BACKGROUND: Distal symmetric polyneuropathy (DSP) is the most common variety of neuropathy. Since the evaluation of this disorder is not standardized, the available literature was reviewed to provide evidence-based guidelines regarding the role of laboratory and genetic tests for the assessment of DSP. METHODS: A literature review using MEDLINE, EMBASE, and Current Contents was performed to identify the best evidence regarding the evaluation of polyneuropathy published between 1980 and March 2007. Articles were classified according to a four-tiered level of evidence scheme and recommendations were based upon the level of evidence. RESULTS AND RECOMMENDATIONS: 1) Screening laboratory tests may be considered for all patients with polyneuropathy (Level C). Those tests that provide the highest yield of abnormality are blood glucose, serum B12 with metabolites (methylmalonic acid with or without homocysteine), and serum protein immunofixation electrophoresis (Level C). If there is no definite evidence of diabetes mellitus by routine testing of blood glucose, testing for impaired glucose tolerance may be considered in distal symmetric sensory polyneuropathy (Level C). 2) Genetic testing should be conducted for the accurate diagnosis and classification of hereditary neuropathies (Level A). Genetic testing may be considered in patients with cryptogenic polyneuropathy who exhibit a hereditary neuropathy phenotype (Level C). Initial genetic testing should be guided by the clinical phenotype, inheritance pattern, and electrodiagnostic features and should focus on the most common abnormalities which are CMT1A duplication/HNPP deletion, Cx32 (GJB1), and MFN2 mutation screening. There is insufficient evidence to determine the usefulness of routine genetic testing in patients with cryptogenic polyneuropathy who do not exhibit a hereditary neuropathy phenotype (Level U).
BACKGROUND: Distal symmetric polyneuropathy (DSP) is the most common variety of neuropathy. Since the evaluation of this disorder is not standardized, the available literature was reviewed to provide evidence-based guidelines regarding the role of laboratory and genetic tests for the assessment of DSP. METHODS: A literature review using MEDLINE, EMBASE, and Current Contents was performed to identify the best evidence regarding the evaluation of polyneuropathy published between 1980 and March 2007. Articles were classified according to a four-tiered level of evidence scheme and recommendations were based upon the level of evidence. RESULTS AND RECOMMENDATIONS: 1) Screening laboratory tests may be considered for all patients with polyneuropathy (Level C). Those tests that provide the highest yield of abnormality are blood glucose, serum B12 with metabolites (methylmalonic acid with or without homocysteine), and serum protein immunofixation electrophoresis (Level C). If there is no definite evidence of diabetes mellitus by routine testing of blood glucose, testing for impaired glucose tolerance may be considered in distal symmetric sensory polyneuropathy (Level C). 2) Genetic testing should be conducted for the accurate diagnosis and classification of hereditary neuropathies (Level A). Genetic testing may be considered in patients with cryptogenic polyneuropathy who exhibit a hereditary neuropathy phenotype (Level C). Initial genetic testing should be guided by the clinical phenotype, inheritance pattern, and electrodiagnostic features and should focus on the most common abnormalities which are CMT1A duplication/HNPP deletion, Cx32 (GJB1), and MFN2 mutation screening. There is insufficient evidence to determine the usefulness of routine genetic testing in patients with cryptogenic polyneuropathy who do not exhibit a hereditary neuropathy phenotype (Level U).
Authors: Claudia Gonzaga-Jauregui; Feng Zhang; Charles F Towne; Sat Dev Batish; James R Lupski Journal: Neurogenetics Date: 2010-06-09 Impact factor: 2.660
Authors: Heather M McLaughlin; Reiko Sakaguchi; William Giblin; Thomas E Wilson; Leslie Biesecker; James R Lupski; Kevin Talbot; Jeffery M Vance; Stephan Züchner; Yi-Chung Lee; Marina Kennerson; Ya-Ming Hou; Garth Nicholson; Anthony Antonellis Journal: Hum Mutat Date: 2011-11-09 Impact factor: 4.878
Authors: Anita S D Saporta; Stephanie L Sottile; Lindsey J Miller; Shawna M E Feely; Carly E Siskind; Michael E Shy Journal: Ann Neurol Date: 2011-01 Impact factor: 10.422
Authors: Brian C Callaghan; James F Burke; Ann Rodgers; Ryan McCammon; Kenneth M Langa; Eva L Feldman; Kevin A Kerber Journal: Neurol Clin Pract Date: 2013-10
Authors: Claudia Gonzaga-Jauregui; Timothy Lotze; Leila Jamal; Samantha Penney; Ian M Campbell; Davut Pehlivan; Jill V Hunter; Suzanne L Woodbury; Gerald Raymond; Adekunle M Adesina; Shalini N Jhangiani; Jeffrey G Reid; Donna M Muzny; Eric Boerwinkle; James R Lupski; Richard A Gibbs; Wojciech Wiszniewski Journal: JAMA Neurol Date: 2013-12 Impact factor: 18.302
Authors: Jenny L Davies; Janean K Engelstad; Linde E Gove; Linda K Linbo; Rickey E Carter; Christopher Lynch; Nathan P Staff; Christopher J Klein; P James B Dyck; David N Herrmann; Peter J Dyck Journal: Muscle Nerve Date: 2018-04-20 Impact factor: 3.217