhibitor gefitinib (“Iressa,” ZD1839) to inhibit EGFR activation in vitro and in vivo, inhibit ATC cellular proliferation, induce apoptosis and reduce the growth of ATC cells in vivo when administered alone and in combination with paclitaxel.
Results: EGFR was overexpressed in ATC cell lines in vitro and in vivo and in human ATC specimens. Activation of EGFR by EGF was blocked by the addition of gefitinib. In vitro studies showed that gefitinib greatly inhibited cellular proliferation and induced apoptosis in ATC cell lines and slowed tumor growth in a nude mouse model of thyroid carcinoma cells injected subcutaneously. Conclusions: ATC cells consistently overexpress EGFR, rendering this receptor a potential target for molecular therapy. Gefitinib effectively blocks activation of EGFR by EGF, inhibits ATC cellular proliferation and induces apoptosis in vitro. Our in vivo results show that gefitinib has significant antitumor activity against ATC in a subcutaneous nude mouse tumor model and therefore is a potential candidate for human clinical trials
Transoral resection of pharyngeal cancer: Summary of a National Cancer Institute Head and Neck Cancer Steering Committee Clinical Trials Planning Meeting, November 6–7, 2011, Arlington, Virginia
Recent advances now permit resection of many pharyngeal tumors through the open mouth, an approach that can greatly reduce the morbidity of surgical exposure. These transoral techniques are being rapidly adopted by the surgical community and hold considerable promise. On November 6–7, 2011, the National Cancer Institute sponsored a Clinical Trials Planning Meeting to address how to further investigate the use of transoral surgery, both in the good prognosis human papillomavirus (HPV)–initiated oropharyngeal cancers, and in those with HPV‐unrelated disease. The proceedings of this meeting are summarized. © 2012 Wiley Periodicals, Inc. Head Neck, 2012Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/94490/1/23136_ftp.pd
Videomics: bringing deep learning to diagnostic endoscopy
PURPOSE OF REVIEW: Machine learning (ML) algorithms have augmented human judgment in various fields of clinical medicine. However, little progress has been made in applying these tools to video-endoscopy. We reviewed the field of video-analysis (herein termed 'Videomics' for the first time) as applied to diagnostic endoscopy, assessing its preliminary findings, potential, as well as limitations, and consider future developments.RECENT FINDINGS: ML has been applied to diagnostic endoscopy with different aims: blind-spot detection, automatic quality control, lesion detection, classification, and characterization. The early experience in gastrointestinal endoscopy has recently been expanded to the upper aerodigestive tract, demonstrating promising results in both clinical fields. From top to bottom, multispectral imaging (such as Narrow Band Imaging) appeared to provide significant information drawn from endoscopic images.SUMMARY: Videomics is an emerging discipline that has the potential to significantly improve human detection and characterization of clinically significant lesions during endoscopy across medical and surgical disciplines. Research teams should focus on the standardization of data collection, identification of common targets, and optimal reporting. With such a collaborative stepwise approach, Videomics is likely to soon augment clinical endoscopy, significantly impacting cancer patient outcomes
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The dawn of robotic surgery in otolaryngology-head and neck surgery.
Transoral robotic surgery (TORS) utilizing the da Vinci robotic system has opened a new era for minimally-invasive surgery (MIS) in Otolaryngology-Head and Neck Surgery. Awareness of the historical steps in developing robotic surgery (RS) and understanding its current application within our field can help open our imaginations to future of the surgical robotics. We compiled a historical perspective on the evolution of surgical robotics, the road to the da Vinci surgical system, and conducted a review of TORS regarding clinical applications and limitations, prospective clinical trials and current status in Japan. We also provided commentary on the future of surgical robotics within our field. Surgical robotics grew out of the pursuit of telerobotics and the advances in robotics for non-medical applications. Today in our field, cancers and diseases of oropharynx and supraglottis are the most common indications for RS. It has proved capable of preserving the laryngopharyngeal function without compromising oncologic outcomes, and reducing the intensity of adjuvant therapy. TORS has become a standard modality for MIS, and will continue to evolve in the future. As robotic surgical systems evolve with improved capabilities in visual augmentation, spatial navigation, miniaturization, force-feedback and cost-effectiveness, we will see further advances in the current indications, and an expansion of indications. By promoting borderless international collaborations that put 'patients first', the bright future of surgical robotics will synergistically expand to the limits of our imaginations
Recommended from our members
The dawn of robotic surgery in otolaryngology-head and neck surgery.
