Q&A with Dr. Aaron Gardner

what? jahoda's DSC cells only? and in his wife's arm? what about rejection? why did jahoda do that? why not in his own arm?

what? jahoda's DSC cells only? and in his wife's arm? what about rejection? why did jahoda do that? why not in his own arm?

and if DSC cells could do that trick alone, why not concentrate on multiplying those cells and inject them instead?

man, i'm totally confused now. i'm lost. it feels like the cure is here already but nobody is willing to go the final step =D

ok, so then it absolutely makes sense what Replicel does. i was wondering why they were going the way with DSC cells.

i'm not sure if DSC cells are also that difficult do expand like DP cells.

but the big difference here: if DSC cells could do that trick ALONE, it would be a much easier way i assume, because no need for complex 3D culturing of more than one different cells. (3D spheres, with coating of epithelial cells, and maybe even add DSC cells into the mix).

we need more information about that experiment. it seems too good to be true.

and maybe Dr. Xu is able to convert iPS cells into DSC cells already. if not, who knows... maybe he can figure it out faster than converting to DP cells.

with what cell types are currently working in the lab? (of which cells does the follicle consist?)

DP cells
DSC cells
Epithelial cells
ECM? we heard the extracellular matrix is build up automatically when the DP cells come and interact together (according to team Lauster)

are you able (and other researches too) to isolate EVERY different cell type out of the follicle? or is there still a cell type which makes problems and can't be isolated for multiplitication?

Dr. Gardner,

Have you read much about the PGD2 research (eg http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3319975/ and http://www.ncbi.nlm.nih.gov/pubmed/24521203 ) and if so may we have your opinion on the potential of this pathway?

Thanks a lot.

Dr. Gardner,

Have you read much about the PGD2 research (eg http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3319975/ and http://www.ncbi.nlm.nih.gov/pubmed/24521203 ) and if so may we have your opinion on the potential of this pathway?

Thanks a lot.

Aaron, some time ago Desmond posted this link: http://online.liebertpub.com/doi/abs....TEA.2013.0547 and we thought that hairloss was cured since it seemed these guys could now culture cells while keeping all genes expressed. But re-reading that abstract they dont specifically say that 100% genes were expressed. What do you think ? Cause if I understand correctly, once we can culture dp cells (enough of them) while retaining 100% gene expression, then we've overcome a major hurdle and you guys can focus on things like hair growth direction etc, right ?

Dr. Gardener, Has there been any thought regarding your research about injecting the 40% of cultured cells that have reclaimed their genetic character into a balding scalp to see if they can rejuvenate miniaturized follicles, as opposed to creating follicles denovo? And do you have any thoughts as to whether this might be effective, at least to an extent far greater than what Aderans and Replicel have been able to achieve to date? My understanding is that these concepts have been in large part unsuccessful because the cells they are culturing have lost their inductivity. If this is indeed the reason, perhaps the rejuvenation concept is the quickest way forward.

I don't quite understand this;

3D culture as we currently do it is relatively laborious. For example creating ~500 spheres would take about an hour. These need to be fed manually every 3 days which would take several hours. There are ways of automating this though, we just don't do this.

Does this mean that the spheres after about an hour would be ready to implant into the scalp, but if held for preservation to implant at a later date, they must be fed every 3 days?

Would this then mean from culturing to implanting we could see all of it done in a matter of hours?

Thanks Dr. Gardner for your time and patience.

It seems to me that all the research teams are tackling hair growth one step at a time, as would be expected. I'm glad that you've cleared up the fact that no one has achieved full inductivity retention, or full gene expression (many on here didn't seem to understand the difference).

Two ideas as far as restoring characteristics is concerned
a) would it be of any use to not only combine cells, but also add growth factors such as fg9, or whatever compounds are implicated in the wnt pathway, which seems so crucial to follicle growth?
b) shape-wise, and from a designer's perspective, the sheath cup cells seem to be the most crucial as far as keeping everything in line, would it not make sense to start incorporating these into your mix right away? Maybe your epithelial cells are not "sticky" enough because they are only a second part of the puzzle, and you need all the pieces. Just a thought.

Another thing that I'm curious about is if any of you research teams have any solid ideas of why baldness actually happens in a broader sense. I know it is activated by androgens, but is it a matter of every cell in the scalp being programmed and implicated in these changes, or is it just the DP cells that have the receptors, and are sending signals to the environment- or is it the fat cells controlling the game? It seems a big effort has been made to understand the interaction between fat cells and DP cells, and I'm wondering if the key to retaining inductivity and maintaining hair growth doesn't lie in the interaction with the fat in the skin.

The epithelial, DP, and other hair follicle cells seem to be able to work together to create a follicle, but the fact that these follicles are small in vitro, and not the same as healthy hairs begs the question of what it is that they are missing. I doubt full gene expression is the complete answer, and my guess would be that they need to interact with not only epithelial cells, but also whatever other cells are in the scalp. are fat cells the answer? If so, can you guys begin to culture DP spheroids in a way where they are exposed to healthy fat cells?

I think you're right about it being hard to induce and maintain hair in a balding scalp, and thus I don't think any of the research will go anywhere as far as curing alopecia until the roots of the condition are understood (are they?) . A workaround solution could be the creation of follicles in engineered skin, and then the implantation of these follicles with new surrounding tissue, similar to current transplants.

Are these guys working on an actual cure or treatment, or they only doing research on hair follicle and skin?

ok, so then it absolutely makes sense what Replicel does. i was wondering why they were going the way with DSC cells.

i'm not sure if DSC cells are also that difficult do expand like DP cells.

but the big difference here: if DSC cells could do that trick ALONE, it would be a much easier way i assume, because no need for complex 3D culturing of more than one different cells. (3D spheres, with coating of epithelial cells, and maybe even add DSC cells into the mix).

we need more information about that experiment. it seems too good to be true.

and maybe Dr. Xu is able to convert iPS cells into DSC cells already. if not, who knows... maybe he can figure it out faster than converting to DP cells.

Sorry, I was thinking from a research perspective where we are testing the spheroid cultures. Sphere formation occurs after approximately 24 hours, but I would expect they would be left longer to adhere more tightly to each other.
The DP cell number needs to be increased in 2D expansion culture first which is the time consuming step, so from isolation to re-implantation I think a timeline of 6-8 weeks would be feasible.

Thanks for answering questions Dr. Gardner!

Will the color of these new hairs match the existing hairs?

If you have a head of gray hair will the new hair come out gray?

Thanks again!