RESUMO
Over the last three decades, skin punch biopsy has become the gold standard for diagnosis of small fiber neuropathies, including autonomic neuropathies commonly seen in diabetics, patients with HIV, and children with hereditary sensory autonomic neuropathies and toxin-induced neuropathy. Clinical, biochemical, electrophysiological tests are inconclusive, making it difficult to diagnose and initiate treatment. A skin punch biopsy is easy to perform in the outpatient clinic, is highly sensitive, and provides an objective diagnosis. Importantly, it helps avoid performing invasive nerve biopsy in patients with small fiber neuropathy, thereby preventing complications such as non-healing of the biopsy site, which is common in these patients. Secondly, the greatest advantage of skin punch biopsies is that they can be repeated any number of times, unlike a nerve biopsy, and are useful to evaluate disease progression and therapeutic response. More recently, its use has been expanded to the diagnosis of large fiber neuropathies, inherited demyelinating neuropathies, etc., obviating the need for a nerve biopsy. The European Federation of Neurological Societies has published guidelines for evaluation to ensure uniformity with regard to the site of biopsy, processing, and quantification. The evaluation of the skin biopsy involves morphometric assessment of the intraepidermal nerve fiber density using PGP 9.5 immunostained sections by bright-field microscopy. This review focuses on the practical aspects of skin punch biopsy and its utility for the practicing pathologist.
RESUMO
Muscular dystrophies are a clinically and genetically heterogeneous group of disorders involving the skeletal muscles. They have a progressive clinical course and are characterized by muscle fiber degeneration. Congenital muscular dystrophies (CMD) include dystroglycanopathies, merosin-deficient CMD, collagen VI-deficient CMD, SELENON-related rigid spine muscular dystrophy, and LMNA-related CMD. Childhood and adult-onset muscular dystrophies include dystrophinopathies, limb-girdle muscular dystrophies, Emery-Dreifuss muscular dystrophy, facioscapulohumeral muscular dystrophy, and myotonic dystrophy. Traditionally, muscle biopsy and histopathology along with special pathology techniques such as immunohistochemistry or immunoblotting were used for the diagnosis of muscular dystrophies. However, recent advances in molecular genetic testing, especially the next-generation sequencing technology, have revolutionized the diagnosis of muscular dystrophies. Identification of the underlying genetic basis helps in appropriate management and prognostication of the affected individual and genetic counseling of the family. In addition, identification of the exact disease-causing mutations is necessary for accurate prenatal genetic testing and carrier testing, to prevent recurrence in the family. Mutation identification is also essential for initiating mutation-specific therapies (which have been developed recently, especially for Duchenne muscular dystrophy) and for enrolment of patients into ongoing therapeutic clinical trials. The 'genetic testing first' approach has now become the norm in most centers. Nonetheless, muscle biopsy-based testing still has an important role to play, especially for cases where genetic testing is negative or inconclusive for the etiology.