Cancer Anorexia–Cachexia Syndrome

Cancer anorexia–cachexia syndrome (CACS) represents the most common paraneoplastic disorder in both human and veterinary patients. The incidence among veterinary patients is yet to be determined by appropriate clinical studies. However, the incidence has been estimated at only 4% [10], which may be significantly lower than the real figure [9]. Oncologic patients frequently show weight loss and metabolic alterations associated with both adequate nutritional intake (cancer cachexia) and/or poor nutritional intake (cancer anorexia). This PNS results in alterations in carbohydrate, lipid, and protein metabolism that, if left untreated, decrease the patients’ quality of life, their survival time, and sometimes their chances of being suitable candidates for a more appropriate therapy [11]. Clinically, CACS is characterized by nausea, anorexia, and weight loss that ultimately leads to severe wasting due to massive body fat depletion and a dramatic decrease in muscle protein mass (Figure 17.1) [12].

Patients may also have alterations in food perception (i.e., smell and taste), which decreases the palatability of the food they are offered [12]. The metabolic disorders associated with the CACS may occur even before weight loss is first detected and they may often persist after the patient is successfully treated for the neoplastic disorder, making weight gain challenging. The underlying CACS pathophysiologic mechanism is mediated by the production and release of serotonin and cytokines that lead to alterations in the resting energy expenditure as well as in physiologic protein, fat, and carbohydrate metabolism (Table 17.2) [12].

Oncologic patients that suffer from CACS require aggressive nutritional support to limit the adverse effects of CACS and to enhance immune system function as well as the efficacy and tolerance of different therapeutic interventions (i.e., diets rich in omega‐3 fatty acids) [13]. Nasoesophageal, esophagostomy, or gastrostomy tubes are also recommended in those patients that are persistently anorexic.

As a result of the aforementioned changes associated with PNS, a low fat‐to‐body mass ratio and a low muscle‐to‐body mass ratio are commonly found in these patients. Due to the decreased availability of drug protein binding, higher circulating levels of free‐fraction or active drugs (e.g., barbiturates) administered in the perianesthetic period may be present. To avoid overdose and prolonged and/or rough anesthetic recoveries, careful pharmacological choices and dosing regimens need to be applied. Additionally, due to their very low fat‐to‐body mass ratio, these patients may be more prone to hypothermia during the perianesthetic period. Active efforts to decrease as much as possible heat loss is warranted (i.e., insulation from cold surfaces, careful wrapping, use of heat and moisture exchange filters, warm water blankets, etc.).

Fever

Fever as a PNS is associated with a wide variety of neoplastic disorders and, although it is very common in human patients, its incidence in veterinary medicine is unknown [14]. The pathogenesis of paraneoplastic fever is mostly due to the production and release of pyrogenic cytokines by the host immune system and/or tumor itself [15]. A thorough preanesthetic evaluation is warranted to rule out the presence of an infectious process prior to formulating an anesthetic plan. Severe elevations in body temperature are associated with an increased metabolic state and degree of oxygen consumption that may even exceed oxygen delivery to tissues. This situation may eventually lead to the development of a series of multiorgan dysfunctions (i.e., acute renal failure, myocardial arrhythmias, and disseminated intravascular coagulation [DIC]). In addition, hyperthermia is related to an increase in inhalant minimum alveolar concentrations (MAC) [20]. Anesthetic maintenance with inhalant agents may necessitate higher end‐tidal inhalant concentrations. If infection is ruled out and the fever is severe or life‐threatening, nonsteroidal anti‐inflammatory drugs (NSAIDs) should be used to inhibit the chemical mediators responsible for fever production while still allowing for normal thermoregulation [16]. Although NSAIDs are relatively safe, they should be avoided in patients with renal disease, gastrointestinal ulceration, or bleeding disorders. Dipyrone is also an injectable NSAID with antipyretic properties via cyclooxygenase (COX‐3) inhibition [17, 18] not associated with the usual NSAID contraindications. At this time, dipyrone is not used widely in small animals in the United States; however, it was recently approved by the Food and Drug Administration (FDA) for use in horses. Dipyrone may induce blood dyscrasias in human patients; however, this has not been shown in animals [19].

