- Email: [email protected]
Therapeutic efficacy of a case of pyruvate dehydrogenase complex deficiency monitored by localized proton magnetic resonance spectroscopy
Magnetic
Resonance
Imaging, Vol. 14, No. 1, pp. 129-133, 1996 Copyright 0 1996 Elsevier Science Inc. Printed in the USA. All rights reserved 0730-725X/96 $15.00 + .OO
0730-725X(95)02047-0
ELSEVIER
0 Case Report THERAPEUTIC EFFICACY OF A CASE OF PYRUVATE DEHYDROGENASE COMPLEX DEFICIENCY MONITORED BY LOCALIZED PROTON MAGNETIC RESONANCE SPECTROSCOPY MASAFUMI
HARADA, * MIKI TANOUCHI,* KAEKO ARM,* HIROMU HIROKAZU MIYOSHI, $ AND TOSHIAKI HASHIMOTO~
NISHITANI,”
Departments of *Radiology and tpediatrics, School of Medicine and SDepartment of Radiological Technology, School of Medical Science, University of Tokushima Kuramoto-cho, 3-18-15, Tokushima, Japan We experienced a case of pyruvate dehydrogenase deficiency observed by proton magnetic resonance spectroscopy(‘H MRS). This case was diagnosed as West syndrome by characteristic convulsion and the periodic hypsarrhythmia pattern of EEG. At the age of 11 months, the first examination of ‘H MRS revealed a high peak of lactate, and the high concentration of lactate and pyruvate was confirmed in sampled cerebrospinal fluid (CSF). Deficiency of pyruvate dehydrogenase complex was finally diagnosed by genetic examination. Dichloroacetate was administered to the patient as therapy. Decrease of lactate in the brain was found by ‘H MRS. Lactate and pyruvate in the CSF was also decreased. In accordance with the suspension of dichloroacetate, increase of lactate in the brain was detected and the convulsions reappeared. After readministration of dichloroacetate, the patient was almost symptom free and lactate in the brain and CSF had decreased to the normal extent. We considered that ‘H MRS provides useful information for screening metabolic disorders of infants and assessingthe efficacy of therapy. Keywords: ‘H MRS; West syndrome; Pyruvate; Lactate; Dichloroacetate.
by electroencephalograph (EEG). We diagnosed this patient as West syndrome due to the characteristic generalized myoclonic seizure and EEG pattern. The first examination by ‘H MRS and MRI was conducted on the patient at the age of 11 months when the spasm was suppressed by anticonvulsant for 1 wk. For the measurement of MRI, a short spin-echo sequence (TR = 500 ms, TE = 15 ms, acquisition = 3 times) and a double echo long spin-echo sequence (TR = 2000 ms, TE = 22 and 90 ms, acquisition = 1 time) were used. The sequence for ‘H MRS was PRESS (spin-echo sequence) and the measurement conditions were as follows: TR = 1500 ms, TE = 270 ms, sum of FIDs = 200, total measurement time = 5 min; Chess pulse was used for water suppression. The voxel of 3.4 ml was placed in the rt. parietal lobe. The spin-echo was sampled by 1024 complex data points with a sampling width of 500 Hz using a lowpass filter of 0.5 Hz. The raw FID
INTRODUCTION
West syndrome is an infantile spasm and includes various pathological disorders. Tuberous sclerosis is a frequent disease that occurs in West syndrome. We experienced a case of West syndrome resulting from a deficiency of pyruvate dehydrogenase complex (PDHC). In our case, ‘H MRS played an important role in the diagnosis of PDHC deficiency. Furthermore, the correct diagnosis led to efficacious therapy by administration of dichloroacetate(DCA). ‘H MRS was also used to assess the efficacy of therapy noninvasively. CASE
The gestation of this patient was normal and the Apgar score was 10 at birth. The patient had no history of hypo-oxygenation. Convulsion appeared from the age of 10 months and periodic hypsarrhythmia, which is a characteristic pattern of West syndrome, was found
RECENED
12/19/94;
ACCEPTED
Address correspondence to Masafumi Harada.
