Appointments: 314-514-3500 Appointments: 314-432-3600
Blog Topic: Latest Publication on Intraoperative
Halo-femoral Traction
1-26-2022
This study was just
published in the Journal of Spine Deformity
For those
interested to read more please use this hyperlink supplied by the publisher:
https://rdcu.be/cFHmd
Blog Topic: What is a “Spine Fusion”
1-16-2022
In the average, normal spine there are 7 cervical, 12
thoracic, and 5 lumbar vertebra, a sacrum and coccyx.
From the skull to the sacrum, each vertebra is separated by a mobile disc, which is a highly complex structure which provides stability and motion at the same time.
In spinal deformity, such as scoliosis, the spine twists and
bends, first through the discs and then the actual vertebra start to become
misshapen, more trapezoidal instead of being more rectangular.
When we do surgery to correct spinal deformity (scoliosis)
the first step is to get fixation into the vertebra so we can move those
vertebra to a better, more desired position and then hold this new position
firmly. In 2022 the most secure and most
commonly utilized spine fixation are metal pedicle screws (usually made of
titanium +/- cobalt chrome), which are placed from the back of the spine, into
the bone, through the pedicle and into the vertebra.
Alternatively, hooks, wires and bands can also be used but these
are not as good a fixation option when compared to screws.
The next step is to connect these screws (or hooks, wires,
and bands) together with rods. These
rods can then move the screws (or hooks, wires, and bands) to the desired position
and then held rigidly in the new position.
These rods, in my practice, are 98% of the time are cobalt chrome, the
stiffest metal currently available and can obtain the optimal 3-d alignment of
the spine in my hands.
These metal screws and rods are VERY strong and
durable. However, we know the day we
place them in surgery is when they are their strongest and have the strongest
grip/fixation on the spine, and each day that goes by after surgery the metal
gradually and almost imperceptibly gets weaker and the screws/hooks/wires/bands
can get looser in/on the bone.
So 1 of 3 outcomes happen after we do spine surgery, at EACH
VERTEBRAL LEVEL:
1. 1. The screws, hooks, wires, bands get loose from
the bone.
2. 2. The rods, screws, hooks, wires and bands break.
3. 3. The spine fuses.
To achieve a spine fusion, we roughen the area to be fused with a drill, and then place bone graft. The body then breaks down/dissolves the bone graft which is then used by bone cells to create a solid bony connection over the area we want to fuse.
The aim of bone graft is to develop a spine fusion before
the spine implants get loose from the bone or break.
Next blog post will discuss the different type of bone
grafts.
Blog Topic: What is ApiFix?
1-2-2022
In previous posts the
Anterior Vertebral Body Tethering (VBT) has been presented. This implant utilizes the flexibility of the
growing thoracic spine, and its growth, to straighten the spine and then
modulates its growth through the remainder of spinal growth. There has been a lot of social media interest
and publications about this procedure over the last several years touting its
benefits, which are small incisions, rapid recovery, and the ability to correct
the spine deformity yet not fuse the spine which preserves some of the spinal
motion. The challenges of this procedure have also been well-documented, such
as how much tension to apply to the tether/spine, how many levels to tether,
and chronologic timing of the procedure (when to do the procedure).
Interestingly, an alternative
procedure was approved the same month (8/2019), the ApiFix device. There has been a lot less attention give to
the ApiFix device, compared to the VBT procedure. So the question is why?
Why has all the focus been on
VBT and not ApiFix?
Some reasons:
1. 1. VBT has been used
by pediatric spine surgeons in the U.S. since the 2010s, although in an
unlabeled manner. Whereas ApiFix was
developed in Israel and used only outside the U.S. Hence more surgeon in the U.S. are familiar
to the VBT procedure than ApiFix
2. 2. To many the
ApiFix looks and acts similar to a traditional growing rod. Whereas the VBT is inserted through small incisions,
placed on the anterior spine and uses a tether as opposed to a lot of metal.
3. 3. Due to the longer
surgeon experience with VBT, dramatically more research has been produced on
VBT.
4. 4. Currently, any
pediatric spine surgeon who undergoes a short training session can perform the
VBT procedure. For the ApiFix device the
company is performing a study on all patients in the U.S., so all surgeons who
use the device undergo more rigorous training and all patients will be
studied. This means there are far fewer
surgeons in the U.S. performing the ApiFix surgery than VBT
5. 5. As a continuation
of #4, since all patients are going to be in the FDA study on ApiFix there is
strict criteria as to who can undergo the procedure. The VBT procedure is left up to each surgeon
to determine is applicability and effectiveness for each patient.
The effectiveness of VBT and
ApiFix for each patient requires an in-depth discussion between patient/family
and the surgeon. At present there is no
scientific evidence of the superiority of either system
Blog Topic: Gustavus Health Professions Podcast
12-19-2021
This fall I had the wonderful opportunity to be interviewed by Heather Banks and Heidi Selzler-Bahr for the Gustavus Health Professions Podcast. This was impactful for me as Gustavus Adolphus College in St. Peter, Minnesota is my alma mater. This small, Lutheran, liberal arts college (about 90 minutes from Minneapolis) and provided me the opportunity to grow in all facets of my life. It helped launch my career in medicine.
