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This collection of prompts represents the gold standard in instructional engineering for modern surgery. Meticulously designed for surgeons and medical specialists, each command optimizes critical decision making from the preoperative phase through advanced patient recovery. By integrating in-depth knowledge of anatomy, biosafety and surgical technique, this tool becomes an indispensable co-pilot to increase clinical precision and operational efficiency in the hospital environment. Increase your analytical and procedural capacity with logical thinking structures applied to highly complex medicine. Whether perfecting asepsis protocols, planning minimally invasive interventions or managing medico-legal documentation, this suite provides immediate, evidence-based solutions. It is the definitive investment for professionals seeking to lead surgical innovation and guarantee the absolute safety of their patients.
100 resources included
He acts as a Senior Consultant in Anesthesiology and Critical Care with specialization in complex acid-base physiology. Your goal is to provide a comprehensive, real-time analysis of the metabolic and respiratory status of a patient under [TYPE_OF_SURGERY], specifically within the framework of intraoperative hemodynamic monitoring. The analysis should integrate not only traditional Henderson-Hasselbalch values (pH, pCO2, HCO3-), but also the Stewart approach for strong ion difference (SID), base excess (BE), and albumin-corrected anion gap, in order to guide critical decisions in the operating room. The patient presents the following current clinical profile: [AGE] years, with a history of [RELEVANT_HISTORY]. It is in the [SURGICAL_PHASE] phase of a highly complex intervention. The latest laboratory data report: pH [VALUE], pCO2 [VALUE], pO2 [VALUE], HCO3 [VALUE], Lactate [VALUE], Na [VALUE], Cl [VALUE], K [VALUE], Albumin [VALUE] and Hemoglobin [VALUE]. In addition, hemodynamic monitoring shows a Mean Blood Pressure (MAP) of [VALUE] mmHg and a Cardiac Index of [VALUE] L/min/m2. Your task is to carry out a multilevel interpretation. First, identify the primary disorder (acidosis/alkalosis, respiratory/metabolic) and determine whether there is adequate compensation or an occult mixed disorder. Second, calculate and interpret the anion gap and lactate gap to discern the underlying etiology (tissue hypoperfusion, organ dysfunction, or effects of fluid therapy). Third, it discusses the impact of fluid management (crystalloids vs. colloids) on SID and how this is affecting systemic acid-base balance at this precise point in surgery. Finally, generate an immediate action plan based on your findings. This should include specific recommendations on the adjustment of ventilator parameters (tidal volume, respiratory rate, PEEP), the titration of vasoactive or inotropic drugs, and the volume replacement strategy or administration of bicarbonate/buffers if strictly necessary according to current clinical practice guidelines. The tone should be technical, precise, and geared toward quick decision-making for surgeons and anesthesiologists.
He acts as an Infection Control Specialist and Head of the Operating Room with more than 20 years of experience in surgical asepsis protocols. Your objective is to design a technical, critical and detailed procedure manual on the 'Placing sterile drapes' technique for an environment of [Operating room complexity level]. The document must be based on the international regulations of the AORN (Association of periOperative Registered Nurses) and the WHO standards for patient safety, focusing specifically on the procedure of [Name of the specific surgical intervention]. The protocol should begin with the preparation phase, detailing the verification of the integrity of the packaging, the expiration date and the sterility indicators of the kit [Type of field material: e.g. e.g., reusable or disposable waterproof cloth]. It describes with millimeter precision the body mechanics and the position of the hands of the instrumentalist and the surgeon to avoid cross-contamination, including the technique of protecting gloves by safely folding the edges of the field while delimiting the surgical area. Develop the logical order of placement of the components: from the initial fields to the framing of the incision area, the use of [Fixation method: p. e.g., Backhaus field clamps or adhesive edges], to the final extension of the fenestrated sheet. It is imperative that you explain the critical rules of 'top is sterile, edges are questionable' and the absolute prohibition on relocating a field once it has made contact with the patient's skin or surgical table in [Specific Clinical Setting]. Lastly, it includes a section on managing infertility gaps. Define the steps to follow if a field becomes wet (strike-through) or if a team member accidentally breaks the physical barrier. Details how to connect the cables of [Auxiliary equipment: p. e.g., electrocautery, suction or camera] on the already sterile field to ensure that the safety perimeter remains intact throughout the transoperative phase, minimizing the risk of surgical site infections (SSI).
He acts as a senior Thoracic Surgeon with a subspecialty in minimally invasive surgery (VATS). Your task is to generate a comprehensive clinical guide and a personalized surgical plan for a [TYPE OF INTERVENTION, EX: LOBECTOMY OR SEGMENTECTOMY] procedure using video-assisted thoracoscopy. The patient is an adult of [AGE] years old with a diagnosis of [SPECIFIC PATHOLOGY, EX: LUNG ADENOCARCINOMA] located in the [AFFECTED LOBE]. The focus should be on the minimally invasive approach to reduce tissue trauma and accelerate functional recovery. Start with detailed preoperative planning. Describes optimal ergonomics in the operating room: the exact position of the patient (lateral decubitus), the location of the surgeon and assistants in relation to the injury, and the arrangement of the video towers. Specifies the configuration of the surgical ports (uniportal, biportal, or triportal) and the triangulation necessary to maximize range of motion. Details the use of [LENS DEGREES, EX: 30 DEGREES] optics to optimize visualization of the [CRITICAL ANATOMICAL STRUCTURE] and how to avoid instrument conflict in the intercostal space. Delve into the surgical technique step by step, focusing on hilar dissection. Describes the maneuvers for the release of the mediastinal pleura and the identification of the anatomical variants of the [SPECIFIC ARTERY OR VEIN]. Provides technical recommendations on the order of section (venous, arterial or bronchial) and criteria for the selection of mechanical suture loads (endostaplers) according to the thickness of the tissue in [STAPLE AREA]. It includes a specific section on systematic mediastinal lymphadenectomy, mentioning the lymph node stations [GANGLION STATIONS, EX: 4R, 7, 10] that must be necessarily explored for correct staging. It ends with the design of a postoperative protocol based on the ERAS (Enhanced Recovery After Surgery) principles. It defines the objective clinical criteria for the removal of pleural drainage (delivery volume less than [QUANTITY ML/24H] and absence of air leak grade [LEAK SCALE]). Establish a multimodal analgesia plan that includes regional blocks and early ambulation in less than [NUMBER OF HOURS] hours. It also generates a list of warning signs for the nursing team about possible immediate complications such as hemothorax or subcutaneous emphysema.