Douglas A. Greene

A Practical Two-Step Quantitative Clinical and Electrophysiological Assessment for the Diagnosis and Staging of Diabetic Neuropathy

OBJECTIVE Early diagnosis of distal symmetric sensorimotor polyneuropathy, a common complication of diabetes, may decrease patient morbidity by allowing for potential therapeutic interventions. We have designed an outpatient program to facilitate diagnosis of diabetic neuropathy. RESEARCH DESIGN AND METHODS Patients are initially administered a brief questionnaire and screening examination, designated the Michigan Neuropathy Screening Instrument (MNSI). Diabetic neuropathy is confirmed in patients with a positive assessment by a quantitative neurological examination coupled with nerve conduction studies, designated the Michigan Diabetic Neuropathy Score (MDNS). In this study, 56 outpatients with confirmed type I or II diabetes were administered the standardized quantitative components required to diagnose and stage diabetic neuropathy according to the San Antonio Consensus Statement (1) and the Mayo Clinic protocol (2). These same patients were then assessed with the MNSI and the MDNS. RESULTS Of 29 patients with a clinical MNSI score > 2, 28 had neuropathy. Twenty-eight patients with an MDNS of ≥ 7 had neuropathy, while 21 non-neuropathic patients had a score ≤ 6. Of 35 patients with diabetic neuropathy, 34 had ≥ 2 abnormal nerve conductions. Twenty-one normal patients and one patient with neuropathy had ≤ 1 abnormal nerve conduction. CONCLUSIONS The results indicate that the MNSI is a good screening tool for diabetic neuropathy and that the MDNS coupled with nerve conductions provides a simple means to confirm this diagnosis.

Double‐blind randomized trial of tramadol for the treatment of the pain of diabetic neuropathy

Objective The objective of this study was to evaluate the efficacy and safety of tramadol in treating the pain of diabetic neuropathy. Background The pain of diabetic neuropathy is a major cause of morbidity among these patients and treatment, as with other small-fiber neuropathies, is often unsatisfactory. Tramadol is a centrally acting analgesic for use in treating moderate to moderately severe pain. Methods This multicenter, outpatient, randomized, double-blind, placebo-controlled, parallel-group study consisted of a washoutlscreening phase, during which all analgesics were discontinued, and a 42-day double-blind treatment phase. A total of 131 patients with painful diabetic neuropathy were treated with tramadol (n = 65) or placebo (n = 66) tramadol, which were administered as identical capsules in divided doses four times daily. The primary efficacy analysis compared the mean pain intensity scores in the tramadol and placebo groups obtained at day 42 of the study or at the time of discontinuation. Secondary efficacy assessments were the pain relief rating scores and a quality of life evaluation based on daily activities and sleep characteristics. Results Tramadol, at an average dosage of 210 mg/day, was significantly (p < 0.001) more effective than placebo for treating the pain of diabetic neuropathy. Patients in the tramadol group scored significantly better in physical (p = 0.02) and social functioning (p = 0.04) ratings than patients in the placebo group. No statistically significant treatment effects on sleep were identified. The most frequently occurring adverse events with tramadol were nausea, constipation, headache, and somnolence. Conclusions The results of this placebo-controlled trial showed that tramadol was effective and safe in treating the pain of diabetic neuropathy.

Regeneration and Repair of Myelinated Fibers in Sural-Nerve Biopsy Specimens from Patients with Diabetic Neuropathy Treated with Sorbinil

There is reason to believe that diabetic neuropathy may be related to the accumulation of sorbitol in nerve tissue through an aldose reductase pathway from glucose. Short-term treatment with aldose reductase inhibitors improves nerve conduction in subjects with diabetes, but the effects of long-term treatment on the neuropathologic changes of diabetic neuropathy are unknown. To determine whether more prolonged aldose reductase inhibition reverses the underlying lesions that accompany symptomatic diabetic peripheral polyneuropathy, we performed a randomized, placebo-controlled, double-blind trial of the investigational aldose reductase inhibitor sorbinil (250 mg per day). Sural-nerve biopsy specimens obtained at base line and after one year from 16 diabetic patients with neuropathy were analyzed morphometrically in detail and compared with selected electrophysiologic and clinical indexes. In contrast to patients who received placebo, the 10 sorbinil-treated patients had a decrease of 41.8 +/- 8.0 percent in nerve sorbitol content (P less than 0.01) and a 3.8-fold increase in the percentage of regenerating myelinated nerve fibers (P less than 0.001), reflected by a 33 percent increase in the number of myelinated fibers per unit of cross-sectional area of nerve (P = 0.04). They also had quantitative improvement in terms of the degree of paranodal demyelination, segmental demyelination, and myelin wrinkling. The increase in the number of fibers was accompanied by electrophysiologic and clinical evidence of improved nerve function. We conclude that sorbinil, as a metabolic intervention targeted against a specific biochemical consequence of hyperglycemia, can improve the neuropathologic lesions of diabetic neuropathy.

