AUTHOR AND EDITOR INFORMATION

Section 1 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

INTRODUCTION

Section 2 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Background

Secondary hyperparathyroidism is characterized by pronounced parathyroid gland hyperplasia resulting from end-organ resistance to parathyroid hormone (PTH). The consequent hypersecretion of PTH depresses calcium levels. The most important cause of secondary hyperparathyroidism is chronic renal insufficiency.

The clinical manifestation of secondary hyperparathyroidism includes bone and joint pain, as well as limb deformities. The characteristics of the disease that are displayed radiologically in the skeleton are similar to those of primary hyperparathyroidism. (See also the eMedicine articles Hyperparathyroidism [in the Pediatrics section], Hyperparathyroidism [in the Emergency Medicine section], Hyperparathyroidism [in the Otolaryngology and Facial Plastic Surgery section], Hyperparathyroidism [in the Endocrinology section], and Hyperparathyroidism, Primary.)

Pathophysiology

Secondary hyperparathyroidism is often accompanied by pronounced hyperplasia of the parathyroid gland's chief cells. All 4 glands are usually affected by this hyperplasia, but in some cases, for reasons that remain obscure, only 1 or 2 are involved. A true adenoma may develop, but only in rare instances. Histologically, islands of oxyphils are often present, and hyperplastic cells usually replace the fat.

Secondary hyperparathyroidism most commonly results from chronic renal disease, which can develop in hemodialysis patients. Chronic hypocalcemia and secondary hyperparathyroidism can also be products of pseudohypoparathyroidism, vitamin D deficiency, and intestinal malabsorption syndromes that are characterized by inadequate vitamin D and calcium absorption.

Long-term furosemide therapy in infants, the use of oral contraceptives, and idiopathic hypercalciuria are other, highly unusual causes of secondary hyperparathyroidism. (See also Management of Secondary Hyperparathyroidism in CKD Stages 3 and 4: Is it Time for a Change?, Parathyroid Hormone Assays: Monitoring Therapeutic Approaches to Secondary Hyperparathyroidism, Bone Growth During Daily Or Intermittent Calcitriol Treatment During Renal Failure With Advanced Secondary Hyperparathyroidism, Calcimimetics for Secondary Hyperparathyroidism in Chronic Kidney Disease Patients, and Vitamin D Metabolism in the Pathogenesis of Renal Osteodystrophy and Secondary Hyperparathyroidism, on Medscape.)

In most cases, the sequence of events leading to the development of PTH hypersecretion is any long-standing osteomalacia. The most common cause is chronic renal insufficiency, such as that in renal polycystic disease or chronic pyelonephritis. Chronic renal insufficiency is accompanied by several biochemical abnormalities, including diminished urinary excretion of phosphate with consequent elevation of serum phosphate levels and elevation in the levels of the calcium-phosphate product. Serum calcium levels tend to be normal, but they may be marginally reduced. The alkaline phosphates are almost always elevated. The hyperphosphatemia and damaged renal parenchyma lead to a reduction of renal production of 1,25-dihydroxycholecalciferol (1,25-DHCC). Decreased intestinal absorption of vitamin D3 follows, impairing the mobilization of calcium from the bones as a result of PTH resistance.

Aluminum accumulates in patients undergoing long-term hemodialysis. This accumulation causes dementia and, owing to a poorly understood mechanism, also prevents the mineralization of osteoid. The bone changes that may occur with aluminum toxicity include osteopenia, fractures, and osteomalacia. An early sign of aluminum toxicity is periosteal new-bone formation along the shafts of long bones and at the pelvic inlet. Low or normal serum calcium levels usually indicate pre-existing osteomalacia. A markedly elevated alkaline phosphatase level typically accompanies skeletal disease.

