Copper Histidine Therapy for Menkes Diseases
Early Copper Histidine Therapy in Menkes Disease
2 other identifiers
interventional
60
1 country
1
Brief Summary
Menkes Disease is a genetic disorder affecting the metabolism of copper. Patient with this disease are both physically and mentally retarded. Menkes disease is usually first detected in the first 2-3 months of life. Infant males born with the disease fail to thrive, experience hypothermia, have delayed development, and experience seizures. These infants also have characteristic physical features such as changes of their hair and face. Females may also have changes in hair and skin color, but rarely have significant medical problems. Appropriate treatment of Menkes Disease requires that the disease be diagnosed early and treatment started before irreversible brain damage occurs. The aim of treatment is to bypass the normal route of absorption of copper through the gastrointestinal tract. Copper must then be delivered to brain cells and be available for use by enzymes. Copper histidine is a copper replacement that can be injected directly into the body to avoid absorption through the gastrointestinal tract. However, studies have shown the genetic abnormalities causing Menkes disease cannot simply be corrected by copper replacement injections. The genetic abnormality causing Menkes disease can vary in its severity. Patients with a genetic abnormality that may still permit some production of the enzymes required to process copper may receive benefit from early treatment with copper replacement. However, patients with severe abnormalities of the genes responsible for copper metabolism may receive no benefit from copper replacement. The purpose of this study is to continue to evaluate the effects of early copper histidine in Menkes disease patients and to correlate specific molecular defects with responses to treatment.
Trial Health
Trial Health Score
Automated assessment based on enrollment pace, timeline, and geographic reach
participants targeted
Target at P75+ for phase_1
Started Jun 1990
Longer than P75 for phase_1
1 active site
Health score is calculated from publicly available data and should be used for screening purposes only.
Trial Relationships
Click on a node to explore related trials.
Study Timeline
Key milestones and dates
Study Start
First participant enrolled
June 1, 1990
CompletedFirst Submitted
Initial submission to the registry
November 3, 1999
CompletedFirst Posted
Study publicly available on registry
November 4, 1999
CompletedPrimary Completion
Last participant's last visit for primary outcome
July 1, 2012
CompletedStudy Completion
Last participant's last visit for all outcomes
July 1, 2013
CompletedResults Posted
Study results publicly available
October 30, 2015
CompletedOctober 30, 2015
September 1, 2015
22.1 years
November 3, 1999
August 5, 2014
September 29, 2015
Conditions
Keywords
Outcome Measures
Primary Outcomes (4)
Gross Motor Development at 36 Mos of Age or at Death (Mos)
This was measured based on the Denver Developmental Screening Test (DDST) I or II for age-appropriate gross motor development in apparently normal healthy subjects at specific ages (in months). The DDST employs a grid to assess expected developmental milestones in relation to chronologic age.
36 months or death
Fine Motor Adaptive Development at 36 Mos of Age or at Death (Mos)
This was measured based on the Denver Developmental Screening Test (DDST) I or II for age-appropriate fine motor development in apparently normal healthy subjects at specific ages (in months). The DDST employs a grid to assess expected developmental milestones in relation to chronologic age.
36 months or death
Personal-Social Development at 36 Mos of Age or at Death (Mos)
This was measured based on the Denver Developmental Screening Test (DDST) I or II for age-appropriate personal-social development in apparently normal healthy subjects at specific ages (in months). The DDST employs a grid to assess expected developmental milestones in relation to chronologic age.
36 months or death
Language Development at 36 Mos of Age or at Death (Mos)
This was measured based on the Denver Developmental Screening Test (DDST) I or II for age-appropriate language development in apparently normal healthy subjects at specific ages (in months). The DDST employs a grid to assess expected developmental milestones in relation to chronologic age.
36 months or death
Secondary Outcomes (3)
Somatic Growth Percentiles at 3 Years of Age (or at Age of Death) - Weight Percentile
36 months or death
Somatic Growth Percentiles at 3 Years of Age (or at Age of Death) - Length Percentile
36 months or death
Somatic Growth Percentiles at 3 Years of Age (or at Age of Death) - Head Circumference Percentile
36 months or death
Study Arms (1)
Copper histidine
EXPERIMENTALInterventions
Eligibility Criteria
You may qualify if:
- Newborn infants in whom Menkes disease is confirmed on biochemical or molecular grounds and in whom no neurological symptoms are present are eligible for enrollment in this study.
You may not qualify if:
- Newly identified patients classified as symptomatic at the time of diagnosis, and affected individuals with mild phenotypes are not currently eligible for this clinical trial.
Contact the study team to confirm eligibility.
Sponsors & Collaborators
Study Sites (1)
National Institutes of Health Clinical Center, 9000 Rockville Pike
Bethesda, Maryland, 20892, United States
Related Publications (15)
Kaler SG, Buist NR, Holmes CS, Goldstein DS, Miller RC, Gahl WA. Early copper therapy in classic Menkes disease patients with a novel splicing mutation. Ann Neurol. 1995 Dec;38(6):921-8. doi: 10.1002/ana.410380613.
PMID: 8526465RESULTKaler SG, Holmes CS, Goldstein DS, Tang J, Godwin SC, Donsante A, Liew CJ, Sato S, Patronas N. Neonatal diagnosis and treatment of Menkes disease. N Engl J Med. 2008 Feb 7;358(6):605-14. doi: 10.1056/NEJMoa070613.
