Stem Cell Treatment for Optic Nerve Atrophy (ONA)

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How does stem cell therapy work?

Since 2007, we have been developing comprehensive stem cell treatment protocols for optic nerve atrophy (ONA) to overcome the limitations of conventional therapies.

In our protocols, stem cells are combined with specialized therapies for ONA that not only focus on helping the patient to cope with their symptoms, but also treat the root cause of the condition by promoting the healing of the optic nerve. We believe that our comprehensive treatment approach for ONA gives our patients the best chances for vision improvement, allowing for a better quality of life.

Repair optic nerve atrophy using stem cells

The optic nerve acts as a signal transmission channel between the retina in the eye and the visual cortex in brain. When the optic nerve is damaged (atrophy), visual signals become unable to travel freely to the brain and the patient gets affected by partial or total loss of vision.

It is important to remember that optic nerve atrophy can arise from various demyelinating, inflammatory, ischemic or traumatic origins, and conditions such as open angle glaucoma, optic neuritis or Leber hereditary optic neuropathy are among the various causes of ONA. In some cases, the optic nerve atrophy is causing a constant and progressive loss of vision.

Few conventional treatment options are available for patients diagnosed with ONA, which mostly focus on helping the patients to cope with their disability. However, none of them are actually treating the loss of optic nerve function. Stem cells have the ability to regenerate nerve cells in the optic nerve, allowing ONA patients to recover some vision.

What improvements from our treatment?

The purpose of our stem cell treatment is to restore neurological function in the brain/spinal cord lesion area, thus, various kinds of improvement are possible after our treatment and our past patients have experienced the following*:

  • Sharpened visual acuity
  • Enhanced light perception
  • Enlarged visual field
  • Brighter night vision
  • Reduced nystagmus
  • Improved strabismus

*It is important to remember that as for any medical treatment, improvements cannot be guaranteed. Please contact us for more information regarding the possible improvements for a particular case.

More about Optiv Nerve Atrophy (ONA)

What is optic nerve atrophy (ONA)?

Optic nerve atrophy (ONA) is an umbrella term used to describe a number of conditions, which result in vision loss. Optic nerve atrophy can be classified according to the cause of the atrophy, accordingly:

  • Demyelinating
  • Inflammatory
  • Ischemic
  • Traumatic

What causes Optic nerve atrophy?

The cause of ONA is dependent upon the type of atrophy present:

  • Demyelinating ONA, also known as optic neuritis, occurs in conditions such as multiple sclerosis and other demyelinating and inflammatory conditions. Patients often present with rapid loss of vision in one eye, which may be loss in part or all of the visual field.
  • Ischemic ONA results from occlusion of blood vessels supplying the optic nerve and can occur in conditions such as vasculitis, giant cell arteritis, granulomatosis with polyangiitis, and rheumatoid arthritis. Patients with ischemic ONA develop rapidly progressing loss of vision, often in the superior aspect of their visual field.
  • Traumatic ONA results from direct injury to the optic nerve, often from blunt force or accidents such as motor vehicle collisions.
  • Inflammatory ONA, also known as infiltrative neuropathy, results in destruction of the optic nerve from locally invading tumors, infection and autoimmune processes such as sarcoidosis.

How is Optic nerve atrophy diagnosed?

ONA is diagnosed by extensive ophthalmological investigation which may include:

  1. Visual field testing: visual field defects in optic neuropathies can take several patterns including central, diffuse, arcuate, and altitudinal defect. The pattern of visual filed defect is not specific of any etiology and almost any type of field defect can occur with any optic neuropathy. However, altitudinal defects are more common in ischemic optic neuropathies and central, or cecocentral defects frequently accompany toxic/nutritional and hereditary optic neuropathies.
  2. Electrophysiological testing: Visual evoked potential (VEP) are often abnormal in optic neuropathies. Although VEP is not necessary in the diagnosis of optic neuropathy, it can be useful in patients with early or sub-clinical optic neuropathy who may have normal pupillary responses and no discernible optic disc changes on clinical examination
  3. Optical coherence tomography: a relatively new technique which uses low coherence light to penetrate tissue and a camera to analyze the reflected image. By performing circular scans around the optic nerve head, the peripapillary nerve fiber layer can be analyzed. This has been useful in the follow up of patients with optic neuritis, traumatic optic neuropathy, and Leber’s hereditary optic neuropathy

Symptoms of ONA often include tunnel vision (also known as scotoma), blurred vision, and loss of other visual fields. These defects are diagnosed on further investigation using the aforementioned techniques.

What are the current treatments for Optic nerve atrophy?

Currently, there are no effective treatments for ONA. Following destruction of the optic nerve, regeneration of neurons using conventional medical treatment is not possible. Therefore, treatment with novel therapies, such as stem cells, offers a promising hope that regeneration of vision in ONA patients may be a possibility.

How can stem cell treatment restore vision in patients?

The mechanisms by which stem cells deliver their regenerative action are :

  • Secretion of neurotrophic factors before or after differentiation. MSCs release certain neurotrophic growth factors including brain derived neurotrophic factor (BDNF) which may offer neuroprotection.
  • Injection of MSC may result in anti-inflammatory effects, thereby increasing regeneration of neurons located within the optic nerve.
  • Studies in mice have shown that injection of MSCs provided by intravitreal injection were shown to migrate to the surface of the retina and integrate into the nerve fiber layer ultimately forming the optic nerve.