The most common presentation of renal osteodystrophy is a combination of osteomalacia, secondary hyperparathyroidism, and a varying degree of osteosclerosis. Several pathologic changes occur in association with renal osteodystrophy. These include lacunar bone resorption, fibrous replacement of the marrow following hemorrhage, necrosis, and brown tumors caused by intense osteoclastic activity in some areas. The skeletal changes in children are typically the same as those occurring in rickets; they affect the epiphyseal plate, as demonstrated through the use of undecalcified preparations. (See also the eMedicine article Osteomalacia and Renal Osteodystrophy.) 

There is considerable speculation as to why secondary hyperparathyroidism is frequently accompanied by osteosclerosis. Two possibilities are as follows: 

• Excessive PTH directly acts as an anabolic agent on the bone, causing osteosclerosis.
• A significant increase in the formation of woven bone contributes to the osteosclerotic appearance.

Hyperuricemia is often found with chronic renal insufficiency, which in rare instances manifests as gout. Another complication of chronic renal disease is oxalosis, in which oxalate deposition occurs in growth plates, metaphyses, and intervertebral plates.

With appropriate treatment, such as renal transplantation or vitamin D supplementation, the changes related to secondary hyperparathyroidism may resolve. Long-standing secondary hyperparathyroidism associated with extensive glandular hyperplasia may not revert. In the patients with this condition, the presence of tertiary hyperparathyroidism should be considered.

The tertiary condition develops in patients with long-standing secondary hyperparathyroidism, which stimulates the growth of an autonomous adenoma. A clue to the diagnosis of tertiary hyperparathyroidism is the presence of intractable hypercalcemia and/or an inability to control osteomalacia despite vitamin D therapy.

Frequency

United States

Renal osteodystrophy is present in almost all patients with chronic advanced renal failure.

Mortality/Morbidity

Renal osteodystrophy progresses despite intermittent hemodialysis. Bone pain from renal osteodystrophy can slowly progress until the patient is bedridden. In some patients, secondary hyperparathyroidism responds to the control of phosphate and calcium levels, as well as to vitamin D therapy. Such measures may lead to improved homeostasis of calcium and phosphorus levels and may reverse the symptoms of bone pain and PTH suppression. In some patients, the disease responds to renal transplantation. However, not all cases respond to these measures, and parathyroidectomy may be required.

Race

No racial predilection exists.

Sex

Males and females are affected equally.

Age

Secondary hyperparathyroidism is more common in children than in adults.

Clinical Details

Features of renal failure or other conditions are associated with secondary hyperparathyroidism. Symptoms associated with renal osteodystrophy usually appear with advanced renal failure, although biochemical abnormalities appear early and should prompt treatment to prevent irreversible bone changes.

Bone and joint pains may develop and slowly progress until the patient is bedridden. The pain is usually vague and is commonly located in the lower back, hips, knees, and legs. Severe lower back pain occurs as a result of a collapsed vertebral body, and a spontaneous rib fracture can cause sharp chest pain. Joint pain may also occur as a result of the periarticular deposition of hydroxyapatite crystals; this pain particularly occurs in marked hyperphosphatemia. Rarely, avascular necrosis of the femoral head may occur in association with renal osteodystrophy, causing pain and limping.

Muscular weakness is usually proximal; it progresses slowly and usually responds to vitamin D therapy. Pruritus may occur as a result of calcium deposition in renal insufficiency, particularly in patients with severe hyperparathyroidism. In children with azotemia, skeletal deformities are common. These deformities include bowing of the tibia and femur, as well as deformity resulting from a slipped femoral epiphysis. In adult patients with chronic renal failure, particularly those with predominant osteomalacia, lumbar kyphoscoliosis and deformity of the thoracic cage may be present.

Growth reduction is generally observed in young children before and during hemodialysis. Vascular calcification and peripheral ischemic necrosis may cause violaceous discoloration of the skin of the fingers and toes. Sometimes, associated ulceration and scar formation are present. An association with mitral and aortic stenosis has been described.

