Percutaneous endoscopic gastrostomy

Placement of a percutaneous endoscopic gastrostomy (PEG) tube is one of the most effective means of proactive intervention to maintain body weight and hydration . Optimally, the PEG tube should be introduced early to supplement oral intake and reduce the stress of maintaining all nutritional needs by mouth. Patient acceptance of the PEG tube can be greatly improved by educating the patient that they may still enjoy favorite foods by mouth. Moreover, use of the PEG to meet the increased caloric requirements of the disease can conserve time and energy for both patient and caregiver. The patient’s autonomy, confidence, and quality of life are enhanced by knowing that they can aggressively affect their disease course by the use of a PEG tube, while minimizing their fear of choking and the caregiver’s burden.

The timing of PEG tube placement varies widely among practitioners; however, the American Academy of Neurology recommends PEG placement before the patient’s forced vital capacity falls below 50% predicted . This timing is to avoid risk of respiratory compromise during the procedure. This recommendation is based on available outcomes data from studies meeting the qualifications for the guidelines. General consensus among practitioners suggests that adopting the tube early in the course of progressive dysphagia, even before significant weight loss, is well accepted and allows the patient the choice of incrementally using the PEG for their nutritional needs . Alternative protocols for feeding tube placement, including insertion of the tube with radiographic guidance (RIG) have been endorsed as means of lessening the risk of aspiration . Recently an alternative Bi-level positive airway pressure mask was introduced allowing for continuous noninvasive ventilatory support during PEG placement reducing risk of respiratory compromise and improving patient comfort even when forced vital capacity falls much below 50% .

Oxidative injury

Oxidative damage is thought to be a major contributing factor in the death of motor neurons . Oxidative injury can have both a primary role and a secondary role triggered by other mechanisms mentioned below. Reactive oxygen species (ROS) include superoxide, hydrogen peroxide (H ₂ O ₂ ), hydroxyl free radicals (OH), and nitric oxide (NO). ROS readily react with lipids, proteins, and DNA to induce cellular damage . The high metabolic activity of neurons leads to considerable ROS formation in these cells . The high content of lipids and iron in the nervous system may make it particularly sensitive to ROS damage . Glutathione peroxidase, catalase, and superoxide dismutase (SOD) are all endogenous antioxidants that counteract ROS damage. Toxicity resulting from mutated SOD has been directly implicated in the pathophysiology in familial ALS. Further support for the ROS hypothesis comes from elevated levels of protein carbonyls and 8-hydroxy-2-deoxyguanosine (8-OHdG), both markers of oxidative damage, in the motor cortex of sporadic ALS patients . In addition, elevated plasma levels of 8-OHdG and thiobarbituric acid reactive substances (TBARS) have been identified in sporadic ALS patients compared with healthy controls. Possible benefit from exogenous nutraceuticals may result from their direct antioxidant activity and/or effects on endogenous enzyme pathways .

Excitotoxicity

Glutamate is a primary excitatory neurotransmitter in CNS. Dysfunction in synaptic uptake of glutamate may lead to prolonged opening of glutamate-dependent Ca ⁺² channels in neuron, which may, in turn, generate free radicals and directly damage intracellular organelles (ie, mitochondria). Glutamate release and reuptake is usually tightly regulated; however, increased glutamate in cerebrospinal fluid was found in sporadic ALS patients. Riluzole, the only FDA-approved drug with indication for ALS, acts by blocking the presynaptic release of glutamate . Supplements that likewise act to block glutamate release, enhance reuptake, or protect cells against the damaging effects of excessive glutamate may aid in the medicinal management of ALS.

Mitochondrial dysfunction

Strong evidence exists for mitochondrial dysfunction in motor neuron disease. Morphologic changes in mitochondria have been identified in SOD-1 mice and in sporadic ALS patients without SOD-1 mutations . Structural abnormalities within the electron transport chain and mutations within mitochondrial DNA have been implicated in the pathogenesis of ALS . The primary role of mitochondria in cells is energy production by oxidative phosphorylation. Given the high metabolic demand of neurons, energy supply and use is critical and is reflected in the large number of neuronal mitochondria. Mitochondrial damage may be due to, or result in, increased free radical activity, increased intracellular free Ca ⁺² , defective electron transport enzymes (complexes I-IV), or coenzymes . Dysfunctional mitochondria lead to the overproduction of ROS; abnormalities in the mitochondrial transition pore may activate a caspase cascade resulting in further oxidative damage .