Anemia

Tumors and their metastases can alter hematopoietic cell lines after infiltration of the bone marrow, and anemia is one of the most common PNS in veterinary patients with an incidence from 30% to 69% [21]. The most common causes are anemia of chronic disease (ACD), immune‐mediated hemolytic anemia (IMHA) usually associated with hematopoietic tumors, blood loss anemia associated with paraneoplastic gastroduodenal ulceration, and microangiopathic hemolytic anemia (MAHA) most associated with microvascular tumors or any type of tumor that could lead to the development of DIC.

In the case of acute or severe anemia, stabilization is desirable before general anesthesia is considered. In ACD, blood loss anemia, and MAHA, only the tumor removal can improve the condition; however, when IMHA is present, treatment with corticosteroids with or without immunosuppressive agents such as azathioprine or cyclophosphamide may significantly improve the condition before general anesthesia is undertaken [22–26]. In addition, supportive treatment with whole blood or packed red blood cell transfusion may be necessary where hypoperfusion and hypoxia are a concern. Administration of hemoglobin‐based oxygen‐carrying solutions (HBOCs) may be also considered if available. In addition, measures should be taken to optimize oxygen delivery to the tissues in the anesthetized patient such as preoxygenation before induction of general anesthesia, maintaining the inspired oxygen level (FIO₂) of 1.0 throughout the procedure, and striving for optimal perfusion at all times.

Erythrocytosis

Polycythemia or erythrocytosis is uncommon in veterinary oncologic patients, and it is mainly associated with renal tumors in which an increased level of erythropoietin may be present [27, 28]. Patients present with clinical signs of tissue hypoxia, polyuria, bleeding, or thrombosis that result from hyperviscosity of the blood as well as decreased perfusion of small vessels. Stabilization via phlebotomy can be a useful temporary adjunct therapy. Serial phlebotomies of 10–20 ml kg⁻¹ of blood may be carried out until clinical symptoms have resolved or the target hematocrit is reached (usually below 50% for cats and below 55% in dogs). However, repeated phlebotomies may result in thrombotic complications or iron deficits, as well as the need for concomitant aggressive fluid therapy and potential administration of plasma [29]. Consequently, if phlebotomies are required more frequently than every 6–8 weeks, myelosuppressive therapy is advised, and hydroxyurea may be used [30]. Definitive treatment of PNS erythrocytosis implies the removal of the erythropoietin‐producing tumor.

Thrombocytopenia

The incidence of thrombocytopenia in veterinary cancer patients is high, occurring in up to 58% of dogs and 20% of cats [31–33]. Clinical signs are usually not evident until the platelet count decreases below 30 000 μl⁻¹. Definitive treatment requires removal of the stimulating tumor.

Anesthetic management of PNS thrombocytopenia includes a thorough physical exam and hematological evaluation; platelet‐rich plasma or plasma transfusions may be indicated. Fresh frozen plasma (FFP) transfusions of 10 and 15–18 ml kg⁻¹ have been reported with favorable results [34, 35]. Transfusion reactions are rare and range from mild signs (i.e., pruritus, facial swelling, and rash) to more severe (i.e., anaphylactic reactions or even death). Patients being transfused should always be closely monitored. Corticosteroids (>2 mg kg⁻¹ PO daily) and immunosuppressive drugs such as azathioprine (2 mg kg⁻¹ PO daily then 0.5–1 mg kg⁻¹ every other day) may be used in the case of immune‐mediated disease [36]. Additionally, the use of lyophilized platelets in thrombocytopenic dogs has recently been reported with favorable results [37].

