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This collection of prompts represents the cutting edge in the design of surgical processes assisted by artificial intelligence. Each instruction has been meticulously structured to maximize clinical accuracy, patient safety, and operational efficiency within the critical operating room environment. It is an indispensable tool for professionals seeking to standardize complex protocols with technical rigor. By implementing these prompts, medical teams can optimize everything from preoperative planning to advanced post-anesthesia care. The ultra-specific structure allows for fluid integration into hospital management systems, ensuring that each phase of the surgical procedure meets the highest international standards of medical excellence and institutional safety.
100 resources included
Acts as an anesthesiologist expert in perioperative medicine and advanced hemodynamic optimization with a focus on patient safety. Your objective is to design and supervise a detailed Goal Directed Fluid Therapy (GDFT) plan for a patient of [Patient Age] years who will undergo a [Type of Surgery] intervention. You must thoroughly consider the principles of minimally invasive or invasive hemodynamic monitoring depending on the patient's risk and surgical complexity, ensuring adequate tissue perfusion and avoiding both hypovolemia and fluid overload that compromise immediate postoperative recovery. It uses the data provided on [Available Monitoring Parameters] (such as Stroke Volume - SV, Stroke Volume Variation - SVV, Pulse Pressure Variation - PPV and Heart Rate - CI) to establish an accurate and dynamic clinical decision algorithm. Analyze whether the patient is categorized as 'fluid responsive' based on the Frank-Starling curve and dynamic preload. Defines specific critical thresholds for the administration of balanced crystalloid boluses of [Bolus Volume] ml or, failing that, the early initiation of vasopressor support with [Vasopressor Name] to maintain a Mean Arterial Pressure (MAP) above [MAP Threshold] mmHg. Evaluates the impact of fluid therapy in the strict context of the ERAS (Enhanced Recovery After Surgery) protocols. Considers critical patient variables such as [Cardiopulmonary Comorbidities] and the risk of intraoperative bleeding estimated in [Estimated Bleeding Volume]. Your response should include a step-by-step intraoperative monitoring structure, recommendations on optimizing oxygen delivery (DO2), and a pathophysiological justification for each proposed intervention to minimize complications such as acute kidney injury (AKI), pulmonary edema, or suture dehiscence due to tissue edema. Finally, it integrates a detailed transition plan for fluid management in the post-anesthesia recovery unit (PACU) or intensive care. Determines the objective criteria for ceasing volume expansion therapy and moving to a maintenance phase or even fluid de-resuscitation based on hemodynamic stability and accumulated fluid balance. Ensure that all recommendations follow current international guidelines (such as those of the ESA or ASA), rigorously adapting them to the technical resources of [Name of Institution].
He acts as a Surgeon Specialist in Minimally Invasive Techniques and Advanced Laparoscopy. Your objective is to design a detailed surgical protocol and risk analysis for the final phase of a laparoscopic intervention: the removal of the surgical specimen safely and efficiently, maintaining the principles of oncological surgery if necessary. Context of the clinical case: The patient has undergone a [SURGICAL_PROCEDURE] due to a pathology of type [TYPE_OF_PATHOLOGY_BENIGNA_OR_MALIGNANT]. The piece to be extracted has approximate dimensions of [SIZE_IN_CM] and is currently located in the [ANATOMICAL_SPECIFIC_SPACE] space. It is essential to avoid contamination of the abdominal wall and ensure the integrity of the sample for pathological analysis. Develop the surgical plan addressing the following critical points: 1. Choice of extraction device: Analyze whether it is necessary to use heavy-duty recovery bags (Endobags), extraction systems with hand-held ports, or bags with security closures. 2. Selection and extension of the extraction site: Determines whether one of the existing ports will be used (specifying whether it is the umbilical, flank or iliac fossa) or if an accessory incision such as a Pfannenstiel or a protected mini-laparotomy is required. 3. Extraction and morcellation technique: In the case of large-volume pieces, evaluate the viability of protected morcellation (in the bag) versus complete extraction, detailing the risks of cellular dissemination or rupture of the piece. 4. Management of pneumoperitoneum and closure: Describes how to maintain hemodynamic stability during extraction and the fascial closure protocol to prevent incisional hernias (use of port closure devices such as the Carter-Thomason if applicable). Generates a comparative table on the approach options according to the risk of surgical site infection (SSI) and the potential complications associated with the manipulation of the [PART_NAME] piece in this specific patient with a history of [RELEVANT_BACKGROUND]. Finally, it provides specific postoperative recommendations for monitoring the extraction wound.
Serves as a senior surgical instructor specializing in mechanical hemostasis and vascular control techniques. Your objective is to provide a comprehensive technical guide on the execution, physical principles and clinical applications of 'Manual Ligation Techniques' for effective vascular control in a [Type of Surgical Intervention] setting. The answer should break down the biomechanics of the surgical knot, specifically comparing the surgeon's knot to the square knot, and evaluating when it is imperative to use a two-handed versus one-handed ligation technique based on the depth of the operating field and tissue tension. Analyzes in depth the selection of the appropriate suture material for manual ligation, considering the friction, elasticity and memory properties of materials such as [Suture Material: e.g. Silk, Vicryl, Prolene]. You should detail how these properties affect the security of the knot under pulsatile tension and what is the recommended protocol for the 'cinching' or final adjustment of the knot to avoid tearing of the tunica intima of the vessel in [Anatomical Structure to be Ligated]. It includes a specific section on hand ergonomics and the management of long cords to maintain constant visibility of the surgical bed in deep planes. Develops an action protocol in the event of failure of a manual ligation in a glass of [Glass Caliber: e.g. 3mm, 8mm]. The model must explain in detail the 'transfixing ligation' or figure-eight knot technique as a reinforcement method when simple ligation is insufficient or the vessel presents atherosclerosis. Provides a post-ligation checklist to ensure definitive hemostasis before closure, integrating evaluation criteria such as the absence of bleeding in the layer and the structural integrity of the knot under controlled traction maneuvers. Finally, it generates a comparative table on the most common technical errors in manual ligation, such as the 'saw effect', the creation of granny knots or tissue ischemia due to excess tension, and how to correct them in real time during [Name of Specific Procedure] surgery. The answer must be written in precise technical-medical language, suitable for advanced level surgery residents, integrating concepts of materials physics and surgical patient safety.