PMID: 18256395RESULTKaler SG, Gahl WA, Berry SA, Holmes CS, Goldstein DS. Predictive value of plasma catecholamine levels in neonatal detection of Menkes disease. J Inherit Metab Dis. 1993;16(5):907-8. doi: 10.1007/BF00714295. No abstract available.
PMID: 8295415RESULTKaler SG, Westman JA, Bernes SM, Elsayed AM, Bowe CM, Freeman KL, Wu CD, Wallach MT. Gastrointestinal hemorrhage associated with gastric polyps in Menkes disease. J Pediatr. 1993 Jan;122(1):93-5. doi: 10.1016/s0022-3476(05)83496-1.
PMID: 8419622RESULTGrange DK, Kaler SG, Albers GM, Petterchak JA, Thorpe CM, DeMello DE. Severe bilateral panlobular emphysema and pulmonary arterial hypoplasia: unusual manifestations of Menkes disease. Am J Med Genet A. 2005 Dec 1;139A(2):151-5. doi: 10.1002/ajmg.a.31001.
PMID: 16278898RESULTPrice DJ, Ravindranath T, Kaler SG. Internal jugular phlebectasia in Menkes disease. Int J Pediatr Otorhinolaryngol. 2007 Jul;71(7):1145-8. doi: 10.1016/j.ijporl.2007.02.021. Epub 2007 May 4.
PMID: 17482283RESULTHicks JD, Donsante A, Pierson TM, Gillespie MJ, Chou DE, Kaler SG. Increased frequency of congenital heart defects in Menkes disease. Clin Dysmorphol. 2012 Apr;21(2):59-63. doi: 10.1097/MCD.0b013e32834ea52b.
PMID: 22134099RESULTKaler SG, Gallo LK, Proud VK, Percy AK, Mark Y, Segal NA, Goldstein DS, Holmes CS, Gahl WA. Occipital horn syndrome and a mild Menkes phenotype associated with splice site mutations at the MNK locus. Nat Genet. 1994 Oct;8(2):195-202. doi: 10.1038/ng1094-195.
PMID: 7842019RESULTLiu PC, Chen YW, Centeno JA, Quezado M, Lem K, Kaler SG. Downregulation of myelination, energy, and translational genes in Menkes disease brain. Mol Genet Metab. 2005 Aug;85(4):291-300. doi: 10.1016/j.ymgme.2005.04.007.
PMID: 15923132RESULTKaler SG, Das S, Levinson B, Goldstein DS, Holmes CS, Patronas NJ, Packman S, Gahl WA. Successful early copper therapy in Menkes disease associated with a mutant transcript containing a small In-frame deletion. Biochem Mol Med. 1996 Feb;57(1):37-46. doi: 10.1006/bmme.1996.0007.
PMID: 8812725RESULTTang J, Donsante A, Desai V, Patronas N, Kaler SG. Clinical outcomes in Menkes disease patients with a copper-responsive ATP7A mutation, G727R. Mol Genet Metab. 2008 Nov;95(3):174-81. doi: 10.1016/j.ymgme.2008.06.015. Epub 2008 Aug 26.
PMID: 18752978RESULTKaler SG, Tang J, Donsante A, Kaneski CR. Translational read-through of a nonsense mutation in ATP7A impacts treatment outcome in Menkes disease. Ann Neurol. 2009 Jan;65(1):108-13. doi: 10.1002/ana.21576.
PMID: 19194885RESULTKaler SG, Liew CJ, Donsante A, Hicks JD, Sato S, Greenfield JC. Molecular correlates of epilepsy in early diagnosed and treated Menkes disease. J Inherit Metab Dis. 2010 Oct;33(5):583-9. doi: 10.1007/s10545-010-9118-2. Epub 2010 Jul 21.
PMID: 20652413RESULTDesai V, Donsante A, Swoboda KJ, Martensen M, Thompson J, Kaler SG. Favorably skewed X-inactivation accounts for neurological sparing in female carriers of Menkes disease. Clin Genet. 2011 Feb;79(2):176-82. doi: 10.1111/j.1399-0004.2010.01451.x.
PMID: 20497190RESULTKaler SG. Neurodevelopment and brain growth in classic Menkes disease is influenced by age and symptomatology at initiation of copper treatment. J Trace Elem Med Biol. 2014 Oct;28(4):427-30. doi: 10.1016/j.jtemb.2014.08.008. Epub 2014 Aug 28.
PMID: 25281031RESULT
Related Links
MeSH Terms
Conditions
Interventions
Condition Hierarchy (Ancestors)
Results Point of Contact
- Title
- Kaler, Stephen G
- Organization
- National Institute of Child Health and Human Development
Study Officials
- PRINCIPAL INVESTIGATOR
Stephen G Kaler, M.D.
Eunice Kennedy Shriver National Institute of Child Health and Human Development (NICHD)
Publication Agreements
- PI is Sponsor Employee
- Yes
- Restrictive Agreement
- No
Study Design
- Study Type
- interventional
- Phase
- phase 1
- Allocation
- NA
- Masking
- NONE
- Purpose
- TREATMENT
- Intervention Model
- SINGLE GROUP
- Sponsor Type
- NIH
- Responsible Party
- SPONSOR
Study Record Dates
First Submitted
November 3, 1999
First Posted
November 4, 1999
Study Start
June 1, 1990
Primary Completion
July 1, 2012
Study Completion
July 1, 2013
Last Updated
October 30, 2015
Results First Posted
October 30, 2015
Record last verified: 2015-09