The general information on the mechanism of action of local anaesthetics, nerve fibre types and their specific function, along with time to onset and duration of action of different local anaesthetics, is commonly published and can be referenced from many sources (Berde & Strichartz, ; Catterall & Mackie, ; Scholz, Salinas, Spencer, & Liu., ). Veterinary‐focused reviews have been published (Campoy & Read, ; Rioja Garcia, ). Original research is not available for much of this information but is included where possible. Specific information in dogs and cats is included where possible.

As stated, local anaesthetics block sodium channels in the nerve to block propagation and transmission of nociceptive impulses. The presence of myelination, nerve fibre diameter and firing frequency impact the order and likelihood of blockade and contribute to the ‘selective’ or ‘differential’ blockade of the nerves, which was first described in 1929 (Gasser & Erlanger, ). Nerves are divided into groups (A, B, C) according to size and myelination. Group A fibres are large, myelinated fibres that transmit signals associated with motor function of muscles (A‐α); touch, pressure and proprioception (A‐β); and intense, early onset (or ‘fast’) pain (A‐δ). Group B are small, myelinated fibres primarily associated with autonomic function like vasomotor control. Group C are small, unmyelinated fibres that transmit signals associated with temperature and low‐level or ‘dull’ pain. Although not entirely straight forward, in general, following the administration of local anaesthetics, the fibres in Group B are desensitized first, followed by the C‐ and A‐δ fibres, then by the A‐ β fibres (Rioja Garcia, ). The larger‐diameter fibres in Group A are the most blockade resistant, thus motor function is the last to be blocked or may not be blocked at all (Rioja Garcia, ). Return to normal signal transmission appears to occur in the opposite order (Becker & Reed, ). Also contributing to selective blockade is the fact that myelinated nerves require blockade of at least three nodes of Ranvier to halt impulse conduction and the increased internodal distance in larger nerves makes these nerves more resistant to blockade (Fink, ). Not only fibre‐type but also specific drugs can contribute to differential blockade with bupivacaine (0.125%) reported to have more sensory than motor blockade (Bleyaert, Soetens, Vaes, Steenberge, & Donck, ). Ropivacaine and levobupivacaine (Camorcia, Capogna, Berritta, & Columb, ) and liposome‐encapsulated bupivacaine (Joshi, Patou, & Kharitonov, ) cause less motor blockade than regular bupivacaine. Clinically, higher dosages and/or concentrations of any of these drugs are more likely to cause motor blockade and motor blockade should always be anticipated. This can be concerning if patients cannot use limbs to ambulate following surgery but the motor effects are generally minimal or absent by the time the patient has recovered from anaesthesia to the point that it is ambulatory. Motor blockade and subsequent muscle relaxation may actually be useful in a number of instances, as in fracture reduction.

The speed of onset of action of local anaesthetics is determined by the effect of pKa on the number of lipid soluble molecules at the cell membrane. It is the unionized lipid soluble molecules that can more easily, thus more rapidly, cross into the cell and the pKa of the drug dictates the proportion of molecules that are in an unionized lipid‐soluble state (Berde & Strichartz, ; Catterall & Mackie, ; Scholz et al., ). Drugs like lidocaine with a pKa (7.9) near physiologic pH (7.4) have a fast onset of action, whereas drugs like bupivacaine and ropivacaine (pKa 8.1) have a slower onset of action. An acidic local tissue environment, as might occur with infection, will cause an increased number of local anaesthetic (weak bases) molecules to remain in the unionized state and the onset of action may be slower (Berde & Strichartz, ; Catterall & Mackie, ; Scholz et al., ). Although it is the lipid soluble molecules that cross into the cell, increased lipid solubility of the drug may actually cause slower onset of action since the injected drug will have more uptake into lipid tissues like fat (Gissen, Covino, & Gregus, ). The drug is then slowly released from the lipid compartment instead of acting relatively immediately on the nerve, which slows onset, but prolongs duration, of action (Campoy & Read, ). While lipid solubility and protein binding are separate attributes, they are also related. Drugs that are more lipid soluble have greater protein binding, which also increases the duration of the block. Thus, drugs with high lipid solubility like bupivacaine have a longer duration of action than those with low lipid solubility like lidocaine. Finally, potency, described as the number of molecules needed to produce a pharmacologic effect (i.e. dose), is also based on lipid solubility, with increased solubility equating to increased potency. These properties (pKa, lipid solubility, protein binding) are inherent to each drug and determined by the chemical structure of that drug (Berde & Strichartz, ; Catterall & Mackie, ; Scholz et al., ).