7113195. 129
II
Meetings
University of Michigan Medical School P.O. Box 1157 Ann Arbor, MI 48106-1157 Telephone: (313) 763-1400 FAX: (313) 936-1641
March 18-22, 1996 Ihilani Resort and Spa, Kapolei, Hawaii March 25-21, 1996 Thomas B. Turner Building, Baltimore,
Maryland
PET AND SPECT IMAGING IN CANCER DIAGNOSIS AND TREATMENT March lo-S,1996 GENERAL RADIOLOGY REVIEW Guest Quarters Suite Hotel Santa Monica, California
COURSE
The Department of Radiological Sciences of the University of California at Los Angeles will conduct a general radiology review course. The course will include the latest clinical information regarding breast imaging, musculoskeletal, gastrointestinal, genitourinary, head and neck, neuroradiology, and ultrasound. Fee: $420.00. 40 hours of Category I accreditation. For further information, please contact: Continuing Medical Education Office UCLA School of Medicine 10920 Wilshire Blvd., Ste. 1060 Los Angeles, CA 90024-6512 Telephone: (3 10) 794-2620 FAX: (3 10) 794-2624
March 15-16, 19% ADVANCES IN ABDOMINAL Copley Plaza Hotel, Boston
MRI 8z MRA
Sponsored by the Boston University School of Medicine. This course will provide a review of advances in abdominal and pelvic MRI. It is intended for radiologists with clinical experience in MRI who seek to apply newer MRI imaging techniques for applications in the abdomen and pelvis including magnetic resonance angiography and cholangiopancreatography. Technical background and clinical applications will be emphasized. The Course Director is Joseph T. Ferrucci, MD, and the Co-Director is E. Kent Yucci, MD. Tuition Fee: $475 for MDs, $350 for others. Credits: 14. For further information, please contact: Continuing Medical Education Boston University School of Medicine 80 E. Concord Street Boston, MA 02118 Telephone: (617) 638-4605 FAX: (617) 638-4905 e-mail: [email protected]
These courses are sponsored by the Johns Hopkins University School of Medicine. The Course Director is Henry N. Wagner, Jr., MD, for both courses, with Marc N. Coel, MD, of Queens Medical Center, in Hawaii. Oncologists, surgeons, internists, radiologists, and nuclear medicine physicians will discuss the problems they face in patients with cancer of the lung, breast, prostate, colon, ovary, thyroid, brain, and pancreas, as well as melanoma, neuroendocrine tumors, and leukemia. The solutions to these problems with new radiopharmaceuticals and techniques will be demonstrated. PET (positron emission tomography) and SPECT (single photon emission tomography) imaging in patients with cancer will be presented in a problemoriented format, which will be oriented toward the solution of specific patient problems. Registrants will learn which studies are best suited to each problem and how they can be applied in the cost-effective care of their patients with cancer. The Johns Hopkins University designates this continuing medical education activity for 17 credit hours in Category I of the Physician’s Recognition Award of the American Medical Association for the Hawaii course and 18.5 Category I credit hours for the Baltimore course. VOICE credit is pending for both courses. The fee is $495 for Physicians and $395 for Residents, Fellows, and Allied Health Professionals. For further information, please contact: Program Coordinator Johns Hopkins Medical Institutions Office of Continuing Medical Education, Turner Building 720 Rutland Avenue, Baltimore, MD 21205 Telephone: (410) 955-2959 or Julia W. Buchanan, Course Co-Director Telephone: (410) 955-8582 June 24-28, 1996 CONCEPTS OF MAGNETIC RESONANCE Kiawah Island, South Carolina Presented by the Departments of Radiology at Duke University and Stanford University Medical Centers. This course is designed to give the physician, physi-
Therapeutic efficacy of pyruvate dehydrogenase deficiency 0 M. HARADA
ET AL.
131
(a)
Fig. 1. MR images of the brain on this patient before any therapy. (a) T,-weighted image, (b) T2-weighted image. The high intensity in the white matter is shown.
132
Magnetic Resonance Imaging 0 Volume 14, Number 1, 1996 NAA
2.5
2.0 Chemical
NAA
I
1:5
1.0
3.0
2.5 Chemical
shift/ppm
1:5
1.0
shiftlppm (b)
(a)
NAA
Cho
3.0
2.0
2.5
2.0 Chemical
1:5
1.0
shiftlppm (cl
3.0
2.5
2.0 Chemical
1.5
1 .o
shiftlppm (d)
Fig. 2. (a) ‘H MR spectra of the brain on this patient before any therapy. Abbreviations are the same in the text. The high lactate peak is shown. (b) ‘H MR spectra of the brain during the first DCA therapy. Lactate is decreased. (c) ‘H MR spectra of the brain after the suspension of DCA therapy. The high peak of lactate was found again. (d) ‘H MR spectra of the brain during the second DCA therapy. Lactate is not easily confirmed.
