31 research outputs found
A Simple, Effective Technique for Port-Site Closure After Laparoscopy
The authors describe a technique that allows suture of the abdominal fascia at sites using a transcurtaneous approach and standard surgical instruments
Use of contrast-enhanced intraoperative ultrasonography during liver surgery for colorectal cancer liver metastases - Its impact on operative outcome. Analysis of a prospective cohort study
Abstract Background Preliminary reports led to discordant conclusions concerning the use of contrast-enhanced intraoperative ultrasonography (CE-IOUS) during surgery for colorectal liver metastases (CLM). The aim of this study was to evaluate the impact of CE-IOUS in patients undergoing surgery for CLM using an advanced preoperative imaging work-up, and well-established reference standards. Materials and methods Forty-seven consecutive patients underwent liver resection using IOUS and CE-IOUS for CLM. All patients underwent preoperative computed tomography (CT) and magnetic resonance imaging (MRI) within 2 weeks prior to surgery. CE-IOUS was performed by injecting intravenously 4.8 ml of sulphur-hexafluoride microbubbles (SonoVue, Bracco, Italy). Reference standards were histology, and 6-month imaging follow-up. Results IOUS discovered 43 additional lesions in 20 patients. CE-IOUS found 10 additional lesions not seen at IOUS in four patients, and confirmed all the IOUS findings. Fourteen CLM in 10 patients appeared within 6 months after surgery. Sensitivity, specificity, positive predictive value, negative predictive value and accuracy were, respectively: 66%, 0%, 98%, 0% and 65% for CT + MRI; 88%, 100%, 100%, 8%, 88% for IOUS and 93%, 100%, 100%, 13%, 93% for IOUS + CE-IOUS. In nine patients CE-IOUS afforded better definition of tumour margins thus helping in resection guidance. Conclusions CE-IOUS improves IOUS findings both for detection and for resection guidance. The combination of IOUS and CE-IOUS should be considered routinely in patients operated for CLM
Prototype isochoric preservation device for large organs
This paper presents the design and prototype of a constant volume (isochoric) vessel that can be used for the preservation of large organs in a supercooled state. This prototype is a preliminary version of a more advanced design. The device consists of a cooling bath operated by a mechanical vapor compression refrigeration unit and an isochoric chamber made of stainless steel. The preservation of organs using supercooling technology in an isochoric chamber requires a continuous temperature and pressure monitoring. While the device was initially designed for pig liver experiments, its innovative design and preservation capabilities suggest potential applications for preserving other organs as well. The isochoric reactor may be used to accommodate a variety of organ types, opening the door for further research into its multi-organ preservation capabilities. All the design details are presented in this study with the purpose of encouraging researchers in the field to build their own devices, and by this to improve the design. We chose to design the device for isochoric supercooling as the method of preservation to avoid the ice formation
Temporomandibular joint dysfunction syndrome – a therapeu-tic approach
Background: Temporomandibular joint (TMJ) is responsible for vital functions like mas-tication, swallowing, and suction reflex and other relational functions, like talking and phonation. The etiology of temporomandibular joint disorders is multifactorial and in-volves subjective and objective clinical symptomatology. (2) Methods: The therapy is complex and encompasses a series of methods that interconnects various medical spe-cialties. Bad habits and parafunction are risk factors that may initiate and exacerbate a temporomandibular joint pathology. This prospective study aimed to show the positive impact of correct multidisciplinary therapy on the complex of TMJ disorders - pain and bad oral behaviors. The therapy methods used in this study were: medical, prosthetic, or-thodontic, surgical, and physiotherapy (PKT). (3) Results: The data obtained showed good results if the oral habits and TMJ disorders are treated correctly and simultaneous-ly. (4) Conclusions: All therapeutical approaches addressed in this study had beneficial effects on the recovery of the temporomandibular joint
Parenchyma-Sparing Liver Resection or Regenerative Liver Surgery: Which Way to Go?
