Small Animal Surgical Emergencies. Группа авторов

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Название Small Animal Surgical Emergencies
Автор произведения Группа авторов
Жанр Биология
Серия
Издательство Биология
Год выпуска 0
isbn 9781119658627



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perioperative first‐ and second‐generation cephalosporins likely do not provide adequate antimicrobial coverage and should not be used in favor of more broad‐spectrum medications. In the absence of confirmatory culture and sensitivity testing, broad‐spectrum therapy should be used until a diagnostic culture result is obtained and antimicrobial therapy can be de‐escalated. Intravenous administration is preferred in all cardiovascularly unstable and critically ill patients as oral, intramuscular, and subcutaneous absorption may not be predictable. Antibiotics that can be considered for first‐line broad‐spectrum therapy include ampicillin and clavulanate (Unasyn®, Pfizer, 22–30 mg/kg IV every 8 hours); ampicillin (18–22 mg/kg IV every 8 hours) combined with enrofloxacin (10–15 mg/kg IV every 24 hours), cefoxitin (30 mg/kg IV every 6 hours), and clindamycin (10 mg/kg IV every 12 hours) combined with cefotaxime (40–50 mg/kg IV every 6 hours), or ceftazidime (30–50 mg/kg IV every 6–8 hours with dosing at the lower end of the range for cats and higher end for dogs).

      Metabolic Shock

      Metabolic shock is defined as dysfunction of cellular metabolism, which generally occurs in the face of adequate perfusion and oxygenation. Examples include severe pH derangements, hypoglycemia, adrenal insufficiency, and certain toxicities such as cyanide. The clinical signs seen with metabolic shock closely resemble those in hypovolemic shock and are related to the underlying etiology. Mental depression is the most universally recognized sign of metabolic shock. The same diagnostics used for patients in hypovolemic shock are indicated for the patient in metabolic shock. Treatment may include correction of acid–base derangements with IV fluids and/or bicarbonate, dextrose supplementation, and steroid administration, if adrenal dysfunction is demonstrated or highly suspected [70–74].

      Source: Adapted from Simmons and Wohl [65]. CRI = constant rate infusion.

CRI dose Effect Additional information
Dopamine 1–4 μg/kg/minute Vasodilation (renal) Mixed data for renal effects
5–10 μg/kg/minute Increased contractility, some vasoconstriction
10–20 μg/kg/minute Vasoconstriction, variable contractility effects
Dobutamine 2–20 μg/kg/minute (dogs) Increased contractility, little vasoconstriction
2–5 μg/kg/minute (cats) Increased contractility, little vasoconstriction Can cause seizures in cats
Norepinephrine 0.05–2 μg/kg/minute Potent vasoconstriction
Vasopressin 0.5–2 mU/kg/minute (dogs) Potent vasoconstriction (even in acidosis) Limited clinical experience in dogs, no dose established for cats

      This formula incorporates fluid deficit (dehydration), ongoing losses, and maintenance fluid needs. It should be used only after intravascular volume deficits (hypovolemic shock) have been corrected.

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      Rate of deficit correction is generally over 12–36 hours depending on patient stability, chronicity of dehydration, and tolerance for IV fluids.

      Maintenance needs are generally 2–3 ml/kg/hour for dogs and 1–2 ml/kg/hour for cats.

      Example Fluid Prescription Calculation

      25 kg mixed breed dog (lean body condition)

      Estimated to be 8% dehydrated based on physical exam findings (tacky mucous membranes, prolonged skin tent, slightly sunken globes, hyperviscous saliva in the corner of the mouth).

      No conditions that would make the patient fluid intolerant; plan to correct over 24 hours.

      The dog is losing approximately 60 ml in vomit every hour, no excessive gastrointestinal or urinary losses.

       Deficit = 0.08 × 25

       Deficit = 2000 ml

       Rate of deficit correction = 2000/24 = 83 ml/hour

       Fluid prescription (per hour) = 83 ml (deficit) + 60 ml (losses) + 50 ml (maintenance)

       Fluid prescription = 193 ml/hour