Table 2.
New and experimental treatments.
| Type of therapy | Mechanism of action | Compound/drug | Evidence | References |
|---|---|---|---|---|
| Drug Therapy | Increase cellular concentration of mitochondrial NAD+ | KL1333 | KL1333 has been shown to improve mitochondrial biogenesis and function in fibroblast line derived from a MELAS patient. No in vivo studies yet. | [82] |
| Increase cellular concentration of mitochondria concentration | Omaveloxolone | Well tolerated and improved lowering heart rate and lactate levels during submaximal exercise, did not significantly change peak exercise workload in MM. | [83] | |
| REN001 | PPAR β/δ agonist shown to improve fatigue and function in patients with fatty acid oxidation defects. Phase II trials in MM ongoing. | [84] | ||
| Bezafibrate | Modest improvement in cardiac function and reduction in immunodeficient muscle fibers in MM patients | [85] | ||
| Acipimox | Acipimox has been shown to improve mitochondria expression in vitro. Phase I clinical trials in adult MM patients ongoing. | [86,87] | ||
| Protecting mitochondria from damage | Elamipretide | Shown to be associated with clinical and functional improvements in children and adults with MM. | [[88], [89], [90], [91], [92], [93]] | |
| Restoring mitochondrial homeostasis | Deoxynucleoside therapy | Use in patients with TK2 deficiency showed improved motor and respiratory function | [[94], [95], [96]] | |
| Enzyme replacement | Erythrocyte Encapsulated Thymidine Phosphorylase (EE-TP) | Use of patients with MNGIE showed clinical improvement and reductions in thymidine, and deoxyuridine. | [[97], [98], [99]] | |
| Dietary supplementation | Correct taurine modification defect at the first anticodon nucleotide of mitochondrial tRNALeu(UUR) | High dose taurine | Use in MELAS patients was shown to reduce frequency of stroke-like episodes and improved taurine modification of mitochondrial tRNALeu(UUR) from peripheral blood leukocytes | [100] |
| Improve systemic NAD+ deficiency | Niacin | Oral niacin supplement increased blood NAD+ up to 8-fold and muscle NAD+ up to level of controls | [101,102] | |
| Influencing glutamate-glutamine cycle and glutamine transporters in the blood-brain barrier | High dose glutamine | Significant reduction in CSF glutamate and increment of CSF glutamine level in MELAS patients | [103] | |
| Stimulate mitochondrial function | Resveratrol | In vitro studies suggest improvements in mitochondrial fatty oxidation. However in vivo studies demonstrate lack of improvement in exercise capacity in adults with MM. | [104,105] | |
| Dietary manipulation | Stimulate mitochondrial function | Ketogenic diet | Positive impact on mitochondrial bioenergetics, mitochondrial ROS/redox metabolism and mitochondrial dynamics | [106] |
| Exercise therapy | Improve oxidative capacity and activity tolerance | Aerobic training | Aerobic training improves mitochondrial volume. Uncertain effect on muscle strength, effort tolerance and quality of life. | [61,61,107,108] |
| Device | Reduce oxidative stress | Near-infrared light-emitting diode | In vitro evidence as an effective antioxidant therapy | [109,110] |
| Modulate cortical and subcortical functional abnormalities | Transcranial direct current stimulation | Improved mitochondrial function and attenuated mitochondrial damage in mouse models. Aided improved clinical outcomes in autism, dyslexia and attention deficit. | [111,112] | |
| Surgery | Alleviate symptoms due to ptosis-related impairment of visual axis and head posture | Ptosis surgery in CPEO | Ptosis surgery (levator resection or frontalis silicone sling surgery) in patients with CPEO showed statistically significant improvement in marginal-to-reflex distance (MDRI) and chin-up posture. | [113] |
| Gene therapy | tRNA modification | MTO1 overexpression fully restored 5-taurinomethyluridine frequency and partially increased the aminoacylation efficiency of MELAS tRNA, leading to the upregulation of mitochondrial protein synthesis and respiratory activity in MELAS myoblasts in vitro. | [114] | |
| AAV gene delivery | Administration of human NDUFS4 coding sequence by AAV2/9 and/or AAV-PHP.B vectors improved clinical phenotype and prolonged the lifespan in Leigh syndrome mouse models | [[115], [116], [117]] | ||
| AAV9 delivery of human TK2 cDNA delaying disease onset and extending lifespan in mouse models. | [96] | |||
| Mitochondrial targeting with recombinant oligoribonucleotides | In vitro studies showed improved heteroplasmy proportions of mutant mtDNA in cultured cells with KSS mtDNA deletion and with mtDNA ND5 point mutation. | [118,119] | ||
| CRISPR-Cas9-mediated mitochondrial genome editing | In vitro studies in human cell lines and zebrafish has shown ability for this to target and reduce mtDNA copy number. | [120,121] | ||
| CRISPR-free base editing | In vitro studies have shown application for mitochondrial base editing in human cell lines, mice, zebrafish and plants. | [[122], [123], [124]] | ||