of PDHC deficiency depends on the measurement of PDHC activity in cultured fibroblast cells and genetic examination.* In this case, pyruvate was not detected by ‘H MRS because the concentration of pyruvate was under the limit of sensitivity, but lactate was shown clearly even when the spasm was suppressed by anticonvulsant. It has been shown that repeated seizures cause increase of lactate in the brain,3 and we were not able to completely deny induction of lactate by seizures in our case as well. However, it was reported that the increase in extracellular lactate level is limited to the site of the seizure and depends on the neuron activity.4 We considered that lactate would be gradually washed out from the brain when the seizure was arrested, and the high peak of lactate in our case suggested the possibility of metabolic disorder and suppression of TCA cycles. There are some reports of ‘H MRS examinations that have shown an increase of lactate in the infantile brain,5-s and the reported diseases were hypo-oxygenation? mitochondrial encephalopathy (MELAS, etc.),6
malignant neoplasm,’ and hypoperfusion (infarction, etc.).8 Most cases of mitochondrial encephalopathy were caused by disorder of cytochrome C oxidase.9s10 To our knowledge, there are no reports of PDHC deficiency observed by ‘H MRS. Our first examination of ‘H MRS prompted a pediatrician to measure lactate and pyruvate, which led to a definitive diagnosis of PDHC deficiency. DCA was highly effective as therapy in our case and decrease of lactate was confirmed by assay of the CSF and ‘H MRS. ‘H MRS revealed the changes in lactate noninvasively and repeatedly. CSF sampling by lumbar puncture holds the high risk of nerve injury and infection in addition to incurring a high medical expense. We considered that ‘H MRS is more suitable for the follow-up study than CSF sampling, because of its noninvasive nature, and low risk and low cost (‘H MRS following MRI study requires only the electricity charge and there is no expense for patients in Japan). NAA is considered to be a neuron-specific substance, and the decrease of NAA suggests dysfunction
Therapeuticefficacyof pyruvate dehydrogenasedeficiency0 M. HARADA ET AL.
or delayed neuron development. Because it is difficult to obtain absolute values by ‘H MRS, we calculated the intensity ratios of NAA/Cho for the comparative evaluation of DCA therapy. Some other groups and ourselves have reported that the NAA/Cho ratio showed a change in neuronal development.“-l3 The NAA/Cho ratio increases remarkably until 2 yr of age and increases slowly after 2 yr until adult age. Compared to such a result, the NAA/Cho ratio in this patient was low and growth-dependent development was not found. Only the fourth ‘H MRS measurement after the second DCA therapy showed a slight increase of the NAA/Cho ratio. Although neuron development might have been induced by therapy, further long-term follow-up study will be required. MRI is indispensable for screening the cause of seizure and is usually conducted on all patients of epilepsy. We considered that ‘H MRS offers important information for diagnosis and therapy in the short measurement time following MRI study, and repeated CSF sampling for assessment of the therapeutic efficacy should be replaced by ‘H MRS. The combination of MRI and ‘H MRS study will contribute to clinical management of PDHC deficiency and other hyperlactemia. However, the differential diagnosis between PDHC deficiency and other hyperlactemia, especially mitochondrial encephalopathy, may be difficult. Acknowledgment-This work was supported in part by a Grant-inAid for Scientific Research (1994-1995, #06857059) from the Japanese Ministry of Education, Science, and Culture.
REFERENCES 1. Robin, B.H.; Mac Millan, H.; Benedict, R.R.; Sherwood, W.G. Variable clinical presentation in patients with defective E, component of pyruvate dehydrogenase complex. J. Pediatr. 111:525-533; 1989. 2. Naito, E.; Kuroda, Y.; Takeda, E. Detection of pyruvate metabolism disorders by culture of skin fibroblasts with dichloroacetate. Pediatr. Res. 23:561; 1988.
133
3. Perichard, J.W. Nuclear magnetic resonance spectroscopy off seizure states. Epilepsia 35 (Suppl. 6): S14-20; 1994. 4. During, M. J.; Fried, I.; Leone, P.; Katz, A.; Spencer, D.D. Direct measurement of extracellular lactate in the human hippocampus during spontaneous seizures. J. Neurochem. 62:2356-2361; 1994.