Thrombocyte Hyperaggregability

Veterinary oncologic patients may present with hyperaggregability and thromboembolism. Pulmonary thromboemboli (PTE) usually present with unexplained sudden hypotension, tachycardia, tachypnea, hypoxemia, or bronchospasm. Arterial blood gas analysis may reveal hypoxemia, hypocapnia, and an increased alveolar–arterial oxygen gradient. A decrease in end‐tidal CO₂ levels is also suggestive of pulmonary embolism, although it is not specific. Definitive diagnosis of intraoperative PTE may require selective pulmonary angiography or computed tomography with contrast angiography. However, these techniques are highly sophisticated and may not be readily available. Oxygen therapy should be instituted in a timely manner and definitive therapy may include thrombolytic therapy (streptokinase, 90 000 U as an IV infusion over 20–30 min, followed by 45 000 U as an IV infusion over 3–7 h) [38] as well as anticoagulation with heparin and warfarin therapy (low‐molecular‐weight heparin at 75–100 U kg⁻¹ SC every 8 h followed by warfarin at 0.1 mg kg⁻¹ every 24 h) [39]. Prophylactically, the selection of short‐acting or reversible anesthetic agents is warranted in patients prone to suffering PTE, as these protocols may allow early postoperative ambulation, therefore decreasing the incidence of additional thromboembolic episodes. Additionally, in animals considered at risk for PTE, prophylactic anticoagulant therapy may be instituted (low‐molecular‐weight heparin at 75–100 U kg⁻¹ SC every 8 h) [39].

Coagulation Disorders

PNS coagulopathies may be present, especially if alterations in platelet number and functionality are also present and DIC is the most frequent clinical abnormality [40]. Thrombocytopenia, prolongation of activated partial thromboplastin time (APTT), increased levels of fibrin degradation products (FDPs and D‐dimers), hypofibrinogenemia, and decreased antithrombin III (AT III) levels may be clear indicators of the presence of DIC (Table 17.3) [41]. Appropriate stabilization of any coagulation disorders is warranted prior to undertaking of general anesthesia.

Hypercalcemia

Approximately two‐thirds of dogs and one‐third of cats that present with hypercalcemia are diagnosed with neoplasia [47, 48]. The most common neoplasia associated with hypercalcemia of malignancy (HM) is lymphoma, but it may also be seen with mammary gland (adeno)carcinoma, parathyroid gland neoplasia, thyroid carcinoma, bone neoplasia, anal sac apocrine gland carcinoma, multiple myeloma, thymoma, squamous cell carcinoma, melanoma, and primary lung neoplasia [49–54]. Hypercalcemia occurs via bone resorption by osteoclasts and subsequent release of circulating calcium [55]. However, additional differentials include acute renal failure, hypoadrenocorticism, granulomatous disease, hypervitaminosis D, or a laboratory artifact (due to hemolysis or lipemia) [56]. Additionally, in the case of acidemia, an increase in the free ionized fraction of calcium can occur [9]. Similarly, the relationship between calcium and serum albumin should be evaluated, and the following correction formula could be used:

Total calcium levels >18 mg dl⁻¹ should be approached as a medical emergency [57]. Systemic signs include twitching, shaking, weakness, hypertension, bradycardia, depression, stupor, or even coma. Deposition of calcium salts in the renal parenchyma leads to pre‐renal and renal azotemia, while severe vasoconstriction causes a decrease in renal blood flow and glomerular filtration rate [58]. Decreased responsiveness to the antidiuretic hormone (ADH) at the distal tubule is responsible for the inability to concentrate urine. The urinary epithelium may then undergo degeneration and, eventually, necrosis [57]. Vomiting, polydipsia, and polyuria may develop and lead to progressive deterioration and dehydration of the patient. Since some of the symptomatic therapies to treat hypercalcemia could impair the ability to reach a final diagnosis or a final resolution of the etiology (e.g., glucocorticoids), the primary goal when managing a patient with HM should always be to elucidate and treat the underlying cause (for this reason, the use of corticosteroids in cases of hypercalcemia with undiagnosed neoplasia is strongly discouraged) [9, 59, 60].