Preferred Examination

Radiographs are the mainstays of the radiologic diagnosis of secondary hyperparathyroidism, because the predominant changes are skeletal, with abnormal calcifications at various sites; these calcifications are well depicted on conventional radiographs.¹

The changes observed on radionuclide studies are not consistent or specific. The diagnosis is made or incidentally suggested because radionuclide investigation is initially performed for the evaluation of conditions other than secondary hyperparathyroidism, such as bone pain.

Similarly, computed tomography (CT) scan findings are usually incidental, and CT scanning is not specifically performed for the diagnosis of secondary hyperparathyroidism. Ultrasonography may be useful in evaluating enlarged parathyroid glands.

Limitations of Techniques

Subperiosteal erosions, periosteal reactions, and several other osseous abnormalities in secondary hyperparathyroidism are not specific for the disease and may occur in other skeletal disorders or conditions, as well as in primary hyperparathyroidism. The exact sensitivity of plain radiography in the diagnosis of secondary hyperparathyroidism is not known, but the fact that biochemical abnormalities may precede radiologic change is well recognized.

Radionuclide findings are not specific, and pure osteomalacia and primary hyperparathyroidism can result in an appearance similar to that of secondary hyperparathyroidism. As with radiographic findings, CT scan depictions of the osseous changes are nonspecific. Ultrasonography may not always show hyperplasia of the parathyroid glands.

DIFFERENTIALS

Section 3 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Other Problems to Be Considered

Familial hyperparathyroidism
Tertiary hyperparathyroidism
Conditions involving ectopic parathyroid production (eg, bronchogenic carcinoma, renal cell carcinoma)
Thymoma as a cause of a true ectopic hyperparathyroidism
Multiple endocrine neoplasia type IIA
Other metabolic bone diseases
Osteoarthritis, secondary
Reiter syndrome, musculoskeletal

RADIOGRAPH

Section 4 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Findings

Radiography is the most important investigational modality in the diagnosis of secondary hyperparathyroidism; radiographs may show several skeletal abnormalities. The radiologic features of secondary hyperparathyroidism are similar to those of the primary form of the disease. The combination of 2 pathologic processes of hyperparathyroidism and osteomalacia and/or rickets is responsible for the osseous abnormalities in renal osteodystrophy.²

In children, widening of the growth plates of the long bones may be present, with irregularity of the metaphyseal margins and disorganization of the growth plate, which is indicative of advanced rickets. These changes of gross disease have been likened to the rotting of a wooden post at its stem.

Severe osteopenia may be complicated by pathologic fractures. Epiphyseal displacement of metaphyseal fractures may be present; the most commonly involved sites include the distal radius, the proximal humerus, the distal femur, and the heads of metacarpal and metatarsal bones.

Skeletal maturation may be retarded. Lateral Blount disease may occur as a result of lateral angulation of the proximal tibial epiphysis and genu valgum. Jaw enlargement has been described.

In adults, subperiosteal bone resorption characteristically affects the phalangeal tufts, the radial aspect of the proximal and middle phalanges of the fingers, the metatarsals, the rib margins, the lamina dura, and the medial margins of the proximal humerus, femur, and tibia.

Intracortical bone resorption, which results in a lacy appearance, involves the cortex of the metacarpals. Endosteal resorption may involve the phalanges of the digits. Subligamentous bone resorption affects the tuberosities of the humerus, the ischium, and the greater and lesser femoral trochanters, as well as the inferior surface of the lateral end of the clavicle and the inferior surface of the calcaneus. Subchondral resorption occurs at several sites, including the sternoclavicular and acromioclavicular joints, the symphysis pubis, the sacroiliac joints, and the discovertebral joints. An erosive-type arthropathy is reported with secondary hyperparathyroidism.