5. Waatt, J.S. Non-invasive assessmentof cerebral oxidative metabolism in the human newborn. J. R. Coll. Physicians Lond. 28:126-132; 1994. 6. Barkovich, A.J.; Good, W.V.; Koch, T.K.; Berg, B.O.
Mitochondrial disorders: Analysis of their clinical and 7.
8. 9.
10.
11.
12.
13.
imaging characteristics. Am. J. Neuroradiol. 14: 11191137; 1993. Heesters, M.A.; Kamman, R.L.; Mooyaart, E.L.; Go, K.G. Localized proton spectroscopy of inoperable brain gliomas, response to radiation therapy. J. Neurooncol. 17:27-35; 1993. Ford, C.C.; Griffey, R.H.; Matwiyoff, N.A.; Rosenberg, G.A. Multivoxel ‘H-MRS of stroke. Neurology 42:1408-1412; 1992. Fujii, T.; Ito, M.; Okuno, T.; Mutoh, K.; Nishikomori, R.; Mikawa, H. Complex I (reduced nicotinamideadenine dinucleotide-coenzyme Q reductase) deficiency in two patients with probable Leigh syndrome. J. Pediatr. 115:84-87; 1990. Reichmann, H.; Scheel, H.; Bier, B.; Ketelsen, U.P.; Zabransky, S. Cytochrome c oxidasedeficiency and longchain acyl coenzyme A dehydrogenase deficiency with Leigh’s subacute necrotizing encephalomyelopathy. Ann. Neurol. 31:107-109; 1992. Peden, C.J.; Cowan, EM.; Bryant, D.J.; Sargentoni, J.; Cox, I.J.; Menon, D.K.; Gadian, D.G.; Bell, J.D.; Dubowitz, L.M. Proton MR spectroscopy of the brain in infants. J. Comput. Assist.Tomogr. 14:886-894; 1990. Knaap,M.S.; Grond, J.; Rijen,P.C.;Faber, J.A.;Valk, J.; Willemse, K. Age-dependent changesin localized proton and phosphorus MR spectroscopy of the brain. Radiology 176:509-513; 1990. Hashimoto, T.; Miyazaki, M.; Fujii, E.; Harada, M.; Miyoshi, H.; Tanouchi, M.; Kuroda, Y. Developmental changes in proton MR spectroscopy of the brain. No To Hattatsu 26:26-31; 1994.
Resonance
Imaging, Vol. 14, No. 1, pp. 129-133, 1996 Copyright 0 1996 Elsevier Science Inc. Printed in the USA. All rights reserved 0730-725X/96 $15.00 + .OO
0730-725X(95)02047-0
ELSEVIER
0 Case Report THERAPEUTIC EFFICACY OF A CASE OF PYRUVATE DEHYDROGENASE COMPLEX DEFICIENCY MONITORED BY LOCALIZED PROTON MAGNETIC RESONANCE SPECTROSCOPY MASAFUMI
HARADA, * MIKI TANOUCHI,* KAEKO ARM,* HIROMU HIROKAZU MIYOSHI, $ AND TOSHIAKI HASHIMOTO~
NISHITANI,”
Departments of *Radiology and tpediatrics, School of Medicine and SDepartment of Radiological Technology, School of Medical Science, University of Tokushima Kuramoto-cho, 3-18-15, Tokushima, Japan We experienced a case of pyruvate dehydrogenase deficiency observed by proton magnetic resonance spectroscopy(‘H MRS). This case was diagnosed as West syndrome by characteristic convulsion and the periodic hypsarrhythmia pattern of EEG. At the age of 11 months, the first examination of ‘H MRS revealed a high peak of lactate, and the high concentration of lactate and pyruvate was confirmed in sampled cerebrospinal fluid (CSF). Deficiency of pyruvate dehydrogenase complex was finally diagnosed by genetic examination. Dichloroacetate was administered to the patient as therapy. Decrease of lactate in the brain was found by ‘H MRS. Lactate and pyruvate in the CSF was also decreased. In accordance with the suspension of dichloroacetate, increase of lactate in the brain was detected and the convulsions reappeared. After readministration of dichloroacetate, the patient was almost symptom free and lactate in the brain and CSF had decreased to the normal extent. We considered that ‘H MRS provides useful information for screening metabolic disorders of infants and assessingthe efficacy of therapy. Keywords: ‘H MRS; West syndrome; Pyruvate; Lactate; Dichloroacetate.