General anesthesia should be performed with caution when calcium levels are significantly above the normal range (total calcium >12 mg dl⁻¹ or ionized calcium >1.5 mmol l⁻¹ in dogs and 1.4 mmol l⁻¹ in cats) due to hemodynamic and renal consequences (i.e., bradyarrhythmias, asystole and cardiac arrest, hypertension, azotemia, polyuria, polydipsia). Complete normalization of calcium levels may not be achieved prior to anesthesia, as excision of the tumor will likely be the only definitive treatment in many cases. Nevertheless, treatment should be directed at promoting external loss of calcium, increasing renal excretion of calcium, and inhibiting bone reabsorption [9]. For example, in the case of mild hypercalcemia (12–15 mg dl⁻¹) and no clinical signs, rehydration with 0.9% saline could result in normocalcemia. With moderate hypercalcemia (15–18 mg dl⁻¹), rehydration and consequent diuresis with 0.9% saline and furosemide (1–4 mg kg⁻¹ every 8–24 h IV, in dogs; 1–2 mg kg⁻¹ every 8–24 h IV, in cats) should be initiated to inhibit calcium reabsorption by the ascending loop of Henle. If the final diagnosis has been reached and lymphoma has been ruled out, prednisone (1 mg kg⁻¹ every 12 h PO, both dogs and cats) could be administered. In cases of refractory hypercalcemia, administration of salmon calcitonin (4–10 MRC units kg⁻¹ every 24 h SC) and bisphosphonates such as zoledronate (0.25 mg kg⁻¹ IV, every 4–5 weeks) or pamidronate (1–1.5 mg kg⁻¹ IV in dogs and 1.5–2 mg kg⁻¹ IV in cats, every 2–4 weeks) should be considered [61–63].

Hypoglycemia

Hypoglycemia is mainly associated with insulin‐producing islet cell pancreatic tumors [64]. However, it has been described in patients suffering from leiomyoma, leiomyosarcoma, hepatoma, hepatocellular carcinoma, and hemangiosarcoma [65]. Pathophysiologic mechanisms include increased tumor utilization of glucose, decreased hepatic gluconeogenesis, secretion of insulin‐like growth factors I and II, or upregulation of insulin receptors [66], and the most common clinical signs include weakness, disorientation, seizures, and coma. With severe hypoglycemia, IV bolus of 50% dextrose (1 ml kg⁻¹ diluted 1:2–1:4 over 5 min) and an IV infusion of 2–2.5% dextrose or glucagon should be initiated [67]. However, care must be taken when treating hypoglycemia in patients with suspected insulinoma or other tumors secreting insulin‐like analogs, since IV dextrose may stimulate the release of even larger amounts of insulin from the tumor, further aggravating the hypoglycemic state. Dextrose infusions should be formulated by adding the appropriate amount of 50% dextrose to an isotonic crystalloid fluid (such as Lactated Ringers, 0.9% NaCl, or Plasma‐Lyte) and then administered at fluid therapy maintenance rate (40 ml kg⁻¹ d⁻¹). Care must be taken to not administer 5% dextrose in water, since the solution is hypotonic and devoid of electrolytes. Glucagon can also be administered. It should be reconstituted and diluted in 0.9% saline, resulting in a 1000 ng ml⁻¹ solution. It may be first administered as a 50 ng kg⁻¹ bolus followed by a 5–40 ng kg⁻¹ min⁻¹ constant rate infusion. Some oncologic patients may be already receiving various treatments aimed at fighting hypoglycemia such as diazoxide (10–60 mg kg⁻¹ every 12 h PO, in dogs), as it increases glucose levels by enhancing epinephrine‐induced glycogenolysis and by inhibiting insulin release and uptake by cells [68]. Others may be receiving hydrochlorothiazide (2–4 mg every 12 h PO, in dogs and cats) to potentiate the effects of diazoxide, or somatostatin (5–20 g every 8–12 h PO or SC) [9, 68, 69].