Complications: Neuropathy, Pathogenetic Considerations

The most common form of neuropathy associated with diabetes mellitus is distal symmetric sensorimotor polyneuropathy, often accompanied by autonomic neuropathy. This disorder is characterized by striking atrophy and loss of myelinated and unmyelinated fibers accompanied by Wallerian degeneration, segmental, and paranodal demyelination and blunted nerve fiber regeneration. In both humans and laboratory animals, this progressive nerve fiber damage and loss parallels the degree and/or duration of hyperglycemia. Several metabolic mechanisms have been proposed to explain the relationship between the extent and severity of hyperglycemia and the development of diabetic neuropathy. One mechanism, activation of the polyol pathway by glucose via AR, is a prominent metabolic feature of diabetic rat peripheral nerve, where it promotes sorbitol and fructose accumulation, myo-inositol depletion, and slowing of nerve conduction by alteration of neural Na+-K+-ATPase activity or perturbation of normal physiological osmoregulatory mechanisms. ARIs, which normalize nerve myo-inositol and nerve conduction slowing, are currently the focus of clinical trials. Other specific metabolic abnormalities that may play a role in the pathogenesis of diabetic neuropathy include abnormal lipid or amino acid metabolism, superoxide radical formation, protein glycation, or potential blunting of normal neurotrophic responses. Metabolic dysfunction in diabetic nerve is accompanied by vascular insufficiency and nerve hypoxia that may contribute to nerve fiber loss and damage. Although major questions about the pathogenesis of diabetic neuropathy remain unanswered and require further intense investigation, significant recent progress is pushing us into the future and likely constitutes only the first of many therapies directed against one or more elements of the complex pathogenetic process responsible for diabetic neuropathy.

Effect of aldose reductase inhibition on nerve conduction and morphometry in diabetic neuropathy

Objective: To determine whether the aldose reductase inhibitor (ARI) zenarestat improves nerve conduction velocity (NCV) and nerve morphology in diabetic peripheral polyneuropathy (DPN). Methods: A 52-week, randomized, placebo-controlled, double-blinded, multiple-dose, clinical trial with the ARI zenarestat was conducted in patients with mild to moderate DPN. NCV was measured at baseline and study end. Contralateral sural nerve biopsies were obtained at 6 weeks and at the study’s end for nerve sorbitol measurement and computer-assisted light morphometry to determine myelinated nerve fiber density (number of fibers/mm2 cross-sectional area) in serial bilateral sural nerve biopsies. Results: Dose-dependent increments in sural nerve zenarestat level and sorbitol suppression were accompanied by significant improvement in NCV. In a secondary analysis, zenarestat doses producing >80% sorbitol suppression were associated with a significant increase in the density of small-diameter (<5 μm) sural nerve myelinated fibers. Conclusions: Aldose reductase pathway inhibition improves NCV slowing and small myelinated nerve fiber loss in DPN in humans, but >80% suppression of nerve sorbitol content is required. Thus, even low residual levels of aldose reductase activity may be neurotoxic in diabetes, and potent ARIs such as zenarestat may be required to stop or reverse progression of DPN.

Glucose-induced oxidative stress and programmed cell death in diabetic neuropathy

The Diabetes Control and Complications Trial (DCCT) established the importance of hyperglyemia and other consequences of insulin deficiency in the pathogenesis of diabetic neuropathy, but the precise mechanisms by which metabolic alterations produce peripheral nerve fiber damage and loss remain unclear. Emerging data from human and animal studies suggest that glucose-derived oxidative stress may play a central role, linking together many of the other currently invoked pathogenetic mechanisms such as the aldose reductase and glycation pathways, vascular dysfunction, and impaired neurotrophic support. These relationships suggest combinations of pharmacological interventions that may synergistically protect the peripheral nervous system (PNS) against the metabolic derangements of diabetes mellitus.

