Heavy Metals

Heavy metals such as lead, mercury, cadmium, and aluminum can induce seizures by disrupting neural function.¹³ Heavy metal toxicity should be ruled out as a possible cause in all seizures. A hair mineral analysis provides the most cost-effective screening method for the detection of heavy metals. Urine analysis remains the best method for estimating the levels of stored heavy metals after the administration of a chelating agent such as calcium disodium ethylenediaminetetraacetic acid or dimercaptosuccinic acid (see Chapter 53).

Neurotoxic Chemicals

Many neuron-, axon-, and myelintoxic chemicals have now been released into the environment. These chemicals are finding their way into human tissues, contributing to neurologic dysfunction. Minimizing exposure and improving the body’s ability to eliminate neurotoxic agents become important aspects of the therapeutics approach. Chapters 35 and 53 discuss the impact of these neurotoxins.

Hypoglycemia

Focal neurologic deficits associated with hypoglycemia have been well described in adults with diabetes,¹⁴ and some researchers believe that hypoglycemia is the most important metabolic cause of seizures.¹³ Researchers have found the following^13,15–18:

Although the correlation of blood sugar abnormalities and epilepsy seems well documented, the mechanism of action is unknown. It has been suggested that low blood sugar could impair adenosine triphosphate (ATP) production in nerve cells, reducing the efficacy of the sodium ATPase pump. A defective sodium pump allows for increased intracellular sodium concentrations, which depolarize the cell membrane and thus lowers the firing threshold.

More recent observational studies have pointed to leptin as a factor that may help in regulating the occurrence of seizures. Animal studies have confirmed that injecting leptin reduces the occurrence and severity of seizures. It is well established that low blood sugar results in low circulating leptins levels, leading to another possible mechanism of action.¹⁹

Single measurements of serum glucose levels are inadequate to determine glycemic status—only an extended glucose tolerance test will give a complete picture.

Ketogenic Diet

Originally introduced by Wilder in 1921,²⁰ the ketogenic diet (KD) has a long history of use for the reduction of seizure activity.^21–23

The diet is composed of more than 90% fat by weight, low in carbohydrates, and adequate in proteins, vitamins, and minerals. The low carbohydrate intake inhibits fat metabolism, resulting in the production of excessive levels of ketone bodies (acetone, acetoacetic acid, and beta-hydroxybutyric acid), the intermediary oxidation products. Presumably the beneficial effects of such a diet are due to its induction of metabolic acidosis, which corrects an underlying tendency of epileptics toward the spontaneous development of alkalosis.^20–22 This acidification is thought to normalize nerve conductivity, irritability, and membrane permeability.

Another possible benefit of the KD may be in augmenting ATP production by utilizing ketone bodies in place of glucose. It has been documented that many epileptics are hypoglycemic, thus compromising mitochondrial ATP production. The KD may provide an alternative route for balancing this deficit.²⁴

The two main types of KDs are (1) the classic diet and (2) the medium-chain triglyceride diet. The classic KD produces ketosis by limiting intake of carbohydrates and protein to less than 10% of energy combined. The medium-chain triglyceride diet uses medium-chain triglyceride fat to produce ketosis. This allows for a larger intake of carbohydrates and protein.²⁰

Research continues to document the efficacy of these types of dietary therapy. For example, one study of 27 children from 1 to 16 years of age using the classic diet found that 40% experienced a reduction of seizures of more than 50%, with 25% becoming seizure-free.²⁵ However, 35% discontinued the diet owing to difficulty in following the rigorous guidelines. A review from 1996 concluded that the KD had efficacy in one third to one half of childhood epilepsy cases and was partially effective in another one-third of cases.²⁶ A review article from 1997 states that the KD’s success rate “greatly exceeds that of the medications” and that its side effects are fewer and the therapy cheaper.²⁷

One prospective nonrandomized study measured the nutrient intakes, growth, and biochemical indexes of 30 children from 1 to 16 years of age who had intractable epilepsy before and after a 4-month protocol using a KD. Fourteen children on the classic diet and 11 on the medium-chain triglyceride diet completed the study, for an 83% completion. The results indicated that linear growth was maintained in patients from baseline to 4 months on both therapies. However, body weight decreased for children on both diets, which could be a result of inadequate energy intake. Protein intake met recommendations for both diets. In the medium-chain triglyceride group, there was a 0.7 decrease in the ratio of total cholesterol to high-density lipoprotein ratios at 4 months. All biochemical indices including albumin levels remained within normal limits.²⁰ However, this was only a 4-month study. Longer-term evaluations may show eventual unwanted changes in these parameters. The authors concluded that the medium-chain triglyceride diet may be more nutritionally adequate and thus confer an advantage over the classic KD.