Myasthenia Gravis

Acquired myasthenia gravis (MG) can occur in oncologic patients diagnosed with thymoma, osteosarcoma, lymphoma, and bile duct carcinoma [76–80]. Antibodies to nicotinic acetylcholine receptors are produced because of the tumor, and, as a consequence, failure of transmission across the neuromuscular junction occurs. Clinical signs include exercise intolerance, episodic muscular weakness, dysphagia, megaesophagus, and secondary aspiration pneumonia. Improvement of this tumor‐associated disorder may be observed after surgical removal of the tumor itself. However, the occurrence of megaesophagus is a negative prognostic factor [76]. The administration of immunosuppressive doses of prednisone (over 2 mg kg⁻¹ every 24 h PO, dogs and cats) may be attempted if surgical therapy is not an option. Since these patients frequently present with skeletal muscle weakness, perianesthetic concerns may include diaphragm insufficiency requiring ventilator support and/or megaesophagus (see Chapter 15). Patients may show resistance to depolarizing neuromuscular blockers (i.e., succinylcholine) [81]. On the other hand, acute sensitivity to the effects of nondepolarizing blockers (i.e., vecuronium, rocuronium, or atracurium) may also occur [82]. Consequently, approximately one‐tenth of the initial dose is advised in these patients. Assessment of the neuromuscular block using a nerve stimulator with or without acceleromyography or electromyography should always be established in patients requiring neuromuscular blockade.

Peripheral Neuropathy

Peripheral neuropathy affects both human and veterinary oncologic patients with lymphoma, multiple myeloma, primary lung neoplasia, mammary neoplasia, hemangiosarcoma, and MCTs [83–86]. The underlying pathophysiologic mechanism is due to autoantibodies targeting antigens expressed both on the tumor and the peripheral nerves [70]. Clinical signs range from weakness and progressive paraparesis to tetraparesis with lower motor neuron symptoms with or without polyneuropathy. Pain management is particularly important with these patients. Administration of gabapentin or pregabalin as adjuvant analgesics in addition to the standard pain management plan may be extremely beneficial in treating the neuropathic component of pain [87–93]. The most used dose of gabapentin in dogs is 10 mg kg⁻¹ PO every 8 h, while in cats the dose is of 10 mg kg⁻¹ PO every 12 h [94, 95]. Pregabalin dosages recommended by pharmacokinetic studies in both canine and feline patients are 4 mg kg⁻¹ PO every 12 h [96, 97].

Opioids

Opioids such as morphine, hydromorphone, methadone, fentanyl, buprenorphine, and butorphanol exert their analgesic effects and their side effects through actions on the different opioid receptors (μ, δ, and κ). The most frequent side effects of opioids include dose‐ and drug‐dependent cardiovascular depression due to a reduction in sympathetic tone. This often results in varying degrees of bradycardia, while no direct effects on systemic blood pressure or myocardial contractility are commonly seen [19]. Vasodilation from histamine release can also be observed, mainly after IV administration of morphine and meperidine [129]. Dose‐ and drug‐dependent respiratory depression may be described after opioid administration and may be especially noticeable when given in conjunction with anesthetic induction agents and volatile anesthetics. Ileus decreases gastric emptying time and constipation may be observed as well as short‐term urinary retention. Dysphoria may occur after opioid administration; however, it is infrequent if administered to animals in pain or in combination with sedatives or tranquilizers. Finally, alterations in thermoregulation, such as hypothermia and/or panting, are usually observed, while cats may exhibit hyperthermia after opioid administration.

All the previously mentioned parenteral opioids may be administered by an intermittent IV or IM route [19]. However, with intermittent dosing, patients often feel pain before their subsequent dose and may become sedated after dose administration. Alternatively, continuous rate infusions (CRI) of a shorter‐acting, potent opioid analgesic agent can be used (e.g., fentanyl, alfentanil, remifentanil). Fentanyl administered as a CRI provides constant and reliable plasma levels that provide excellent analgesia and allow sparing of inhalant agent; therefore, reducing its systemic adverse effects [130–134]. Fentanyl may also provide postoperative analgesia; due to potential respiratory depression, patients should be under constant and vigilant observation. Intramuscular, slow IV bolus, or CRI administration of morphine is efficacious, although histamine release may limit its use in MCTs [129]. Fentanyl transdermal patches provide another route of opioid administration and analgesia can be provided for several days [135–137]. However, the degree of analgesia can be unpredictable, especially in cats, probably due to failure of patch application or inappropriate dosing, and frequent patient monitoring is essential [138, 139]. Since plasma levels do not reach peak values until 12–24 h post placement, additional analgesia should be provided in the immediate postoperative period. Fentanyl patches are a suitable option for patients that may need prolonged opioid administration and for those that do not tolerate oral medication. Fentanyl patches should not be prescribed when young children are in the household, since potential removal and ingestion are of concern [140, 141]. Finally, opioids such as morphine and fentanyl have been administered epidurally to prolong perioperative analgesia [142–145]. With placement of an epidural catheter, epidural opioids can be administered for days to weeks in patients suffering from peritoneal or pancreatic pain, as well as following amputations.