Liver resection for malignant tumors should respect oncological margins while ensuring safety and improving the quality of life, therefore tumor staging, underlying liver disease and performance status should all be attentively assessed in the decision process. The concept of parenchyma-sparing liver surgery is nowadays used as an alternative to major hepatectomies to address deeply located lesions with intricate topography by means of complex multiplanar parenchyma-sparing liver resections, preferably under the guidance of intraoperative ultrasound. Regenerative liver surgery evolved as a liver growth induction method to increase resectability by stimulating the hypertrophy of the parenchyma intended to remain after resection (referred to as future liver remnant), achievable by portal vein embolization and liver venous deprivation as interventional approaches, and portal vein ligation and associating liver partition and portal vein ligation for staged hepatectomy as surgical techniques. Interestingly, although both strategies have the same conceptual origin, they eventually became caught in the never-ending parenchyma-sparing liver surgery vs. regenerative liver surgery debate. However, these strategies are both valid and must both be mastered and used to increase resectability. In our opinion, we consider parenchyma-sparing liver surgery along with techniques of complex liver resection and intraoperative ultrasound guidance the preferred strategy to treat liver tumors. In addition, liver volume-manipulating regenerative surgery should be employed when resectability needs to be extended beyond the possibilities of parenchyma-sparing liver surgery
An exploratory study on isochoric supercooling preservation of the pig liver
This study was motivated by the increasing interest in finding ways to preserve organs in a supercooled state for transplantation. Previous research with small volumes suggests that the isochoric (constant volume) thermodynamic state enhances the stability of supercooled solutions.The primary objective of this study was to investigate the feasibility of storing a large organ, such as the pig liver, in a metastable isochoric supercooled state for clinically relevant durations. To achieve this, we designed a new isochoric technology that employs a system consisting of two domains separated by an interior boundary that can transfer heat and pressure, but not mass. The liver is preserved in one of these domains in a solution with an intracellular composition, which is in osmotic equilibrium with the liver. Pressure is used to monitor the thermodynamic state of the isochoric chamber. In this feasibility study, two pig livers were preserved in the device in an isochoric supercooled state at -2°C. The experiments were terminated voluntarily, one after 24 h and the other after 48 h of supercooling preservation. Pressure measurements indicated that the livers did not freeze during the isochoric supercooling preservation. This is the first proof that organs as large as the pig liver can remain supercooled for extended periods of time in an isotonic solution in an isochoric system, despite an increased probability of ice nucleation with larger volumes. To serve as controls and to test the ability of pressure monitoring to detect freezing in the isochoric chamber, an experiment was designed in which two pig livers were frozen at -2°C for 24 h and the pressure monitored. Histological examination with H&E stains revealed that the supercooled liver maintained a normal appearance, even after 48 h of supercooling, while tissues in livers frozen to -2°C were severely disrupted by freezing after 24 h
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An exploratory study on isochoric supercooling preservation of the pig liver
This study was motivated by the increasing interest in finding ways to preserve organs in a supercooled state for transplantation. Previous research with small volumes suggests that the isochoric (constant volume) thermodynamic state enhances the stability of supercooled solutions. The primary objective of this study was to investigate the feasibility of storing a large organ, such as the pig liver, in a metastable isochoric supercooled state for clinically relevant durations. To achieve this, we designed a new isochoric technology that employs a system consisting of two domains separated by an interior boundary that can transfer heat and pressure, but not mass. The liver is preserved in one of these domains in a solution with an intracellular composition, which is in osmotic equilibrium with the liver. Pressure is used to monitor the thermodynamic state of the isochoric chamber. In this feasibility study, two pig livers were preserved in the device in an isochoric supercooled state at -2°C. The experiments were terminated voluntarily, one after 24 h and the other after 48 h of supercooling preservation. Pressure measurements indicated that the livers did not freeze during the isochoric supercooling preservation. This is the first proof that organs as large as the pig liver can remain supercooled for extended periods of time in an isotonic solution in an isochoric system, despite an increased probability of ice nucleation with larger volumes. To serve as controls and to test the ability of pressure monitoring to detect freezing in the isochoric chamber, an experiment was designed in which two pig livers were frozen at -2°C for 24 h and the pressure monitored. Histological examination with H&E stains revealed that the supercooled liver maintained a normal appearance, even after 48 h of supercooling, while tissues in livers frozen to -2°C were severely disrupted by freezing after 24 h