Mitochondrial activity and the underlying physiology in neurons may also differ from the brain and spinal cord . These differences may ultimately provide essential insights into disease heterogeneity in upper versus lower motor neuron clinical presentations.

Nutritional supplements that prevent free radical damage, stabilize mitochondrial membranes, or stimulate electron transport chain complexes may be of value.

Vitamin E

Reports of alpha-tocopherol, an isomer of vitamin E, as a trial therapy for ALS date back to the 1940s when Lou Gehrig received weekly intramuscular injections as putative therapy . Despite the absence of documented clinical benefit in controlled trials, vitamin E continues to be among the most popular of the dietary supplements. This is likely the result of preclinical data, the association of vitamin E and motor neuron disease from other species, and the ease of availability with few or no documented side effects.

B vitamins (folic acid, B6, B12)

Use of the B vitamins, particularly folic acid and methylcombalamin, have been largely driven by the observation that patients who have ALS may have elevated plasma homocysteine levels . In the transgenic SOD-1 mouse model similar elevation of plasma homocysteine was found . Vitamin B12 and folate are involved in reactions that convert homocysteine to methionine, thereby potentially reducing homocysteine levels. Furthermore, vitamin B6 functions in an alternative pathway to convert homocysteine to sulfur amino acids .

In 1998, a double-blind, randomized clinical trial examined the effects of megadose methylcobalamin, an analog of vitamin B12, on averaged compound muscle action potential amplitudes (CMAPs) in ALS patients. Twenty-four ALS patients with similar CMAPs at baseline were randomly assigned to two groups. Group 1 received 25 mg of methylcobalamin daily by intramuscular injection for 28 days. Group 2 received a lower dose (0.5 mg/day) for 28 days. CMAPs of selected muscle groups were measured at baseline, day 14, and day 28. The low-dose methylcobalamin group showed no significant changes in CMAPs from baseline, while the eight patients in the higher-dose group showed significantly higher CMAPs at 28 days compared with baseline. The investigators classified these eight subjects as “responders” and the remaining four subjects as “non-responders.” Based on these data, it was concluded that among certain ALS patients, high-dose methylcobalamin enhances neuronal functioning.

Despite the small sample size, the absence of a placebo group, and the absence of any documented improvement in clinical function, this study has contributed to speculation that such therapy may be of benefit . The study does raise the important possibility that the ALS patient population may be quite heterogeneous, consisting of responders and nonresponders to a certain supplement or medication. If the disease pathophysiology is accepted as multifactorial, then the possibility emerges that there may be a subgroup of responders to selected treatments. Such possibilities have propagated the use of B complex vitamins, in part due to their availability and low side effect profile .

Zinc

Zinc is implicated as a supplement with potential benefit due to its integral role in the function of SOD-1. Mutant forms of SOD-1, as found in the transgenic model of ALS, have impaired ability to bind zinc and are toxic . Zinc supplementation has been shown to up-regulate metallothioneins, and facilitate antioxidant function . Zinc has therefore been implicated especially in patients possessing a mutated SOD-1 protein (ie, familial ALS patients).

Two experiments examining this hypothesis in the transgenic mouse model have yielded contrasting results. In the first experiment, three groups (11 transgenic mice per group) were given 75 mg/kg zinc, 375 mg/kg zinc, or no zinc in their drinking water. Contrary to their hypothesis that zinc would be protective, supplementation actually decreased survival in a dose-dependent manner. Zinc had no effect on symptom onset or on motor neuron numbers. These results suggested that zinc supplementation may actually accelerate motor neuron loss .

In a second study, more moderate dosages of zinc (12 mg/kg) delayed death in G93A-mutant SOD mice by 11 days compared with mice on a zinc-deficient diet . Slightly higher doses (approximately 18 mg/kg) significantly shortened survival and this effect was blocked by concurrent supplementation with copper, which may have been displaced by the higher zinc dose. These data highlight the importance of dosage in supplementing zinc and the synergistic interaction of copper and zinc in predicting the toxic or neuroprotective effects .

Careful attention to the daily dosage of zinc, often found in compounded nutraceutical supplements, in the patient population is advised. It may be most prudent to simply assure adequate intake of zinc to meet the recommended dietary allowance.