Nonsteroidal Anti‐Inflammatory Drugs

NSAIDs such as meloxicam or carprofen are used widely to treat mild‐to‐moderate pain associated with inflammation and to reduce opioid consumption. However, they possess a much lower therapeutic index than opioids and are not reversible. NSAIDs inhibit COX enzymes, thereby preventing the production of prostaglandins (PG), thromboxanes, and prostacyclin from membrane phospholipids. However, the isoenzyme COX‐2 is also related to the pathogenesis and progression of certain types of tumors. The synthesis of PGE₂ by COX‐2 has been associated with the promotion of tumorigenesis, and COX‐2 overexpression inhibits apoptosis, facilitates the adhesion and invasiveness of tumor cells, increases cell growth, suppresses the immune system, and enhances angiogenesis [146, 147]. Overexpression of COX‐2 has been implicated in a number of canine carcinomas, such as those affecting the bladder, kidneys, mammary tissues, and intestines, squamous cell carcinoma, and some sarcomas such as osteosarcoma [148–152]. As a result, the use of selective COX‐2 inhibitors is widespread not only for their analgesic effects in patients with these types of tumors, but also for their beneficial effects on the tumor therapy [153–165].

The most common side effects of NSAIDs include impairment of gastrointestinal protection, inhibition of platelet aggregation and vasoconstriction, and impairment of renal perfusion [166]. Oncologic patients are at greater risk of toxic effects due to their potential for pre‐existing renal disease or the concurrent administration of nephrotoxic oncologic therapies. The use of NSAIDs is not recommended in patients, regardless of their tumor, that present with gastrointestinal disorders, coagulopathies, impaired renal and hepatic function, patients that are dehydrated or hypovolemic, and those that are already receiving other NSAIDs or corticosteroids. Additionally, it should be remembered that cats have longer and inconsistent rates of metabolism and excretion of NSAIDs compared to other species (particularly through glucuronidation), and chronic dosing (longer than 5 days) is likely to be associated with greater risks in cats than other species and therefore should be used cautiously [167]. Renal monitoring of the patient that is receiving NSAID‐based therapy is warranted. The owner should be informed of the potential for toxicity as well as instructed for monitoring of adverse events (depression, lethargy, vomiting, melena, and polyuria). Baseline blood work and urinalysis should also be performed at the beginning of therapy and repeated every 2–4 weeks and up to 1–4 months depending on the individual patient and evolution of the case.

Local Anesthetics

Local anesthesia is the only effective way of providing complete analgesia, as the main mechanism of action is via blockage of sodium channels. Perineural administration completely blocks transmission of nociception, thereby minimizing central sensitization for the duration of block. Local anesthetics (LAs) can be used by topical application, local infiltration, IV administration, interpleural administration, body cavity instillation, through wound‐soaker catheters, by transdermal patches, and through epidural catheters. Neurological side effects are biphasic, first shown as excitatory signs (tremors, visual disturbances, and eventually seizures) and then signs of neurological depression (coma and apnea). Cardiovascular side effects include direct myocardial depression from blockade of cardiac sodium channels.

The use of topical LAs as a eutectic mixture of 2.5% lidocaine and 2.5% prilocaine (EMLA) cream has been suggested to minimize pain and discomfort during venipuncture or intravenous catheterization [168, 169]. LAs may be deposited directly over selected nerves prior to transection during surgical procedures. Ring blocks around the distal end of affected limbs or around a mass that needs to be excised may also be performed through infiltration of tissues. Ideally, the infiltration should be performed prior to surgery, paying attention to a gentle and cautious application if dealing with aggressive tumors (i.e., sarcoma); however, infiltrative blocks can also be employed during closure of surgical wounds, applying the traditional or liposome‐encapsulated local anesthetic at various levels during wound closure. Finally, administration of the local anesthetic adjacent to the wound during closure has been shown to reduce pain postoperatively and reduce opioid requirements following laparotomy [170].