Although the previously mentioned study demonstrated a relatively short use of 4 months, the KD is not without side effects. The long-term risks of a high-fat diet are well known, and a KD may prove unhealthy for a growing child. One retrospective investigation found that the linear growth of some children might be retarded.²⁸ When treating children on a KD, clinicians should recommend adequate intake of energy and protein, a higher proportion of unsaturated to saturated dietary fats, and also consider vitamin and mineral supplements.²⁰ Also, children should not be allowed to eat large meals, because these may predispose them to seizures. Small, frequent meals may be appropriate and may decrease hypoglycemic episodes.

In a study appearing in Seizure, researchers evaluated the long-term efficacy and tolerability of the KD in pediatric drug-resistant epileptic patients. The authors concluded that despite the retrospective nature of the study and the inhomogeneous patient sample, their results pointed to good long-term effects of the KD on seizure frequency, EEG readings, and neurologic development.²⁹

The Atkins diet, which has gained great popularity in past years as a weight-loss tool, theoretically may be useful to treat epilepsy.³⁰ Like the KD, it too produces a ketotic state but creates this effect with less restriction on protein intake. In one pilot study, 6 patients ranging from 7 to 52 years of age were prescribed the Atkins diet for intractable focal and multifocal epilepsy. Five of the patients maintained moderate to large ketosis for periods of 6 weeks to 24 months and 3 experienced seizure reduction. As a result, they were able to reduce their antiepileptic medications.³¹ Larger trials are necessary to explore whether the Atkins diet may be useful to treat patients with epilepsy.

Food Allergy

There has been little research into the correlation between food allergy and epilepsy, with only anecdotal case histories,^35,36 single-case double-blind placebo-controlled studies,^37,38 and uncontrolled studies being reported. It is postulated that epileptic patients may have allergic reactions in the brain that are similar to the swelling, anoxia, and inflammatory chemical reactions seen at other sites of local allergic reactions.³⁵

One uncontrolled study evaluated oligoantigenic diets in 63 children with epilepsy. Of 45 children with recurrent headaches, hyperkinetic behavior, or abdominal symptoms, 25 ceased to have seizures and 11 had fewer seizures during diet therapy. Headaches, abdominal pain, and hyperkinetic behavior ceased in all patients whose seizures ceased and in some of those whose seizures did not cease. Reintroduction of foods reproduced symptoms. Of 24 children with generalized epilepsy, 18 recovered or improved, as did 18 of 21 children with partial epilepsy. In double-blind provocation, 15 of 16 children experienced recurrence of symptoms, including seizures in 8, whereas none improved in the placebo group. Another group of 18 children who had epilepsy alone had no improvement with dietary change.³⁹ This study suggests that food allergy should be suspected in epileptic patients who suffer from multiple other symptoms of food allergy (see Chapter 15).

Another study evaluated two females, 5 and 23 years of age, who had focal occipital epilepsy with cerebral calcifications and were not responding well to antiepileptic therapy. Both had celiac disease as well as documented folic acid deficiency (a common side effect of most antiepileptic drugs). A gluten-free diet combined with supplementation with folic acid (dosage not reported) led to complete normalization of the EEG in the 5-year-old and cessation of seizures. The 23-year-old experienced significant improvement in her EEG and enhanced seizure control. Folic acid returned to the normal range within several months.⁴⁰

A larger study looked more closely at the association between celiac disease and epilepsy. A total of 43 patients (15 male) between 4 and 31 years of age were evaluated for the association between celiac disease, epilepsy, and cerebral calcifications. Intestinal biopsy on the 31 patients with cerebral calcifications of unexplained origin and epilepsy found a flat intestinal mucosa in 24, suggesting celiac disease. CT scans showed cerebral calcifications in 5 of the 12 patients with celiac disease and epilepsy. Antibodies to gluten and folic acid serum concentrations were measured, and histocompatibility leukocyte antigen typing was done in most patients. Only 2 patients with cerebral calcifications and epilepsy had gastrointestinal symptoms at the time of biopsy. A gluten-free diet in epilepsy was found to be inversely related to the duration of epilepsy before the diet and to the patient’s age at the beginning of the diet.

The authors strongly recommend that celiac disease be considered in all cases of epilepsy and cerebral calcifications of unexplained origin, especially when the epilepsy is characterized by occipital seizures and the calcification is located bilaterally in the posterior regions.⁴¹ One work involving 72 epileptic children and 202 controls revealed significantly higher rates of eczema in the mothers and rhinitis in the siblings of the epileptic patients as well as a generally higher incidence of allergic pathologies in both of these groups compared with the controls. Additionally, a significantly higher incidence of allergy to cow’s milk as well as asthma was documented in the epileptic children with respect to the control group. Prick tests gave a significantly higher rate of positive results for cow’s milk proteins in the epileptic patients versus controls.⁴²