Genistein

Genistein is a phytoestrogen that has been implicated in oxidative insult resulting from cerebral ischemia. Estrogen compounds have also been implicated as neuroprotective agents promoting survival of motor neurons. Survival differences between males and female SOD-1 transgenic mice have been attributed to the role of estrogen. This hypothesis was tested using genistein (16 mg/kg, twice daily) in that model. Genistein significantly delayed symptom onset and prolonged survival in male animals, but not in female animals. The study concludes that phytoestrogens in genistein pose gender-specific neuroprotection, likely by the same mechanism of endogenous estrogen. This provides support that the estrogenic effects of genistein may be neuroprotective but not at levels above normal, endogenous estrogen . Clinical trials using genestein have not been reported.

Melatonin

Melatonin displays a wide array of antioxidant activities, including activation of glutathione peroxidase and inhibition of nitric oxide synthase . Treatment with melatonin resulted in a significant, dose-dependent attenuation of glutamate-induced cell death in vitro using a motor neuron cell line. In transgenic mice, melatonin has been tested by administration before symptom onset or on the day of symptom onset. Symptom onset was delayed and survival prolonged when administered before symptom onset, however, not when administered after symptom onset.

In the ALS population, 31 ALS patients were given high-dose melatonin (300 mg/day) by rectal suppository for 24 months and compared with healthy, matched controls. The extent of oxidative injury was accessed by measurement of protein carbonyl levels in serum. At baseline, ALS patients displayed significant elevations of serum protein carbonyl groups. After four months of treatment with melatonin, serum protein carbonyl levels were the same in ALS patients as in healthy controls, indicating that melatonin attenuated oxidative damage. No report on symptom modification or alteration in disease course has been made .

Creatine

Creatine has received much attention within the patient population based largely on preclinical data and anecdotal patient reports. The use of creatine in combination with other agents has also been encouraging, albeit unproven in clinical trials. Creatine monohydrate displays many pharmacokinetic properties relevant to mechanisms of motor neuron loss in ALS. Enhancing energy production within mitochondria and possibly limiting the uptake of glutamate into cells have been proposed as putative neuroprotective effects . The compound also displays antioxidant properties by acting as a mitochondrial membrane stabilizer .

In the transgenic SOD-1 model of ALS, creatine supplementation resulted in a dose-dependent increase in survival and motor performance as well as dose-dependent decreases in motor neuron loss and biomarkers of oxidative damage . Another study reported that supplementation significantly attenuated chemically-induced increases in glutamate, delay in symptom onset and prolonged survival . By contrast, a third study examining the effects of creatine on muscle function and muscle metabolism showed no improvements in rotorod performance, grip strength, ATP concentrations, or glycogen concentrations .

Combination therapies using creatine have been tested in several forms. The effects of riluzole, creatine, or the combination of both yielded delay in symptom onset and prolonged survival compared with control mice; however, no significant differences between treatment groups were observed . The combination appeared to have additive, synergistic effects on these outcome measures compared with the control group or either agent alone . Celecoxib and rofecoxib (both COX-2 inhibitors) were also tested alone and in combination with creatine; this combination resulted in significantly improved motor performance, reduced motor neuron loss, and extended survival. In combination with creatine, the effects on survival were significantly additive .

Despite such promising results from these animal studies, clinical trials have failed to show any significant effects of creatine for any outcomes examined. To date, three large clinical trials of creatine have been completed in the ALS population. All three studies concluded no efficacy in the primary endpoints . While the studies differed somewhat in either dose and/or design, the conclusion followed that creatine, by itself, using available clinical outcomes, did not help. An interesting trend in improved survival in the creatine treatment groups from two of the studies has prompted a meta-analysis. A significant trend of improved survival was noted when the two trials recently completed in North America were combined. This benefit was more modest (not significant) when the third European trial was also included. The implication followed that larger study of survival in the patient population may be warranted.

Coenzyme Q10

Coenzyme Q10 (CoQ10) is a critical component of the electron transport chain of mitochondria. It also exhibits antioxidant properties . Although serum levels of CoQ10 do not differ between sporadic ALS patients and healthy controls , sporadic ALS patients do display significantly higher levels of oxidized CoQ10 . Oxidized CoQ10 can generate superoxide and hydrogen peroxide. Hydrogen peroxide can then react with iron-rich cytochromes to form hydroxyl free radicals .