Transoral robotic surgery (TORS) utilizing the da Vinci robotic system has opened a new era for minimally-invasive surgery (MIS) in Otolaryngology-Head and Neck Surgery. Awareness of the historical steps in developing robotic surgery (RS) and understanding its current application within our field can help open our imaginations to future of the surgical robotics. We compiled a historical perspective on the evolution of surgical robotics, the road to the da Vinci surgical system, and conducted a review of TORS regarding clinical applications and limitations, prospective clinical trials and current status in Japan. We also provided commentary on the future of surgical robotics within our field. Surgical robotics grew out of the pursuit of telerobotics and the advances in robotics for non-medical applications. Today in our field, cancers and diseases of oropharynx and supraglottis are the most common indications for RS. It has proved capable of preserving the laryngopharyngeal function without compromising oncologic outcomes, and reducing the intensity of adjuvant therapy. TORS has become a standard modality for MIS, and will continue to evolve in the future. As robotic surgical systems evolve with improved capabilities in visual augmentation, spatial navigation, miniaturization, force-feedback and cost-effectiveness, we will see further advances in the current indications, and an expansion of indications. By promoting borderless international collaborations that put 'patients first', the bright future of surgical robotics will synergistically expand to the limits of our imaginations
Recommended from our members
Next-Generation Robotic Head and Neck Surgery.
Following the inception of transoral robotic surgery (TORS) in 2005, the field of robotic head and neck surgery has undergone refinement and innovation. Optimizing patient outcome, preserving function, and limiting morbidity are the key drivers. The next leap forward is another generation of flexible robotic surgical systems. Several such systems are under clinical and preclinical evaluation. A new single-port (Sp) robotic surgical architecture is now available integrating three fully articulating instruments and a flexible three-dimensional high-definition camera delivered through a 25-mm cannula. Preclinical feasibility studies of the Sp in human cadaver and porcine models suggest improved application compared to existing platforms for oropharyngeal and nasopharyngeal resection. With 3-handed manipulation of tissue, traction and countertraction may be used to deliver a more precise surgical dissection of head and neck anatomy than is currently possible. The single-port design permits greater access and maneuverability for the bedside surgical assistant. An alternative currently available in clinical use includes the Flex® system using a robotic camera and manually controlled endoscopic instruments. The Cambridge Medical Robotics Versius system is undergoing preclinical evaluation for TORS and may offer a novel modular approach. All of these systems allow the head and neck surgeon to reach further beyond the upper aerodigestive tract with greater agility and precision, expanding the boundaries of minimal access head and neck surgery
Recommended from our members
Next-Generation Robotic Head and Neck Surgery.
Following the inception of transoral robotic surgery (TORS) in 2005, the field of robotic head and neck surgery has undergone refinement and innovation. Optimizing patient outcome, preserving function, and limiting morbidity are the key drivers. The next leap forward is another generation of flexible robotic surgical systems. Several such systems are under clinical and preclinical evaluation. A new single-port (Sp) robotic surgical architecture is now available integrating three fully articulating instruments and a flexible three-dimensional high-definition camera delivered through a 25-mm cannula. Preclinical feasibility studies of the Sp in human cadaver and porcine models suggest improved application compared to existing platforms for oropharyngeal and nasopharyngeal resection. With 3-handed manipulation of tissue, traction and countertraction may be used to deliver a more precise surgical dissection of head and neck anatomy than is currently possible. The single-port design permits greater access and maneuverability for the bedside surgical assistant. An alternative currently available in clinical use includes the Flex® system using a robotic camera and manually controlled endoscopic instruments. The Cambridge Medical Robotics Versius system is undergoing preclinical evaluation for TORS and may offer a novel modular approach. All of these systems allow the head and neck surgeon to reach further beyond the upper aerodigestive tract with greater agility and precision, expanding the boundaries of minimal access head and neck surgery
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