Wound diffusion catheters (also known as wound‐soaker catheters) may be used to provide analgesia to large surgical wounds (e.g., amputations, tumor resection, mastectomies; Figure 17.12). They are usually well‐tolerated and, if correctly placed, may not only improve patient comfort but significantly decrease opioid requirements. The incidence of wound infections or breakdown appears to be the same as in dogs where wound‐soaker catheters are not placed [171]. Occasionally, catheters may fail to provide analgesia for the full extent of the surgical site; this may be due to uneven distribution of local anesthetic, incorrect placement, or catheter blockage. LAs may be administered every 6–8 h (1–2 mg kg⁻¹ ropivacaine or bupivacaine) [171]. The catheters can be removed 48 h after placement or remain in place for longer, if required.

LAs may be administered interpleurally to provide analgesia post thoracotomy and to manage pain in a variety of pleural conditions. After drainage of the chest is performed, a 0.25% solution of bupivacaine (1.5 mg kg⁻¹) may be slowly administered through the drain (Figure 17.13). This technique will usually provide up to 6 h of analgesia, while the pleural cavity may still be drained every hour if necessary, without affecting the efficacy of analgesia [172–176].

LAs may also be administered intraperitoneally. It has been found that the combination of intraperitoneal bupivacaine administered preoperatively with subcutaneous wound infiltration with bupivacaine postoperatively provided improved analgesia in dogs [170]. Similarly, sprayed, and injected intraperitoneal bupivacaine relieves postoperative pain behavior and biochemical stress responses after surgery in dogs [177, 178].

Newer techniques such as IV lidocaine infusions are efficacious and safe in dogs while decreasing isoflurane MAC [179]. In addition, longer‐term epidural analgesia may be preferable for pain management of certain procedures and conditions (e.g., pancreatic pain, extensive hind limb surgery, amputations) and an epidural catheter may be placed to allow repeated administration of LAs (Figure 17.14). Drugs may be epidurally administered intermittently as a bolus or as an infusion using a syringe pump. Preservative‐free morphine (0.1 mg kg⁻¹) may be administered every 12–24 h, while bupivacaine (0.06–0.12 mg kg⁻¹) can be administered intermittently as required. Alternatively, a CRI into the epidural catheter of morphine (0.0125 mg kg⁻¹ h⁻¹) and bupivacaine (0.03 mg kg⁻¹ h⁻¹) has been reported [180].

Lidocaine 5% patches may be applied alongside wounds that present allodynia. Studies in both dogs and cats suggest that local skin lidocaine concentrations are high while plasma levels are low, suggesting that the analgesia seen following placement is most likely due to the local effect rather than to a systemic effect [181–184].

NMDA Antagonists

The use of subanesthetic doses of NMDA antagonists such as ketamine and amantadine may reduce the chances of central sensitization developing postoperatively and may also be particularly helpful for the management of pain derived from nerve damage. Side effects of this drug class include dose‐dependent cardiovascular stimulation via sympathetic activation, increased salivation and respiratory tract secretions, cerebral vasodilation, and elevated systemic blood pressure that may lead to significant increases in cerebral blood flow and intracranial pressure. However, at the doses used for analgesia, these effects are minimized.

Bolus administration of ketamine and low‐dose ketamine infusions for adjunctive analgesia have become common practices in the perioperative setting (e.g., hemilaminectomies, amputations). Several studies have proven the MAC‐sparing properties of ketamine; however, only few studies evaluate the analgesic effects of ketamine which suggest that ketamine decreases postoperative wound hyperalgesia and pain scores and rescues analgesic requirements [185–187].

