Actually, as I watch the full presentation, the new data from Joan Mannick is pretty compelling, as much as I might hate to admit it (I like the fact that everyone who is interested can afford rapamycin and that definitely won’t be the case with Tornado drugs when they are approved).
In her new presentation she’s saying that they’ve dosed as high as 250mg/kg in non-human primates (for 14 days, so its ongoing…) without any significant side effects yet. While its still early, if that holds true over the longer term I think they may have a winner of a product (but sadly, its unlikely I’ll be paying $15K to $20K/month for it).
If you truly can dose their new rapalog drug candidate at 250mg/kg, it suggests that you may be able to get to the higher levels of equivalent lifespan increases that we are seeing in mice at the highest dosing levels of rapamycin (or perhaps higher even, than the 30% median lifespan increase we are seeing in mice). I hope someone has started doing a mouse lifespan study with the Tornado therapeutics candidate molecules!
Just to refresh everyone - here are the results we’ve seen in the past with rapamycin; the higher the dose (generally), the higher the lifespan extension. The downside (for humans) is that we don’t live in a pathogen-free environment (like lab rats / mice). So with higher doses we risk immune suppression and bad (potentially deadly) infections. So the mouse results don’t translate directly to humans.
Most of people currently using rapamycin seem to be (in mouse equivalent dosing) in the low levels tested (note: mice were dosed rapamycin in their food, daily, so that is another difference - vs. us using rapamycin dosed once weekly or so). As you can see, there is a dose/longevity effect for higher dosing of rapamycin and longer lifespan. Many researchers think that is likely due to increased mTOR inhibition, but I wouldn’t say all researchers in this area agree with that theory.
Here are the National Institutes on Aging Results from their rapamycin studies (these are the best rapamycin studies):
Sirolimus
Dose |
mg/kg/day
Dose |
Blood/Sirolimus
Level |
Male Median LS Increase |
Female Median LS Increase |
| 4.7ppm |
∼2.24 |
3 to 4 ng/mL |
3% |
16% |
| 14ppm |
~6.67 |
9-16 ng/mL |
13% |
21% |
| 42ppm |
~20 |
23-80 ng/mL |
23% |
26% |
Here are results from all the higher dose studies I could find:
Sirolimus
Dose |
Mouse
mg/kg/day
Dose |
Mouse:
Blood/Sirolimus
Level |
Human
mg/kg/day
Dose |
Dose for 60kg Human |
Daily Dose adjusted for longer half-life (/4) |
| 4.7ppm |
∼2.24 |
3 to 4 ng/mL |
0.182 mg/kg |
10.92 mg |
2.73 mg |
| 14ppm |
~6.67 |
9-16 ng/mL |
0.542 mg/kg |
32.54 mg |
8.135 mg |
| 42ppm |
~20 |
23-80 ng/mL |
1.626 mg/kg |
97.56 mg |
24.39 mg |
| 126ppm |
~60 |
|
4.878 mg/kg |
292.68 mg |
73.17 mg |
| 378ppm |
~180 |
45 to 1800 ng/mL |
14.634 mg/kg |
878.04 mg |
218 mg |
Based on the FDA animal to human dosing conversion guide here.
Note: ½ life for sirolimus in mice is approx. 15 hours, vs. approx. 62 hours in humans. So, mice metabolize sirolimus approximately 4 times faster than humans.
