This study analyzed the relationship between the density of intraepidermal nerve fibers (IENF) and the characteristics of either nociceptive laser-evoked potentials (LEPs) or contact heat-evoked potentials (CHEPs) in patients with painful sensory polyneuropathy with the aim to determine which parameters of LEPs and CHEPs more reliably reflect IENF loss. A total of 96 patients and 35 healthy volunteers took part in the study. Based on clinical examination, nerve conduction tests, and quantitative sensory testing, we identified 52 patients with small-fiber neuropathy (SFN), 40 with mixed (small-fiber and large-fiber) neuropathy (MFN), and 4 who were excluded from the analysis because of no evidence of involvement of small fibers. The latency of the N2 was delayed for both LEPs and CHEPs in patients with MFN and for CHEPs only in patients with SFN. The amplitude of the vertex N2/P2 potential was similarly reduced in both types of neuropathy, but LEPs were more frequently absent than CHEPs in MFN patients (68% vs 40%). In general, latency and amplitude of LEPs and CHEPs were well correlated with IENF density. SFN patients were characterized by abnormal EPs and slightly decreased but morphologically abnormal IENF. MFN patients were characterized by frequently absent LEPs and CHEPs and a rather severe IENF loss. The correlation between nociceptive evoked potentials (laser-evoked potentials and contact heat-evoked potentials) and skin biopsy aids in the diagnosis of painful neuropathies.
The antibiotic linezolid is a ribosomal inhibitor with excellent efficacy. Although the administration period has been reduced to 28 days, side effects, usually of hematologic or neuropathic origin, are still reported due to secondary inhibition of mitochondrial protein synthesis. Susceptibility to linezolid toxicity remains unknown. Therefore, the objective of this study was to gain an understanding of clinical heterogeneity in response to identical linezolid exposures through exhaustive examination of the molecular basis of tissue-dependent mitotoxicity, consequent cell dysfunction, and the association of mitochondrial genetics with adverse effects of linezolid administered for the recommended period. Peripheral blood mononuclear cells (PBMC) and skin nerve fibers from 19 and 6 patients, respectively, were evaluated before and after a 28-day linezolid treatment in order to assess toxic effects on mitochondria and cells. Mitochondrial DNA haplotypes and single nucleotide polymorphisms (SNPs) in ribosomal sequences where linezolid binds to mitochondrial ribosomes were also analyzed to investigate their genetic contributions. We found that linezolid reduced mitochondrial protein levels, complex IV activity, and mitochondrial mass in PBMC and was associated with a trend toward an increase in the rate of apoptosis. In skin tissue, mitochondrial mass increased within nerve fibers, accompanied by subclinical axonal swelling. Mitochondrial haplogroup U, mutations in 12S rRNA, and the m.2706A¡G, m.3197T¡C, and m.3010G¡A polymorphisms in 16S rRNA showed a trend toward an association with increased mitochondrial and clinical adverse effects. We conclude that even when linezolid is administered for a shorter time than formerly, adverse effects are reported by 63% of patients. Linezolid exerts tissue-dependent mitotoxicity that is responsible for downstream cellular consequences (blood cell death and nerve fiber swelling), leading to adverse hematologic and peripheral nervous side effects. Multicentric studies should confirm genetic susceptibility in larger cohorts.
We quantified the immune histiocytic Langerhans cells (LCs) in skin biopsy samples of patients with distal small fiber neuropathy (SFN). Patients were divided according to the presence or absence of neuropathic pain (burning pain) assessed by a visual analogue scale (VAS). We studied 13 diabetic patients (pain-DSFN), 7 nondiabetic patients (pain-SFN) who reported relevant neuropathic pain (VAS ≥ 3), and 6 nondiabetic patients without neuropathic pain (no-pain-SFN). Using double immunofluorohistochemistry with the PGP 9.5 and the langerin/CD207, we quantified the intraepidermal nerve fibers density (IENFD) and LCs per square millimeter in the epidermis. A group of 10 skin samples from healthy subjects served as controls. Confocal analysis was performed to evaluate LC PGP 9.5-immunoreactivity. We found a mean value of 334.3LC/mm(2) in controls, 310.2LC/mm(2) in no-pain-SFN, 329.6LC/mm(2) in pain-SFN and 484.3LC/mm(2) in pain-DSFN (analysis of variance; P=.01). In patients, analysis of covariance adjusted by different covariables showed that the presence of diabetes (F=5.2, P=.03) was associated with an increased number of LC/mm(2). There was a negative correlation between the IENFD and the number of LCs (r(2)=-0.13, P=.03). No statistically significant differences were found among groups of subjects either for the co-localization or for the number of LCs that were PGP 9.5-immunoreactive (analysis of variance; P>.05). These results indicate that patients with neuropathic pain in the context of SFN, specially those who had diabetes (DSFN), had an increased number of LCs in the epidermis that may play a role in the generation or maintenance of neuropathic pain.
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