0:00:00.000,0:00:03.000 So I am a pediatric cancer doctor 0:00:03.000,0:00:07.000 and stem-cell researcher at Stanford University 0:00:07.000,0:00:10.000 where my clinical focus has been bone marrow transplantation. 0:00:10.000,0:00:12.000 Now, inspired by Jill Bolte Taylor last year, 0:00:12.000,0:00:14.000 I didn't bring a human brain, 0:00:14.000,0:00:17.000 but I did bring a liter of bone marrow. 0:00:17.000,0:00:20.000 And bone marrow is actually what we use 0:00:20.000,0:00:22.000 to save the lives of tens of thousands of patients, 0:00:22.000,0:00:25.000 most of whom have advanced malignancies like leukemia and lymphoma 0:00:25.000,0:00:27.000 and some other diseases. 0:00:27.000,0:00:31.000 So, a few years ago, I'm doing my transplant fellowship at Stanford. 0:00:31.000,0:00:33.000 I'm in the operating room. We have Bob here, 0:00:33.000,0:00:35.000 who is a volunteer donor. 0:00:35.000,0:00:37.000 We're sending his marrow across the country to save the life 0:00:37.000,0:00:39.000 of a child with leukemia. 0:00:39.000,0:00:41.000 So actually how do we harvest this bone marrow? 0:00:41.000,0:00:45.000 Well we have a whole O.R. team, general anesthesia, nurses, 0:00:45.000,0:00:47.000 and another doctor across from me. 0:00:47.000,0:00:49.000 Bob's on the table, and we take this sort of small needle, 0:00:49.000,0:00:51.000 you know, not too big. 0:00:51.000,0:00:53.000 And the way we do this is we basically 0:00:53.000,0:00:55.000 place this through the soft tissue, 0:00:55.000,0:00:57.000 and kind of punch it into the hard bone, 0:00:57.000,0:00:59.000 into the tuchus -- that's a technical term -- 0:00:59.000,0:01:03.000 and aspirate about 10 mls of bone marrow out, 0:01:03.000,0:01:05.000 each time, with a syringe. 0:01:05.000,0:01:08.000 And hand it off to the nurse. She squirts it into a tin. 0:01:08.000,0:01:11.000 Hands it back to me. And we do that again and again. 0:01:11.000,0:01:13.000 About 200 times usually. 0:01:13.000,0:01:15.000 And by the end of this my arm is sore, I've got a callus on my hand, 0:01:15.000,0:01:17.000 let alone Bob, 0:01:17.000,0:01:19.000 whose rear end looks something more like this, 0:01:19.000,0:01:21.000 like Swiss cheese. 0:01:21.000,0:01:25.000 So I'm thinking, you know, this procedure hasn't changed in about 40 years. 0:01:25.000,0:01:27.000 And there is probably a better way to do this. 0:01:27.000,0:01:30.000 So I thought of a minimally invasive approach, 0:01:30.000,0:01:32.000 and a new device that we call the Marrow Miner. 0:01:32.000,0:01:34.000 This is it. 0:01:34.000,0:01:37.000 And the Marrow Miner, the way it works is shown here. 0:01:37.000,0:01:39.000 Our standard see-through patient. 0:01:39.000,0:01:41.000 Instead of entering the bone dozens of times, 0:01:41.000,0:01:43.000 we enter just once, into the front of the hip or the back of the hip. 0:01:43.000,0:01:46.000 And we have a flexible, powered catheter 0:01:46.000,0:01:49.000 with a special wire loop tip that stays inside the crunchy part of the marrow 0:01:49.000,0:01:52.000 and follows the contours of the hip, as it moves around. 0:01:52.000,0:01:54.000 So it enables you to very rapidly aspirate, 0:01:54.000,0:01:57.000 or suck out, rich bone marrow very quickly through one hole. 0:01:57.000,0:01:59.000 We can do multiple passes through that same entry. 0:01:59.000,0:02:01.000 No robots required. 0:02:01.000,0:02:04.000 And, so, very quickly, Bob can just get one puncture, local anesthesia, 0:02:04.000,0:02:08.000 and do this harvest as an outpatient. 0:02:08.000,0:02:11.000 So I did a few prototypes. I got a small little grant at Stanford. 0:02:11.000,0:02:13.000 And played around with this a little bit. 0:02:13.000,0:02:15.000 And our team members developed this technology. 0:02:15.000,0:02:19.000 And eventually we got two large animals, and pig studies. 0:02:19.000,0:02:21.000 And we found, to our surprise, that we not only got bone marrow out, 0:02:21.000,0:02:24.000 but we got 10 times the stem cell activity 0:02:24.000,0:02:26.000 in the marrow from the Marrow Miner, compared to the normal device. 0:02:26.000,0:02:29.000 This device was just FDA approved in the last year. 0:02:29.000,0:02:32.000 Here is a live patient. You can see it following the flexible curves around. 0:02:32.000,0:02:35.000 There will be two passes here, in the same patient, from the same hole. 0:02:35.000,0:02:37.000 This was done under local anesthesia, as an outpatient. 0:02:37.000,0:02:40.000 And we got, again, about three to six times more stem cells 0:02:40.000,0:02:43.000 than the standard approach done on the same patient. 0:02:43.000,0:02:46.000 So why should you care? Bone marrow is a very rich source of adult stem cells. 0:02:46.000,0:02:48.000 You all know about embryonic stem cells. 0:02:48.000,0:02:51.000 They've got great potential but haven't yet entered clinical trials. 0:02:51.000,0:02:53.000 Adult stem cells are throughout our body, 0:02:53.000,0:02:55.000 including the blood-forming stem cells in our bone marrow, 0:02:55.000,0:02:57.000 which we've been using as a form of stem-cell therapy 0:02:57.000,0:02:59.000 for over 40 years. 0:02:59.000,0:03:02.000 In the last decade there's been an explosion of use 0:03:02.000,0:03:05.000 of bone marrow stem cells to treat the patient's other diseases 0:03:05.000,0:03:07.000 such as heart disease, vascular disease, 0:03:07.000,0:03:09.000 orthopedics, tissue engineering, 0:03:09.000,0:03:11.000 even in neurology to treat Parkinson's 0:03:11.000,0:03:13.000 and diabetes. 0:03:13.000,0:03:15.000 We've just come out, we're commercializing, this year, 0:03:15.000,0:03:17.000 generation 2.0 of the Marrow Miner. 0:03:17.000,0:03:19.000 The hope is that this gets more stem cells out, 0:03:19.000,0:03:21.000 which translates to better outcomes. 0:03:21.000,0:03:23.000 It may encourage more people to sign up to be 0:03:23.000,0:03:25.000 potential live-saving bone marrow donors. 0:03:25.000,0:03:27.000 It may even enable you to bank 0:03:27.000,0:03:29.000 your own marrow stem cells, when you're younger and healthier, 0:03:29.000,0:03:32.000 to use in the future should you need it. 0:03:32.000,0:03:34.000 And ultimately -- and here's a picture of our 0:03:34.000,0:03:36.000 bone marrow transplant survivors, 0:03:36.000,0:03:38.000 who come together for a reunion each year at Stanford. 0:03:38.000,0:03:40.000 Hopefully this technology will let us 0:03:40.000,0:03:42.000 have more of these survivors in the future. 0:03:42.000,0:03:44.000 Thanks. 0:03:44.000,0:03:50.000 (Applause)