Ningshan Wang

Quantification of sweat gland innervation A clinical–pathologic correlation

Objective: To evaluate a novel method to quantify the density of nerve fibers innervating sweat glands in healthy control and diabetic subjects, to compare the results to an unbiased stereologic technique, and to identify the relationship to standardized physical examination and patient-reported symptom scores. Methods: Thirty diabetic and 64 healthy subjects had skin biopsies performed at the distal leg and distal and proximal thigh. Nerve fibers innervating sweat glands, stained with PGP 9.5, were imaged by light microscopy. Sweat gland nerve fiber density (SGNFD) was quantified by manual morphometry. As a gold standard, three additional subjects had biopsies analyzed by confocal microscopy using unbiased stereologic quantification. Severity of neuropathy was measured by standardized instruments including the Neuropathy Impairment Score in the Lower Limb (NIS-LL) while symptoms were measured by the Michigan Neuropathy Screening Instrument. Results: Manual morphometry increased with unbiased stereology (r = 0.93, p < 0.01). Diabetic subjects had reduced SGNFD compared to controls at the distal leg (p < 0.001), distal thigh (p < 0.01), and proximal thigh (p < 0.05). The SGNFD at the distal leg of diabetic subjects decreased as the NIS-LL worsened (r = −0.89, p < 0.001) and was concordant with symptoms of reduced sweat production (p < 0.01). Conclusions: We describe a novel method to quantify the density of nerve fibers innervating sweat glands. The technique differentiates groups of patients with mild diabetic neuropathy from healthy control subjects and correlates with both physical examination scores and symptoms relevant to sudomotor dysfunction. This method provides a reliable structural measure of sweat gland innervation that complements the investigation of small fiber neuropathies.

α-Synuclein in cutaneous autonomic nerves.

Objective: To develop a cutaneous biomarker for Parkinson disease (PD). Methods: Twenty patients with PD and 14 age- and sex-matched control subjects underwent examinations, autonomic testing, and skin biopsies at the distal leg, distal thigh, and proximal thigh. α-Synuclein deposition and the density of intraepidermal, sudomotor, and pilomotor nerve fibers were measured. α-Synuclein deposition was normalized to nerve fiber density (the α-synuclein ratio). Results were compared with examination scores and autonomic function testing. Results: Patients with PD had a distal sensory and autonomic neuropathy characterized by loss of intraepidermal and pilomotor fibers (p < 0.05 vs controls, all sites) and morphologic changes to sudomotor nerve fibers. Patients with PD had greater α-synuclein deposition and higher α-synuclein ratios compared with controls within pilomotor nerves and sudomotor nerves (p < 0.01, all sites) but not sensory nerves. Higher α-synuclein ratios correlated with Hoehn and Yahr scores (r = 0.58–0.71, p < 0.01), with sympathetic adrenergic function (r = −0.40 to −0.66, p < 0.01), and with parasympathetic function (r = −0.66 to −0.77, p > 0.01). Conclusions: We conclude that α-synuclein deposition is increased in cutaneous sympathetic adrenergic and sympathetic cholinergic fibers but not sensory fibers of patients with PD. Higher α-synuclein deposition is associated with greater autonomic dysfunction and more advanced PD. These data suggest that measures of α-synuclein deposition in cutaneous autonomic nerves may be a useful biomarker in patients with PD.

Quantification of sudomotor innervation: A comparison of three methods

Peripheral sudomotor dysfunction is present in many peripheral neuropathies, but structural assessments of sudomotor fibers rarely occur. We evaluated 36 diabetic and 72 healthy control subjects who underwent detailed neurologic examinations and punch skin biopsies. Physical exam findings were quantified by neuropathy impairment score in the lower limb. Skin biopsies quantified intraepidermal nerve fiber density (IENFD) and sweat gland nerve fiber density (SGNFD) by a manual, automated, and semiquantitative method. The automated and manual SGNFD correlated with the IENFD at the same site (r = 0.62, P < 0.05 automated method, r = 0.67, P < 0.05 manual method). As neuropathy worsened, the SGNFD at the distal leg declined (automated counting r = −0.81, P < 0.001; manual counting r = −0.88, P < 0.001). The semiquantitative method displayed poor inter‐ and intrareviewer reliability and correlated poorly with standard neuropathy evaluation scores. Our results suggest that sudomotor fibers can be rapidly and reproducibly quantified, and results correlate well with physical exam findings. Muscle Nerve, 2010

Capsaicin Induces Degeneration of Cutaneous Autonomic Nerve Fibers

To determine the effects of topical application of capsaicin on cutaneous autonomic nerves.

Novel Immunohistochemical Techniques Using Discrete Signal Amplification Systems for Human Cutaneous Peripheral Nerve Fiber Imaging

Confocal imaging uses immunohistochemical binding of specific antibodies to visualize tissues, but technical obstacles limit more widespread use of this technique in the imaging of peripheral nerve tissue. These obstacles include same-species antibody cross-reactivity and weak fluorescent signals of individual and co-localized antigens. The aims of this study were to develop new immunohistochemical techniques for imaging of peripheral nerve fibers. Three-millimeter punch skin biopsies of healthy individuals were fixed, frozen, and cut into 50-µm sections. Tissues were stained with a variety of antibody combinations with two signal amplification systems, streptavidin-biotin-fluorochrome (sABC) and tyramide-horseradish peroxidase-fluorochrome (TSA), used simultaneously to augment immunohistochemical signals. The combination of the TSA and sABC amplification systems provided the first successful co-localization of sympathetic adrenergic and sympathetic cholinergic nerve fibers in cutaneous human sweat glands and vasomotor and pilomotor systems. Primary antibodies from the same species were amplified individually without cross-reactivity or elevated background interference. The confocal fluorescent signal-to-noise ratio increased, and image clarity improved. These modifications to signal amplification systems have the potential for widespread use in the study of human neural tissues.