The linked roles of nitric oxide, aldose reductase and, (Na+,K+)-ATPase in the slowing of nerve conduction in the streptozotocin diabetic rat.

Metabolic and vascular factors have been invoked in the pathogenesis of diabetic neuropathy but their interrelationships are poorly understood. Both aldose reductase inhibitors and vasodilators improve nerve conduction velocity, blood flow, and (Na+,K+)-ATPase activity in the streptozotocin diabetic rat, implying a metabolic-vascular interaction. NADPH is an obligate cofactor for both aldose reductase and nitric oxide synthase such that activation of aldose reductase by hyperglycemia could limit nitric oxide synthesis by cofactor competition, producing vasoconstriction, ischemia, and slowing of nerve conduction. In accordance with this construct, N-nitro-L-arginine methyl ester, a competitive inhibitor of nitric oxide synthase reversed the increased nerve conduction velocity afforded by aldose reductase inhibitor treatment in the acutely diabetic rat without affecting the attendant correction of nerve sorbitol and myo-inositol. With prolonged administration, N-nitro-L-arginine methyl ester fully reproduced the nerve conduction slowing and (Na+,K+)-ATPase impairment characteristic of diabetes. Thus the aldose reductase-inhibitor-sensitive component of conduction slowing and the reduced (Na+,K+)-ATPase activity in the diabetic rat may reflect in part impaired nitric oxide activity, thus comprising a dual metabolic-ischemic pathogenesis.

Glucose-induced Alterations in Nerve Metabolism: Current Perspective on the Pathogenesis of Diabetic Neuropathy and Future Directions for Research and Therapy

Recent animal and in vitro studies have identified several interrelated metabolic abnormalities in diabetic nerve that are attributable to elevated ambient glucose concentrations. In combination, these metabolic changes may induce a variety of biochemical and biophysical alterations in peripheral nerve that are highly relevant to the pathogenesis of diabetic neuropathy. This article reviews the current status of several of these metabolic defects and describes ways in which their interaction could lead to pathogenetically important changes in nerve metabolism, function, and structure. Areas of related future research are also discussed.

Are Disturbances of Sorbitol, Phosphoinositide, and Na+-K+-ATPase Regulation Involved in Pathogenesis of Diabetic Neuropathy?

Alterations in myo-inositol and phosphoinositide metabolism, induced by hyperglycemia and prevented by aldose reductase inhibitors, are implicated in impaired Na+-K+-ATPase regulation in peripheral nerve and other tissues prone to diabetic complications by an increasing range of scientific observations. However, the precise role of these related metabolic derangements in various stages of clinical complications is complex. For instance, it appears that these biochemical defects may play a role not only in the initiation of diabetic neuropathy but also in its later progression. Therefore, full appreciation of the potential pathogenetic role of altered phosphoinositide metabolism in diabetic complications requires detailed studies of both the earliest and the more mature stages of these disease processes.

An aldose reductase inhibitor reverses early diabetes-induced changes in peripheral nerve function, metabolism, and antioxidative defense

Aldose reductase inhibitors (ARIs) prevent peripheral nerve dysfunction and morphological abnormalities in diabetic animal models. However, some experimental intervention studies and clinical trials of ARIs on diabetic neuropathy appeared disappointing because of either 1) their inadequate design and, in particular, insufficient correction of the sorbitol pathway activity or 2) the inability to reverse established functional and metabolic deficits of diabetic neuropathy by AR inhibition in general. We evaluated whether diabetes‐induced changes in nerve function, metabolism, and antioxidative defense are corrected by the dose of ARI (sorbinil, 65 mg/kg/d in the diet), resulting in complete inhibition of increased sorbitol pathway activity. The groups included control rats and streptozotocin‐diabetic rats treated with/without ARI for 2 weeks after 4 weeks of untreated diabetes. ARI treatment corrected diabetes‐induced nerve functional changes; that is, decrease in endoneurial nutritive blood flow, motor and sensory nerve conduction velocities, and metabolic abnormalities (i.e., mitochondrial and cytosolic NAD+/NADH redox imbalances and energy deficiency). ARI restored nerve concentrations of two major non‐enzymatic antioxidants, reduced glutathione (GSH) and ascorbate, and completely arrested diabetes‐induced lipid peroxidation. In conclusion, treatment with adequate doses of ARIs (that is, doses that completely inhibit increased sorbitol pathway activity) is an effective approach for reversal of, at least, early diabetic neuropathy.