by electroencephalograph (EEG). We diagnosed this patient as West syndrome due to the characteristic generalized myoclonic seizure and EEG pattern. The first examination by ‘H MRS and MRI was conducted on the patient at the age of 11 months when the spasm was suppressed by anticonvulsant for 1 wk. For the measurement of MRI, a short spin-echo sequence (TR = 500 ms, TE = 15 ms, acquisition = 3 times) and a double echo long spin-echo sequence (TR = 2000 ms, TE = 22 and 90 ms, acquisition = 1 time) were used. The sequence for ‘H MRS was PRESS (spin-echo sequence) and the measurement conditions were as follows: TR = 1500 ms, TE = 270 ms, sum of FIDs = 200, total measurement time = 5 min; Chess pulse was used for water suppression. The voxel of 3.4 ml was placed in the rt. parietal lobe. The spin-echo was sampled by 1024 complex data points with a sampling width of 500 Hz using a lowpass filter of 0.5 Hz. The raw FID
INTRODUCTION
West syndrome is an infantile spasm and includes various pathological disorders. Tuberous sclerosis is a frequent disease that occurs in West syndrome. We experienced a case of West syndrome resulting from a deficiency of pyruvate dehydrogenase complex (PDHC). In our case, ‘H MRS played an important role in the diagnosis of PDHC deficiency. Furthermore, the correct diagnosis led to efficacious therapy by administration of dichloroacetate(DCA). ‘H MRS was also used to assess the efficacy of therapy noninvasively. CASE
The gestation of this patient was normal and the Apgar score was 10 at birth. The patient had no history of hypo-oxygenation. Convulsion appeared from the age of 10 months and periodic hypsarrhythmia, which is a characteristic pattern of West syndrome, was found
RECENED
12/19/94;
ACCEPTED
Address correspondence to Masafumi Harada.
7113195. 129
II
Meetings
University of Michigan Medical School P.O. Box 1157 Ann Arbor, MI 48106-1157 Telephone: (313) 763-1400 FAX: (313) 936-1641
March 18-22, 1996 Ihilani Resort and Spa, Kapolei, Hawaii March 25-21, 1996 Thomas B. Turner Building, Baltimore,
Maryland
PET AND SPECT IMAGING IN CANCER DIAGNOSIS AND TREATMENT March lo-S,1996 GENERAL RADIOLOGY REVIEW Guest Quarters Suite Hotel Santa Monica, California
COURSE
The Department of Radiological Sciences of the University of California at Los Angeles will conduct a general radiology review course. The course will include the latest clinical information regarding breast imaging, musculoskeletal, gastrointestinal, genitourinary, head and neck, neuroradiology, and ultrasound. Fee: $420.00. 40 hours of Category I accreditation. For further information, please contact: Continuing Medical Education Office UCLA School of Medicine 10920 Wilshire Blvd., Ste. 1060 Los Angeles, CA 90024-6512 Telephone: (3 10) 794-2620 FAX: (3 10) 794-2624
March 15-16, 19% ADVANCES IN ABDOMINAL Copley Plaza Hotel, Boston
MRI 8z MRA
Sponsored by the Boston University School of Medicine. This course will provide a review of advances in abdominal and pelvic MRI. It is intended for radiologists with clinical experience in MRI who seek to apply newer MRI imaging techniques for applications in the abdomen and pelvis including magnetic resonance angiography and cholangiopancreatography. Technical background and clinical applications will be emphasized. The Course Director is Joseph T. Ferrucci, MD, and the Co-Director is E. Kent Yucci, MD. Tuition Fee: $475 for MDs, $350 for others. Credits: 14. For further information, please contact: Continuing Medical Education Boston University School of Medicine 80 E. Concord Street Boston, MA 02118 Telephone: (617) 638-4605 FAX: (617) 638-4905 e-mail: [email protected]
These courses are sponsored by the Johns Hopkins University School of Medicine. The Course Director is Henry N. Wagner, Jr., MD, for both courses, with Marc N. Coel, MD, of Queens Medical Center, in Hawaii. Oncologists, surgeons, internists, radiologists, and nuclear medicine physicians will discuss the problems they face in patients with cancer of the lung, breast, prostate, colon, ovary, thyroid, brain, and pancreas, as well as melanoma, neuroendocrine tumors, and leukemia. The solutions to these problems with new radiopharmaceuticals and techniques will be demonstrated. PET (positron emission tomography) and SPECT (single photon emission tomography) imaging in patients with cancer will be presented in a problemoriented format, which will be oriented toward the solution of specific patient problems. Registrants will learn which studies are best suited to each problem and how they can be applied in the cost-effective care of their patients with cancer. The Johns Hopkins University designates this continuing medical education activity for 17 credit hours in Category I of the Physician’s Recognition Award of the American Medical Association for the Hawaii course and 18.5 Category I credit hours for the Baltimore course. VOICE credit is pending for both courses. The fee is $495 for Physicians and $395 for Residents, Fellows, and Allied Health Professionals. For further information, please contact: Program Coordinator Johns Hopkins Medical Institutions Office of Continuing Medical Education, Turner Building 720 Rutland Avenue, Baltimore, MD 21205 Telephone: (410) 955-2959 or Julia W. Buchanan, Course Co-Director Telephone: (410) 955-8582 June 24-28, 1996 CONCEPTS OF MAGNETIC RESONANCE Kiawah Island, South Carolina Presented by the Departments of Radiology at Duke University and Stanford University Medical Centers. This course is designed to give the physician, physi-
Therapeutic efficacy of pyruvate dehydrogenase deficiency 0 M. HARADA
ET AL.