Brown tumors occur, but these are less common with secondary hyperparathyroidism than they are with primary hyperparathyroidism. However, as the life expectancy of patients with chronic renal disease has increased, brown tumors have increasingly been identified with renal osteodystrophy. Brown tumors may occur in the spine and form expansile masses, which can be complicated by paraplegia. Brown tumors of the sellar and/or parasellar regions and face may appear as destructive lesions.

The skull may show a granular pattern, which may be associated with thickening, particularly in the inner table. Osteomalacia may be predominant in patients with renal osteodystrophy. Associated Looser transformation zones and pathologic fractures, possibly symmetric, can be present. Osteosclerosis may affect the epiphyses, metaphyses, pelvis, and ribs. Frequently, a classic rugger-jersey spine is observed; it is caused by ill-defined bands of increased bone density adjacent to the vertebral endplates.

An organized periosteal reaction (eg, periosteal neostasis) may develop around the metatarsals, femora, and pelvis. This finding, although not typical, is more common in secondary hyperparathyroidism than it is in the primary form of disease. Generalized osteopenia, often severe, may occur. Digital phalangeal brachydactyly secondary to healed renal osteodystrophy may be present. Rarely, kyphoscoliosis may occur.

Extra-osseous calcification is more common in secondary hyperparathyroidism than it is in the primary form of the disease, and it is even more common in long-standing disease. Abnormal calcification and other abnormalities include the following:

• Tumoral calcification associated with bone erosions
• Chondrocalcinosis
• Vascular calcification
• Calcified pulmonary nodules
• Cerebral subcortical calcification
• Calcification within the eyes
• Layering of soft-tissue calcification
• Cardiac calcifications
• Breast calcifications
• Renal calcification
• Hepatic calcification

See also the eMedicine articles Cardiac Calcifications, Breast, Benign Calcifications, and Chondrocalcinosis.

Degree of Confidence

In renal osteodystrophy, bone resorption is invariably present. Correlation of findings with the patient's history and biochemical parameters should lead to the correct diagnosis. However, secondary hyperparathyroidism associated with osteomalacia of dietary origin may cause vague symptoms and, sometimes, nonspecific biochemical findings.

False Positives/Negatives

The radiologic features of secondary hyperparathyroidism are similar to those of the disease's primary form. The radiologic changes can sometimes mimic those observed in Paget disease.

CT SCAN

Section 5 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Findings

CT scan findings in renal osteodystrophy include abnormal sacroiliac joints, multiple brown tumors, osteitis fibrosa cystica, prominent Schmorl nodes, periarticular tumoral calcifications, and slipped capital femoral epiphyses.³ Layering of soft-tissue calcification is well demonstrated on CT scans. In general, however, and in comparison with other modalities, CT scanning offers no advantage in the diagnosis of secondary hyperparathyroidism.

Degree of Confidence

CT scanning is rarely employed in screening exams for renal osteodystrophy.³ Nonetheless, knowledge of the CT scan appearances of secondary hyperparathyroidism is important; it helps clinicians avoid confusing the changes associated with secondary hyperparathyroidism with those resulting from other pathologic conditions. On the whole, however, CT scanning is not sensitive in the detection of changes related to secondary hyperparathyroidism.

False Positives/Negatives

Soft-tissue calcification is not specific to secondary hyperparathyroidism and has myriad causes. Erosive changes attributable to secondary hyperparathyroidism may easily be confused with changes in rheumatoid arthritis, seronegative spondyloarthropathies, infection, or even malignancy. Brown tumors and amyloid deposition can easily be mistaken for a neoplastic process.

MRI

Section 6 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Findings

MRI can adequately reveal skeletal deformity, cortical thickening, and irregular trabecular patterns in children with renal osteodystrophy.^{3, 4} In addition, MRI shows osteonecrosis and intraosseous soft-tissue masses more conspicuously than do plain radiographs. This modality also shows diffuse, nonspecific marrow changes.⁵ One case describes the MRI diagnosis of thoracic myelopathy caused by spinal stenosis secondary to renal osteodystrophy.⁶ MRI is also useful in the detection of parathyroid hyperplasia.

