Café-au-lait spots and intertriginous freckling ( Figure 53.1A )

Café-au-lait spots are flat, pigmented macules, and are generally the first cutaneous manifestation of NF1. Often present at birth, they become apparent during the first few years of life. As many as 97% of children who are eventually diagnosed with NF1 will have six or more café-au-lait spots by the time they are 6 years of age. Patients with greater numbers of café-au-lait spots are not at risk for the development of more severe disease. While freckling is common in sun-exposed areas of individuals without NF1, smaller café-au-lait spots or freckling may be seen in areas not directly exposed to the sun in individuals with NF1, and constitutes the second most common diagnostic criterion found in young children. These freckles typically occur in skinfolds, including the axilla, inguinal creases, submammary regions, and the neck.

Clinical features of neurofibromatosis type 1. (A) Café-au-lait spots. (B) Dermal neurofibromas. (C) Plexiform neurofibroma. (D) Lisch nodules.

Dermal neurofibromas ( Figure 53.1B )

Neurofibromas, the hallmark lesion of NF1, are benign nerve sheath tumors arising from peripheral nerves. These tumors are composed of neoplastic Schwann cells as well as numerous stromal cell types (i.e., mast cells, fibroblasts, and perineural cells). Cutaneous neurofibromas arise from small superficial nerves; they are soft, protrude just above the skin’s surface, and often display a violaceous hue. In contrast, subcutaneous neurofibromas arise from deeper nerves and are generally firm. Deep visceral neurofibromas may cause symptoms by compressing vital structures, such as is seen in spinal cord compression from dorsal root neurofibromas. Although young children may have some neurofibromas, these tumors tend to appear with the onset of puberty and increase in both size and number with advancing age.

Plexiform neurofibromas ( Figure 53.1C )

Although plexiform neurofibromas are histologically similar to dermal neurofibromas, they are clinically quite distinct. They are often present at birth or develop in the first several years of life, undergoing a phase of rapid growth during childhood. Although these tumors are generally soft, the observer can often feel multiple firmer thickened nerves within the tumor, described as a “bag of worms.” Overlying hyperpigmentation or fine hair growth may be a clue to the presence of an underlying plexiform neurofibroma. Often arising from branches of major nerves, they can become large and cause significant dysfunction. Plexiform neurofibromas involving the eyelid or orbit may lead to visual loss from associated glaucoma, amblyopia secondary to proptosis, or optic nerve damage. Internal plexiform neurofibromas can cause morbidity as a result of spinal cord compression, erosion of contiguous bone, or ureteral/bladder outlet obstruction.

Lisch nodules ( Figure 53.1D )

Lisch nodules are dome-shaped melanocytic hamartomas of the iris, and are virtually pathognomonic of NF1. Not associated with any visual abnormalities, they are present in 90–95% of adults with NF1. They are best visualized using a slit lamp by an experienced ophthalmologist.

Natural history of OPG

Predicting the natural history of an individual OPG is impossible. For example, rapidly progressive intraorbital tumors which cause proptosis and significant visual loss may stop growing following initial presentation. While progressive disease following the diagnosis of a symptomatic OPG occurs in 35–52% of cases, OPGs found by screening neuroimaging of asymptomatic individuals with NF1 rarely progress. Most importantly, the natural history of NF1-associated OPGs is markedly different from that of sporadic OPG. The latter are significantly more likely to progress radiographically and clinically, leading to the development of increased intracranial pressure and hydrocephalus with substantially greater ophthalmologic morbidity.

Diagnostic evaluation of asymptomatic children with NF1

All young children with NF1 should undergo complete yearly ophthalmologic examinations in order to identify the earliest manifestations of a symptomatic OPG. Complete examinations including ocular alignment and rotations, assessment of color vision, pupillary light response, refractive status, and fundoscopic evaluation should be performed. Visual acuity should be measured using age-appropriate testing (i.e., preferential looking tests in infants, Lea figure, or HOTV matching in preliterate children, Snellen charts in older children). Routine measurement of visual fields is unnecessary as clinically important visual field compromise without concomitant loss of visual acuity is rare. There is no reliable evidence supporting the routine use of visual evoked potentials in the diagnosis of NF1-associated OPG.

There has been considerable debate as to the role of neuroimaging of asymptomatic children with NF1. Routine “screening” neuroimaging would be important if it led to the early detection of OPG which, in turn, led to significantly decreased ophthalmologic morbidity. However, there are substantial data showing that such a strategy would fail; in previous studies, many tumors were detected that never progressed and some children developed symptomatic OPG after a normal visual screening examination. Thus, there is no conclusive evidence that the early detection of OPGs leads to improved outcome. For these reasons, screening “baseline” neuroimaging of asymptomatic children with NF1 is not recommended.

Follow-up of an asymptomatic OPG

Once an asymptomatic NF1-associated OPG has been identified, close follow-up is warranted, as the natural history of an individual tumor cannot be predicted. Generally, ophthalmologic examinations should be performed every 3 months during the first year following diagnosis. Magnetic resonance imaging should also be performed at frequent intervals; the exact protocols vary among institutions. As the child gets older without evidence of either clinical or radiographic progression, the intervals between examinations can be progressively lengthened.

Treatment

There are scant data as to what constitutes sufficient clinical or radiographic progression to warrant treatment. Radiographic progression without a concomitant change in the child’s visual examination may not be sufficiently compelling to mandate treatment. Additionally, the appearance of clinical signs, such as the development of precocious puberty, does not constitute in itself a reason for treatment. However, once the decision to undergo treatment has been made, certain truths exist.

There is a limited role for surgery in the management of NF1-associated OPG. Partial removal of an intraorbital optic nerve glioma is usually reserved for cosmetic purposes only. On occasion, surgical decompression of a hypothalamic glioma may be necessary to treat hydrocephalus secondary to third ventricular compression. Biopsy is only recommended in very atypical cases as NF1-associated OPG are most often low-grade juvenile pilocytic astrocytomas. Similarly, radiotherapy in children with NF1 is not recommended, because of the unacceptable neurovascular (cerebral occlusive vasculopathy), endocrinologic, and neuropsychologic sequelae. Moreover, recent evidence suggests that children with NF1 treated with radiation therapy develop secondary brain malignancies later in life.

Chemotherapy has become the mainstay of treatment for NF1-associated OPGs. The most commonly used chemotherapeutic regimen is the combination of carboplatin and vincristine. This combination is effective in controlling the growth of most NF1-associated OPGs, and is typically well tolerated in this age group. Other chemotherapies have also been used; however, there is no consensus on which second-line therapy is most effective for these tumors.