Amantadine is an antiviral drug that was originally approved to treat influenza A in people. It is also used clinically to reduce symptoms of Parkinson’s disease and other drug‐induced extrapyramidal syndromes. Similar to ketamine, it is an NMDA receptor antagonist. However, it differs from ketamine, as it does not block the flow of current through open channels, but it stabilizes channels in the closed state. Numerous laboratory animal studies suggest that amantadine’s NMDA antagonist activities may make it a useful adjunctive analgesic agent [188–190], but there are a limited number of controlled trials documenting its safety and efficacy in dogs and cats. It has been included in a multimodal analgesic regimen for the alleviation of refractory canine osteoarthritis pain and dogs had activity and lameness scores [191]. Amantadine may come to play a key role in managing chronic pain in dogs in the future and it may be an interesting therapeutic option for oncology patients.

Alpha‐2‐Adrenergic Receptor Agonists

Alpha‐2‐adrenergic receptor agonists such as dexmedetomidine are commonly used as adjunctive analgesics, although they are not considered first‐line analgesics. Alpha‐2‐adrenergic receptors and opioid receptors appear to interact and coadministration of these two classes of drugs may achieve synergistic analgesic effects. However, the alpha‐2 receptor‐mediated analgesic effect is of shorter duration than the sedative effects [192, 193]. They are particularly useful in cardiovascular stable patients that require anxiolysis in addition to analgesia. Side effects include vasoconstriction, decreased cardiac contractility, reflex bradycardia and atrioventricular blocks, nausea and vomiting, polyuria, hyperglycemia, and increased myometrial contractility.

Dexmedetomidine CRIs may help manage both intraoperative and postoperative pain and have been found to be equally effective as morphine CRIs at providing postoperative analgesia, with no significant adverse clinical effects [194]. In addition, the incorporation of low‐dose medetomidine or dexmedetomidine into an epidural protocol may achieve additive or synergistic analgesic effects when combined with standard doses of opioids or LAs due to actions at spinal alpha‐2‐adrenergic receptors [195–198]. In addition to the epidural route, alpha‐2‐adrenergic receptor agonists may be administered intraarticular and perineural, where they contribute to analgesia by inhibition of norepinephrine release and by enhancing peripheral nerve block intensity.

Tramadol

Tramadol is a synthetic codeine analog that exerts weak agonist properties at all opioid receptors (particularly at μ‐opioid receptors). In addition, it stimulates presynaptic serotonin release and inhibits the reuptake of serotonin and noradrenaline [199]. Its analgesic potency is one‐tenth that of morphine; however, recent studies comparing the effects of IV tramadol and morphine administered before ovariohysterectomy concluded that IV tramadol was comparable to morphine in its analgesic efficacy for this type of surgical pain [200, 201]. On the other side, oral administration of tramadol has shown to provide an unreliable degree of absorption as well as low concentrations of the pharmacologically active metabolite (O‐desmethyltramadol, ODM) [202]. In fact, pharmacokinetic studies in dogs have shown that dogs do not produce ODM as a substantial metabolite after tramadol administration; therefore, dogs are not expected to have substantial opioid effects after tramadol administration [203, 204]. However, pharmacokinetics in cats are different, since they produce high concentrations of ODM after tramadol administration and, as a result, can show significant opioid effects. Common side effects include sedation and dysphoria (especially in cats), while constipation and respiratory depression seem to be generally milder than those caused by opioids. Its administration is contraindicated in patients with hepatic insufficiency and in those that are seizure‐prone, as it decreases the seizure threshold in humans. Because of its inhibitory effect on serotonin uptake, tramadol should not be administered to patients that may have received monoamine oxidase inhibitors, such as selegiline.

Anticonvulsants

Neuromodulating drugs, such as anticonvulsants, have become the mainstay of neuropathic pain treatment in human patients in the past decades. Both pregabalin and gabapentin share a similar mechanism of action by binding to the α₂δ subunit of the voltage‐gated calcium channels and inhibiting the release excitatory neurotransmitters involved in pain transmission. Side effects are minimal, and they are limited to mild ataxia and sedation.

Although gabapentin is widely used in the treatment of human patients [205–207], only a few investigations have documented its effectiveness to treat chronic neuropathic pain, chronic cancer pain, chronic osteoarthritis pain, and perioperative pain in veterinary medicine [87–89, 92, 94,208–211

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