For all local anaesthetic drugs, the clinical time‐to‐onset, duration‐of‐action and recommended dose may vary slightly between clinical references and the (generally) small variances are often based on practitioner experience. Dose, concentration of drug and volume of injectate can also impact these parameters. The drug information in this manuscript is compiled from several veterinary‐specific references (Campoy & Read, ; Duke‐Novakovski, ; Lemke, ; Rioja Garcia, ) and from the clinical experience of the authors. Where available, specific dosing references are provided. The doses listed are total cumulative doses and should be divided between blocks if more than one block is planned. If lidocaine infusions are included in the analgesic protocol, the low end of the local block dose and the low end of the infusion dose should be used to avoid overdosage. However, it is not necessary to include the very small amount of lidocaine typically used on the arytenoids during intubation of cats as part of the total cumulative dose. In adult cats, 2% lidocaine dosed at 0.1 ml (total dose) administered topically on the larynx PLUS 0.1 ml/kg administered intratesticularly produced serum concentrations well below toxic levels (Soltaninejad & Vesal, ). In contrast, as mentioned by the reviewer of this manuscript, the dose of a specific product (not used by the authors) is up to 5 mg/kg for arytenoid desensitization. This is a significant contribution and should be considered as part of the total dose.

The most serious adverse effects generally occur secondary to rapid IV bolus of a supra‐clinical dose of local anaesthetic drugs (Epstein et al., ; Mathews et al., ; Rioja Garcia, ). Although the drugs (other than lidocaine) are unlikely to be administered rapidly IV, accidental intravascular injection, as would be most likely with poor injection technique, could occur with any block. Consequently, aspiration should always be used to determine correct needle placement prior to local anaesthetic drug injections. The incidence of systemic toxicity in veterinary species is not documented, but in the opinions of both the authors and other pain management experts (Epstein et al., ; Mathews et al., ), it is very low. The incidence of systemic toxicity in humans is 1–7.5 in 10,000 (Auroy et al., ; Faccenda & Finucane, ). Among local anaesthetics, only lidocaine can be safely administered intravenously. Although commonly used by this route, the administration is not without potential adverse effects. At low serum lidocaine concentrations, inhibitory neuron depression can cause muscle fasciculations, weakness, visual disturbances and can potentially cause cerebral excitation and seizures. At higher concentrations (i.e. overdose), profound central nervous system (CNS) depression with subsequent coma, respiratory arrest and death can occur. Other than bupivacaine, the toxic effects follow a gradation like that just described for lidocaine, with lower dosages causing signs such as mild muscle twitching, and progressing as dosages increase through seizures, unconsciousness, coma, respiratory arrest and cardiovascular collapse (Rioja Garcia, ). Bupivacaine is more cardiotoxic and cardiac signs can occur simultaneous with central nervous system signs. Cardiovascular system adverse effects are most commonly associated with a bupivacaine overdose and are due to the higher lipophilicity of bupivacaine and longer duration of sodium channel blockade when compared with other local anaesthetic drugs (Greensmith & Bosseau, ). IV boluses of bupivacaine can induce hypotension or cardiovascular collapse, which can be fatal, secondary to blockade of the myocardial conduction system. This is unlikely with liposome‐encapsulated bupivacaine (see more information under specific drugs). Inadvertent IV injections of lipophilic drugs, which includes all local anaesthetics with bupivacaine being the most lipophilic, can be managed by the “lipid rescue” protocol to sequester the lipid soluble drug until it can be cleared (Weinberg, Ripper, Feinstein, & Hoffman, ). In lipid rescue a 20% lipid emulsion is infused intravenously as emergency treatment. Although the mechanism of action remains unknown, the presumption is that the injected lipids form a ‘sink’ for the local anaesthetic to bind to, thus decreasing binding to lipid cellular membranes, which decreases the toxic effects (Rothschild, Bern, Oswald, & Weinberg, ). Other adverse effects of local anaesthetics include anaphylaxis, which is very rare and primarily associated with esters (e.g. procaine) and drugs containing methylparaben as a preservative. Lidocaine, ropivacaine, mepivacaine and bupivacaine, including liposome‐encapsulated bupivacaine, are amides. Methemoglobinaemia is rare and primarily associated with benzocaine (ester) in cats. The toxic effects are covered in more detail in other references (Rioja Garcia, ). Dosages of drugs shown to cause systemic toxicity are listed in the section on individual drugs. If not listed, published data are unavailable.

In addition to systemic adverse effects, nerve damage and specific injection site‐related adverse effects could occur and are discussed in Part 2 of the manuscript (Grubb & Lobprise, ). Infections from local anaesthetic injections are an extremely unlikely adverse event because local anaesthetics have a mild antimicrobial effect (Johnson, Saint John, & Dine, ). However, micro‐organisms can spread along the needle tract when infected tissues are infiltrated.