131
(a)
Fig. 1. MR images of the brain on this patient before any therapy. (a) T,-weighted image, (b) T2-weighted image. The high intensity in the white matter is shown.
132
Magnetic Resonance Imaging 0 Volume 14, Number 1, 1996 NAA
2.5
2.0 Chemical
NAA
I
1:5
1.0
3.0
2.5 Chemical
shift/ppm
1:5
1.0
shiftlppm (b)
(a)
NAA
Cho
3.0
2.0
2.5
2.0 Chemical
1:5
1.0
shiftlppm (cl
3.0
2.5
2.0 Chemical
1.5
1 .o
shiftlppm (d)
Fig. 2. (a) ‘H MR spectra of the brain on this patient before any therapy. Abbreviations are the same in the text. The high lactate peak is shown. (b) ‘H MR spectra of the brain during the first DCA therapy. Lactate is decreased. (c) ‘H MR spectra of the brain after the suspension of DCA therapy. The high peak of lactate was found again. (d) ‘H MR spectra of the brain during the second DCA therapy. Lactate is not easily confirmed.
of PDHC deficiency depends on the measurement of PDHC activity in cultured fibroblast cells and genetic examination.* In this case, pyruvate was not detected by ‘H MRS because the concentration of pyruvate was under the limit of sensitivity, but lactate was shown clearly even when the spasm was suppressed by anticonvulsant. It has been shown that repeated seizures cause increase of lactate in the brain,3 and we were not able to completely deny induction of lactate by seizures in our case as well. However, it was reported that the increase in extracellular lactate level is limited to the site of the seizure and depends on the neuron activity.4 We considered that lactate would be gradually washed out from the brain when the seizure was arrested, and the high peak of lactate in our case suggested the possibility of metabolic disorder and suppression of TCA cycles. There are some reports of ‘H MRS examinations that have shown an increase of lactate in the infantile brain,5-s and the reported diseases were hypo-oxygenation? mitochondrial encephalopathy (MELAS, etc.),6
malignant neoplasm,’ and hypoperfusion (infarction, etc.).8 Most cases of mitochondrial encephalopathy were caused by disorder of cytochrome C oxidase.9s10 To our knowledge, there are no reports of PDHC deficiency observed by ‘H MRS. Our first examination of ‘H MRS prompted a pediatrician to measure lactate and pyruvate, which led to a definitive diagnosis of PDHC deficiency. DCA was highly effective as therapy in our case and decrease of lactate was confirmed by assay of the CSF and ‘H MRS. ‘H MRS revealed the changes in lactate noninvasively and repeatedly. CSF sampling by lumbar puncture holds the high risk of nerve injury and infection in addition to incurring a high medical expense. We considered that ‘H MRS is more suitable for the follow-up study than CSF sampling, because of its noninvasive nature, and low risk and low cost (‘H MRS following MRI study requires only the electricity charge and there is no expense for patients in Japan). NAA is considered to be a neuron-specific substance, and the decrease of NAA suggests dysfunction
Therapeuticefficacyof pyruvate dehydrogenasedeficiency0 M. HARADA ET AL.
