Methods and protocols for translatable rodent models of postsurgical pain.

Due to the large volume of surgeries and the subsequent incidence of postsurgical pain, it is vital that the underlying mechanisms of postsurgical pain are thoroughly understood. The intensity of acute postsurgical pain is typically dependent on the severity of tissue damage the surgery produces, and the development of chronic pain is more frequent in major surgeries than in minor ones. It is therefore important that postsurgical pain studies are conducted with the differences between major and minor surgeries in mind. To this end, the paw incision and skin muscle incision and retraction models are the focus of this chapter as they feature aspects observed in minor and major surgeries in humans, respectively. Several elements of these models translate to humans with some limitations, as they allow for the measurement of reflexive, spontaneous, and functional pain-like behavior. For these attributes, the SMIR and paw incision surgeries are widely used in postsurgical pain research. Here we layout detailed protocols to instruct experienced as well as inexperienced researchers studying postsurgical pain in rats and mice.

Methods and protocols for chemotherapy-induced peripheral neuropathy (CIPN) mouse models using paclitaxel.

While cancer patients may have chemotherapeutics to thank for being cured of their malignancy, they are often left to suffer a disabling neuropathy induced by that same cancer treatment. This neuropathy, known as chemotherapy-induced peripheral neuropathy, or CIPN, is one of the most debilitating survivorship concerns for patients, with many citing hallmark symptoms of hyperalgesia, allodynia, and numbness, and subsequently reducing their dose or even ceasing treatment altogether. Investigations into this interplay between the antineoplastic activity of chemotherapeutic agents and the preservation of peripheral nerve health are therefore crucial for the development of CIPN treatment and prevention methods. Responding to need, current literature is inundated with varying preclinical models of CIPN. This chapter thus seeks to provide a detailed and reliable methodology for the induction and assessment of CIPN in mice, using a preclinical model that is both reproducible and translatable to several aspects of the clinical phenotype. Specifically, this chapter lays out a model for intermittent low-dose paclitaxel induction of CIPN in C57BL/6J mice, and a testing of this induction via von Frey filament mechanical hypersensitivity assays, a mechanical hyposensitivity (numbness) assay, and a cold-thermal allodynia assay (acetone test). These protocols can easily be adjusted to fit the needs of individual CIPN experiments, as stated throughout the chapter.