In an open-label dose escalation study, 31 ALS patients received CoQ10, formulated with 300 IU of vitamin E, on a monthly dosage escalation scale (1200–3000 mg/day). CoQ10 was found to be safe and well-tolerated at the maximum dosage. When compared with a placebo group from a previous clinical trial, no differences between CoQ10 and historical placebo groups were observed in strength, grip, forced vital capacity, or ALS functional rating scale scores . These pilot data have yielded a follow-up randomized, double-blind, placebo-controlled multicenter trial now in progress .

Alpha-lipoic acid

Alpha-lipoic acid is an antioxidant and also a cofactor for mitochondrial enzymes. In a study with G93A/SOD-1 mice, alpha-lipoic acid (0.05% in food) beginning at 4 weeks of age showed a significant delay in onset of impaired motor performance, increased survival, and attenuated weight loss in treated mice compared with controls .

L-carnitine

L-carnitine is an essential cofactor for the beta-oxidation of long-chain fatty acids in mitochondria. It has also been shown to inhibit mitochondrial damage and apoptosis in vitro and in vivo. Early oral administration of L-carnitine significantly delayed symptom onset, prolonged motor function as assessed by rotorod, and extended survival in SOD-1 transgenic mice. In a second experiment, 20 transgenic mice were injected with L-carnitine every two days after symptom onset. Survival of these mice was compared with that of 20 transgenic mice not receiving injections. Treatment with subcutaneous L-carnitine increased survival .

Glutathione, N-acetyl-cysteine, and pro-cysteine

Glutathione peroxidase activity has been shown to be lower in plasma and cerebrospinal fluid of patients who have ALS . This observation has led to an open-crossover study, which failed to demonstrate any benefit in measures of manual muscle testing, Norris functional scale ratings, or forced vital capacity .

Cysteine supplementation has been hypothesized to increase intracellular concentrations of glutathione; however, neither intravenous nor oral pro-cysteine had any effect on cerebrospinal concentrations of glutathione with 29 days of treatment . Likewise, in a randomized, double-blind, placebo-controlled clinical trial of acetylcysteine in ALS patients, no significant differences were seen in survival and disease progression between the two groups .

Studies of N-acetylcysteine (NAC) in transgenic mice models have produced conflicting results. In at least one study, transgenic mice given NAC (1% concentration) in drinking water beginning 4–5 weeks of age, showed significantly improved survival and delayed symptom . An earlier study, with similar dosages given after symptom onset, showed no benefit .

Herbs and L-carnosine

In vitro experiments with ginseng suggest that it may act to decrease calcium flux into neurons. In the SOD-1 transgenic mice, Panax quiquefolium ginseng (100 μg, 200 μg versus control) was added to drinking water. Ginseng treated mice had significantly delayed symptom onset and prolonged survival . Similar controlled trials have not been done in the patient population.

EGb761 is a standardized extract of Ginkgo biloba that has shown antioxidant properties in vitro. When tested in the same G93A/SOD-1 transgenic mice, EGb761 (0.022% or 0.045% via diet) significantly prolonged survival and decreased loss of motor neurons in the spinal cords of male transgenic mice but not in female mice. This gender-specific protection, while provocative, is currently unexplained .

Functional foods

Red wine is known to be rich in antioxidant compounds. Lyphilized red wine was dissolved in the drinking water of eight transgenic mice. Supplemented mice were compared with a control group of seven control transgenic mice not receiving treatment. The treatment group displayed significantly prolonged survival .

Epigallocatechin gallate (EGCG) is a major catechin in green tea. It has been shown to display antioxidant, anti-inflammatory, and iron-chelating properties in vitro. Eleven transgenic mice and six wild-type mice received EGCG by intraoral injection (10 mg/kg). Eleven transgenic mice serving as controls did not receive the injections. ECGC significantly delayed symptom onset and prolonged survival. The compound also significantly decreased markers of neuroinflammation and oxidative stress .

In another study of transgenic mice receiving intraoral injections of one of three different dosages of EGCG or control vehicle, dosages of 2.9 mcg/g and 5.8 mcg/g of EGCG also significantly delayed symptom onset and prolonged survival. Treatment was also associated with protective effects on markers of cell signaling associated with cell death and cell survival .