Degree of Confidence

Based on current experience, MRI findings in secondary hyperparathyroidism are not specific enough for this modality to replace radiography. Also, MRI has low sensitivity and specificity in the detection of parathyroid hyperplasia.

False Positives/Negatives

MRI findings in chronic osteodystrophy can often mimic those of other diseases.

ULTRASOUND

Section 7 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Findings

Ultrasonography is useful in the detection of parathyroid enlargement.

Degree of Confidence

The sensitivity of ultrasonography in the detection of parathyroid hyperplasia is low. Imaging modalities in secondary hyperparathyroidism are of a limited value in guiding medical and surgical treatment. However, if percutaneous alcohol ablation is contemplated as an adjunct to medical treatment, ultrasonography may be useful in the initial localization of an abnormal gland.

False Positives/Negatives

Ultrasonography has a high rate of false-negative findings in the diagnosis of parathyroid hyperplasia. A thyroid tumor may mimic a parathyroid adenoma.

NUCLEAR MEDICINE

Section 8 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Findings

Several radionuclide features are reported in secondary hyperparathyroidism. A superscan may reveal the following findings:

• Diffusely increased activity in bones, specifically in the axial skeleton, calvaria, mandible, costochondral junctions, long bones, and sternum
• An increased bone-to–soft tissue ratio
• Absent kidney and urinary bladder findings

Technetium-99m sestamibi and subtraction scintigraphy with thallium-201 (²⁰¹Tl) and ^99mTc have been used to localize parathyroid hyperplasia in secondary hyperparathyroidism, but they are of limited value.^{7, 8, 9, 10}

Degree of Confidence

Radionuclide bone scans have low sensitivity and specificity in the detection of secondary hyperparathyroidism. The use of radionuclides in the diagnosis of parathyroid hyperplasia also has a limited role.

False Positives/Negatives

Besides renal osteodystrophy and/or hyperparathyroidism, the following conditions, displaying the same features as hyperparathyroidism, may appear to be present:

• Hyperthyroidism
• Extensive skeletal metastases
• Aplastic anemia
• Leukemia
• Widespread Paget disease
• Myelofibrosis and/or myelosclerosis
• Waldenström macroglobulinemia
• Systemic mastocytosis

MULTIMEDIA

Section 9 of 10  

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

Media file 1:  Radiograph of the left hand of a 6-year-old girl with chronic renal failure shows ulnar bowing of the distal radius and ulna, mild widening of the growth plates associated with a slight irregularity of the metaphyseal margins, coarsening of the trabecular pattern, and periosteal new bone formation around the metaphyses of the metacarpals and phalanges. The appearance is that of rickets and/or renal osteodystrophy. Note that bone aging is retarded.
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Media file 2:  Radiograph of the dorsal spine (same child as in Image 1) shows the classic rugger-jersey spine. This results from ill-defined bands of increased bone density adjacent to the vertebral endplates.
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Media type:  X-RAY

Media file 3:  Radiograph of both hands of a 36-year-old woman receiving long-term hemodialysis shows subperiosteal bone resorption affecting the radial aspect of the middle phalanges of the fingers. Note the extensive digital arterial calcification.
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Media type:  X-RAY

Media file 4:  Plain radiograph of the skull of a 39-year-old woman demonstrates malabsorption syndrome with the biochemical features of osteomalacia. The image shows a granular pattern of the skull. Note the brown tumor (arrow).
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Media file 5:  Posteroanterior (PA) chest radiograph in a 60-year-old woman shows subligamentous bone resorption of the inferior surface of the lateral ends of the clavicles.
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Media type:  X-RAY

Media file 6:  Radiograph of the dorsal spine of an adult male shows the classic rugger-jersey spine caused by ill-defined bands of increased bone density adjacent to the vertebral endplates.
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Media type:  X-RAY