A multi-center, multinational age- and gender-adjusted normative dataset for immunofluorescent intraepidermal nerve fiber density at the distal leg

Quantification of intraepidermal nerve fibers (IENFs) in skin biopsies is now the tool of choice to diagnose small fiber neuropathies. An adequate normative dataset, necessary to assess normality cutoffs, is available for brightfield microscopy but not for immunofluorescence.

Structural and Functional Small Fiber Abnormalities in the Neuropathic Postural Tachycardia Syndrome

Objective To define the neuropathology, clinical phenotype, autonomic physiology and differentiating features in individuals with neuropathic and non-neuropathic postural tachycardia syndrome (POTS). Methods Twenty-four subjects with POTS and 10 healthy control subjects had skin biopsy analysis of intra-epidermal nerve fiber density (IENFD), quantitative sensory testing (QST) and autonomic testing. Subjects completed quality of life, fatigue and disability questionnaires. Subjects were divided into neuropathic and non-neuropathic POTS, defined by abnormal IENFD and abnormal small fiber and sudomotor function. Results Nine of 24 subjects had neuropathic POTS and had significantly lower resting and tilted heart rates; reduced parasympathetic function; and lower phase 4 valsalva maneuver overshoot compared with those with non-neuropathic POTS (P<0.05). Neuropathic POTS subjects also had less anxiety and depression and greater overall self-perceived health-related quality of life scores than non-neuropathic POTS subjects. A sub-group of POTS patients (cholinergic POTS) had abnormal proximal sudomotor function and symptoms that suggest gastrointestinal and genitourinary parasympathetic nervous system dysfunction. Conclusions and Relevance POTS subtypes may be distinguished using small fiber and autonomic structural and functional criteria. Patients with non-neuropathic POTS have greater anxiety, greater depression and lower health-related quality of life scores compared to those with neuropathic POTS. These findings suggest different pathophysiological processes underlie the postural tachycardia in neuropathic and non-neuropathic POTS patients. The findings have implications for the therapeutic interventions to treat this disorder.

The diagnostic discrimination of cutaneous α-synuclein deposition in Parkinson disease

Objective: To determine the diagnostic discrimination of cutaneous α-synuclein deposition in individuals with Parkinson disease (PD) with and without autonomic dysfunction on autonomic testing, in early and late stages of the disease, and of short and long duration. Methods: Twenty-eight participants with PD and 23 control participants were studied by skin biopsies at multiple sites, autonomic function testing, and disease-specific scales. Results: Skin biopsies provide >90% sensitivity and >90% specificity to distinguish PD from control participants across all biopsies sites with quantification of either pilomotor or sudomotor α-synuclein deposition. All individuals with PD have significantly higher cutaneous α-synuclein deposition than control participants, even those individuals with PD and no evidence of autonomic dysfunction. Deposition of α-synuclein is most prominent in sympathetic adrenergic nerve fibers innervating the arrector pili muscles, but is also present in sudomotor (sympathetic cholinergic) nerve fibers. α-Synuclein is present even in the early stages of disease and disease of short duration. α-Synuclein ratios were higher in individuals with autonomic failure, with more advanced stages of disease and disease of longer duration. Conclusions: The α-synuclein ratio provides a sensitive and specific diagnostic biomarker of PD even in patients without autonomic failure. Classification of evidence: This study provides Class III evidence that cutaneous α-synuclein deposition accurately identifies patients with PD.

Skin biopsies in the assessment of the autonomic nervous system

Cutaneous punch biopsies are widely used to evaluate nociceptive C fibers in patients with suspected small-fiber neuropathy. Recent advances in immunohistochemical techniques and interest in cutaneous autonomic innervation has expanded the role of skin biopsy in the evaluation of the peripheral nervous system. The dermal layers of the skin provide a unique window into the structural evaluation of the autonomic nervous system. Peripheral adrenergic and cholinergic fibers innervate a number of cutaneous structures, such as sweat glands and arrector pili muscles, and can easily be seen with punch skin biopsies. Skin biopsies allow for both regional sampling, in diseases with patchy distribution, and the opportunity for repeated sampling in progressive disorders. The structural evaluation of cutaneous autonomic innervation is still in its scientific infancy, with a number of different methodologies and techniques that will require standardization and widespread acceptance before becoming a standard of care. Future studies of autonomic innervation in acquired, hereditary, neurodegenerative, or autoimmune disorders will be necessary to determine the clinical utility of skin biopsy in these disease states.

The role of skin biopsy in differentiating small-fiber neuropathy from ganglionopathy

We aimed to test the clinical utility of the leg:thigh intraepidermal nerve‐fiber (IENF) density ratio as a parameter to discriminate between length‐dependent small‐fiber neuropathy (SFN) and small‐fiber sensory ganglionopathy (SFSG) in subjects with signs and symptoms of small‐fiber pathology.