Tag Archives: Anti-VEGF

MEDICAL VIEWS: ‘MACULAR DEGENERATION RESEARCH’

Macular degeneration is a leading cause of visual impairment in people over 65 and can lead to blindness. One in three people will eventually suffer some degree of macular degeneration, which is caused by abnormal blood vessels under the retina, the light-sensitive part of the eye. We treat both the more common “dry” as well as the more dangerous “wet” forms of macular degeneration. While there is currently no cure for this disease, we offer the latest treatments to reduce the risk of vision loss and blindness. These include anti-VEGF drugs—which attack proteins that create the abnormal blood vessels that cause macular degeneration—and photodynamic therapy, in which patients ingest medication that is then activated with a laser.

To learn more about macular disease at Yale, visit: https://www.yalemedicine.org/departme…​.

COMMENTARY:

This high quality video shows several aspects of macular degeneration. It discusses treatments with stem cells that are in the research phase; in the future there may be replacements for the abnormal support cells, the vascular cells and pigmented epithelium, that are diseased in macular degeneration.

Current treatment centers on control of abnormal blood vessels either by photo active laser, laser coagulation, or anti-VEGF.
Macular degeneration has two forms, wet and dry. The wet macular degeneration has accumulations, or Drusen, under the epithelium. There are also machines to check the thickness of the macula, which is an aid in diagnosis.

The main symptom of macular degeneration or loss of vision especially in The center of the visual field, which is essential for reading.
As I mentioned in my podcast, I made a posting on macular degeneration that includes an amsler grid. Some early symptoms of macular degeneration include waviness of the lines of this grid. Certainly if you have any visual distortion or loss you should see an ophthalmologist.

If your medical plan permits it, I feel but a regular check buy an ophthalmologist approximately every 6 to 12 months, is very useful. My own ophthalmologist checks my  retinal thickness, optic nerve, pressure and peripheral Field ( to pick up glaucoma) as well as my vision on each visit.

Dr. C.

STANFORD: RESEARCHERS FIND WAY TO “REGROW” NEW CARTILAGE IN JOINTS

The Stanford researchers figured out how to regrow articular cartilage by first causing slight injury to the joint tissue, then using chemical signals to steer the growth of skeletal stem cells as the injuries heal. The work was published Aug. 17 in the journal Nature Medicine.

“Cartilage has practically zero regenerative potential in adulthood, so once it’s injured or gone, what we can do for patients has been very limited,” said assistant professor of surgery Charles K.F. Chan, PhD. “It’s extremely gratifying to find a way to help the body regrow this important tissue.”

STANFORD MEDICINE (Aug 17, 2020): Researchers at the Stanford University School of Medicine have discovered a way to regenerate, in mice and human tissue, the cushion of cartilage found in joints.

Loss of this slippery and shock-absorbing tissue layer, called articular cartilage, is responsible for many cases of joint pain and arthritis, which afflicts more than 55 million Americans. Nearly 1 in 4 adult Americans suffer from arthritis, and far more are burdened by joint pain and inflammation generally.

Read full article

COMMENTARY

Stanford has come up with a Promising new approach to the surgical treatment of osteoarthritis. Unfortunately for the suffering public, this approach is still in the rodent experimental stage.

The pain of osteoarthritis is caused by the LOSS of the CARTILAGE which insulates the bone of the joints. The wonderful cartilage coating prevents the pain which would result from the rubbing of bone on bone. The best solution in osteoarthritis would be to replace the cartilage, and I have no doubt that this will be possible some day.

STEM CELLS is the theoretical method most commonly imagined when it comes to replacing lost tissue.. Brain cells, cardiac muscle cells, and pancreatic islet cells are some of the research areas. The development of stem cells from the cells of the Patient herself (iSCs) obviates the need for immunosuppression, which plagues allographs ( stem cells or organs from other humans).

Recently, in situ transformation of neighboring cells has been described, which sidesteps the need to introduce any cells. For instance the transformation of astrocytes (a type of brain cell) into neuronal stem cells of the dopamine lineage would be a great boon to Parkinson’s disease.

The Stanford method somewhat resembles this last-mentioned technique. An injury is created where the cartilage is desired. Like any injury, bleeding, clotting, and cell infiltration follows, destined to form a scar. However, the researchers added BMP-2, which in this milieu causes the pro-fibroblasts to head toward the bone (osteoblast) lineage. Since cartilage forms first in a tissue destined to be bone, they then added a VEGF antagonist, which interrupts the transformation in the desired cartilage stage. Both BMP-2 and anti-VEGF have already been approved for use, facilitating the development of this attractive therapy.

The researchers have even identified an excellent potential Patient Population: Osteoarthritis patients scheduled for surgical removal of the first metacarpal articulation with the wrist. They could do their procedure on this area, and if there is no benefit, They could just go ahead with the original plan of removal. The thumb happens to be one of my most painful arthritic areas.

I will most interestedly follow their research.

–Dr. C.