Media file 7:  Radiograph in a 53-year-old woman with nutritional osteomalacia shows a brown tumor in the region of the tibial tuberosity (left) and healing of the lesion after vitamin D therapy (right). Also note improved mineralization of the bones.
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Media file 8:  Posteroanterior (PA) chest radiograph shows multiple expansile brown tumors in the medial border of the left scapula and in several of the ribs (black arrows). Also note subperiosteal bone resorption along one of the rib margins (white arrow).
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Media file 9:  Radiograph of the pelvis (same patient as in Image 8) shows multiple brown tumors (arrows).
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Media file 10:  Radiograph of the feet (same patient as in Images 8 and 9) shows fairly large para-articular erosions in the heads of the right third and fourth metatarsal bones. Note the organized periosteal reaction around the shafts of those bones.
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Media file 11:  Anteroposterior (AP) radiograph of the right knee of a 55-year-old man receiving chronic hemodialysis. The patient presented with a red, hot, painful knee. Microscopic analysis of the joint aspirate revealed pyrophosphate crystals. The diagnosis was pseudogout. The radiograph shows chondrocalcinosis.
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Media file 12:  Occasionally, patients with chronic renal failure may present with biochemical and radiographic features of osteomalacia. This plain radiograph of the pelvis of a 77-year-old woman shows multiple pseudofractures. Note the osteosclerosis and a brown tumor in the region of the intertrochanteric line of the left femur.
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Media file 13:  Superscan shows diffusely increased activity in the axial skeleton and perhaps in the calvaria and mandible. The ratio of bone to soft tissue is increased, and the kidneys and urinary bladder are absent.
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Media type:  Image

Media file 14:  Technetium-99m (99mTc) bone scan in a patient with chronic renal disease shows uptake in the lungs and calvaria. No renal or bladder activity was noted. (The kidneys are not shown.)
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Media type:  Image

REFERENCES

Section 10 of 10

• Authors and Editors
• Introduction
• Differentials
• Radiograph
• CT Scan
• MRI
• Ultrasound
• Nuclear Medicine
• Multimedia
• References

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11. Falbo SE, Sundaram M, Ballal S, et al. Clinical significance of erosive azotemic osteodystrophy: a prospective masked study. Skeletal Radiol. Feb 1999;28(2):86-9. [Medline].
12. Gerakis A, Hadjidakis D, Kokkinakis E, et al. Correlation of bone mineral density with the histological findings of renal osteodystrophy in patients on hemodialysis. J Nephrol. Nov-Dec 2000;13(6):437-43. [Medline].
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14. Ito M, Ito M, Hayashi K, et al. Evaluation of spinal bone changes in patients with chronic renal failure by CT and MR imaging with pathologic correlation. Acta Radiol. May 1994;35(3):291-5. [Medline].
15. Leone A, Sundaram M, Cerase A, et al. Destructive spondyloarthropathy of the cervical spine in long-term hemodialyzed patients: a five-year clinical radiological prospective study. Skeletal Radiol. Aug 2001;30(8):431-41. [Medline].
16. Roe S, Cassidy MJ. Diagnosis and monitoring of renal osteodystrophy. Curr Opin Nephrol Hypertens. Nov 2000;9(6):675-81. [Medline].
17. Von Rueden TJ, Knight L, Moller JH, et al. Coarctation of the aorta associated with aortic valvular atresia. Circulation. Nov 1975;52(5):951-4. [Medline].
18. Wada A, Sugihara M, Sugimura K, et al. Magnetic resonance imaging (MRI) and technetium-99m-methoxyisonitrile (MIBI) scintigraphy to evaluate the abnormal parathyroid gland and PEIT efficacy for secondary hyperparathyroidism. Radiat Med. Jul-Aug 1999;17(4):275-82. [Medline]. [Full Text].

Article Last Updated: Dec 18, 2007