or delayed neuron development. Because it is difficult to obtain absolute values by ‘H MRS, we calculated the intensity ratios of NAA/Cho for the comparative evaluation of DCA therapy. Some other groups and ourselves have reported that the NAA/Cho ratio showed a change in neuronal development.“-l3 The NAA/Cho ratio increases remarkably until 2 yr of age and increases slowly after 2 yr until adult age. Compared to such a result, the NAA/Cho ratio in this patient was low and growth-dependent development was not found. Only the fourth ‘H MRS measurement after the second DCA therapy showed a slight increase of the NAA/Cho ratio. Although neuron development might have been induced by therapy, further long-term follow-up study will be required. MRI is indispensable for screening the cause of seizure and is usually conducted on all patients of epilepsy. We considered that ‘H MRS offers important information for diagnosis and therapy in the short measurement time following MRI study, and repeated CSF sampling for assessment of the therapeutic efficacy should be replaced by ‘H MRS. The combination of MRI and ‘H MRS study will contribute to clinical management of PDHC deficiency and other hyperlactemia. However, the differential diagnosis between PDHC deficiency and other hyperlactemia, especially mitochondrial encephalopathy, may be difficult. Acknowledgment-This work was supported in part by a Grant-inAid for Scientific Research (1994-1995, #06857059) from the Japanese Ministry of Education, Science, and Culture.
REFERENCES 1. Robin, B.H.; Mac Millan, H.; Benedict, R.R.; Sherwood, W.G. Variable clinical presentation in patients with defective E, component of pyruvate dehydrogenase complex. J. Pediatr. 111:525-533; 1989. 2. Naito, E.; Kuroda, Y.; Takeda, E. Detection of pyruvate metabolism disorders by culture of skin fibroblasts with dichloroacetate. Pediatr. Res. 23:561; 1988.
133
3. Perichard, J.W. Nuclear magnetic resonance spectroscopy off seizure states. Epilepsia 35 (Suppl. 6): S14-20; 1994. 4. During, M. J.; Fried, I.; Leone, P.; Katz, A.; Spencer, D.D. Direct measurement of extracellular lactate in the human hippocampus during spontaneous seizures. J. Neurochem. 62:2356-2361; 1994.
5. Waatt, J.S. Non-invasive assessmentof cerebral oxidative metabolism in the human newborn. J. R. Coll. Physicians Lond. 28:126-132; 1994. 6. Barkovich, A.J.; Good, W.V.; Koch, T.K.; Berg, B.O.
Mitochondrial disorders: Analysis of their clinical and 7.
8. 9.
10.
11.
12.
13.
imaging characteristics. Am. J. Neuroradiol. 14: 11191137; 1993. Heesters, M.A.; Kamman, R.L.; Mooyaart, E.L.; Go, K.G. Localized proton spectroscopy of inoperable brain gliomas, response to radiation therapy. J. Neurooncol. 17:27-35; 1993. Ford, C.C.; Griffey, R.H.; Matwiyoff, N.A.; Rosenberg, G.A. Multivoxel ‘H-MRS of stroke. Neurology 42:1408-1412; 1992. Fujii, T.; Ito, M.; Okuno, T.; Mutoh, K.; Nishikomori, R.; Mikawa, H. Complex I (reduced nicotinamideadenine dinucleotide-coenzyme Q reductase) deficiency in two patients with probable Leigh syndrome. J. Pediatr. 115:84-87; 1990. Reichmann, H.; Scheel, H.; Bier, B.; Ketelsen, U.P.; Zabransky, S. Cytochrome c oxidasedeficiency and longchain acyl coenzyme A dehydrogenase deficiency with Leigh’s subacute necrotizing encephalomyelopathy. Ann. Neurol. 31:107-109; 1992. Peden, C.J.; Cowan, EM.; Bryant, D.J.; Sargentoni, J.; Cox, I.J.; Menon, D.K.; Gadian, D.G.; Bell, J.D.; Dubowitz, L.M. Proton MR spectroscopy of the brain in infants. J. Comput. Assist.Tomogr. 14:886-894; 1990. Knaap,M.S.; Grond, J.; Rijen,P.C.;Faber, J.A.;Valk, J.; Willemse, K. Age-dependent changesin localized proton and phosphorus MR spectroscopy of the brain. Radiology 176:509-513; 1990. Hashimoto, T.; Miyazaki, M.; Fujii, E.; Harada, M.; Miyoshi, H.; Tanouchi, M.; Kuroda, Y. Developmental changes in proton MR spectroscopy of the brain. No To Hattatsu 26:26-31; 1994.