If you are interested to hear this podcast, copy and past the below webpage address into your browser:
https://anchor.fm/heather-banks/episodes/Orthopaedic-Pediatric-Surgeon-Dr--Luhmann--86-e1aht86
Blog Topic: New publication comparing MAGEC
Growing Rods, Posterior Spinal Fusion and Vertebral Body Tether in 8-11 year
old scoliosis patients.
Spine (Phila Pa 1976). 2021 Oct 1.
doi:
10.1097/BRS.0000000000004245. Online
ahead of print.
Magnetically
Controlled Growing Rods (MCGR) Versus Single Posterior Spinal Fusion (PSF)
Versus Vertebral Body Tether (VBT) in Older Early Onset Scoliosis (EOS)
Patients: How Do Early Outcomes Compare?
Catherine Mackey 1, Regina Hanstein, Yungtai Lo, Majella Vaughan, Tricia St Hilaire, Scott J Luhmann, Michael G Vitale, Michael P Glotzbecker, Amer Samdani, Stefan Parent, Jaime A Gomez, Pediatric Spine Study Group
Affiliations expand
·
PMID: 34610613
·
DOI: 10.1097/BRS.0000000000004245
Abstract
Study design: Retrospective review of prospective data from multicenter
registry.
Objective: Compare outcomes of posterior spinal fusion (PSF) versus
magnetically controlled growing rods (MCGR) versus vertebral body tethers (VBT)
in 8- to 11-year-old idiopathic early onset scoliosis (EOS) patients.
Summary of background data: In EOS, it is unclear at what age the benefit
of growth-sparing strategies outweighs increased risks of surgical
complications, compared with PSF.
Methods: One hundred thirty idiopathic EOS patients, 81% female, aged
8-11 at index surgery (mean 10.5 yrs), underwent PSF, MCGR, or VBT. Scoliosis
curve, kyphosis, thoracic and spinal height, complications, and Quality of Life
(QoL) were assessed preoperatively and at most recent follow-up (prior to final
fusion for VBT/MCGR).
Results: Of 130 patients, 28.5% received VBT, 39.2% MCGR, and 32.3% PSF.
The VBT cohort included more females (P < 0.0005), was older (P <
0.0005), more skeletally mature (P < 0.0005), and had smaller major curves
(P < 0.0005). At follow-up, scoliosis curve corrected 41.1 ± 22.4% in VBT,
52.2 ± 19.9% in PSF, and 27.4 ± 23.9% in MCGR (P < 0.0005), however, not all
VBT/MCGR patients finished treatment. Fifteen complications occurred in 10
VBTs, 6 requiring unplanned surgeries; 45 complications occurred in 31 MCGRs,
11 requiring unplanned surgeries, and 9 complications occurred in 6 PSFs, 3
requiring unplanned revisions. Cox proportional hazards regression adjusted for
age, gender, and preoperative scoliosis curve revealed that MCGR (hazard ratio
[HR] = 21.0, 95% C.I. 4.8-92.5; P < 0.001) and VBT (HR = 7.1, 95% C.I.
1.4-36.4; P = 0.019) patients were at increased hazard of requiring revision,
but only MCGR patients (HR = 5.6, 95% C.I. 1.1-28.4; P = 0.038) were at an
increased hazard for unplanned revisions compared with PSF. Thoracic and spinal
height increased in all groups. QoL improved in VBT and PSF patients, but not
in MCGR patients.
Conclusion: In older idiopathic EOS patients, MCGR, PSF, and VBT controlled
curves effectively and increased spinal height. However, VBT and PSF have a
lower hazard for an unplanned revision and improved QoL.Level of Evidence: 3.
Blog Topic:
Talking Points
between Surgeon and Patient/Family about Thoracic Vertebral Body Tethering vs.
Thoracic Posterior Spinal Fusion
Vertebral Body Tethering (VBT) is a procedure which has
garnered a lot of attention from surgeons, patients and families. Below is a list of talking points which
should be known about VBT so there can be informative, educated, transparent
discussions about VBT, when compared to the other commonly-performed procedure
Posterior Spinal Fusions. Discussions on
these points is necessary before VBT surgery between the surgeon and
patients/families to be fully-informed.
|
Tether |
Posterior Spinal Fusion |
||
|
Preoperative |
|||
|
FDA approved |
Yes |
Yes |
|
|
FDA approved diagnoses |
Idiopathic only |
All diagnoses |
|
|
Length of Time Procedure has been Performed in U.S. |
About 16 years |
>100 years; >45 years with metal implants |
|
|
Skeletal Maturity Risser |
0 to 2 |
Any |
|
|
Skeletal Maturity Sander Grade |
2 to 4 |
Any |
|
|
Curve Size |
45 to 60 degrees |
>50 degrees |
|
|
Curve Flexibility |
Sidebender <30 degrees |
Not applicable |
|
|
Compensatory Curve Size |
<45 degrees |
Any size |
|
|
Surgical |
|||
|
Incisions, Total Number |
3 to 5 |
1 |
|
|
Incisions, Total Length |
10 cm |
25 cm |
|
|
General Surgeon Assisting? |
Yes |
No |
|
|
Need to deflate one lung? |
Yes |
No |
|
|
Major Curve Correction, Immediate |
Mild to Moderate |
Moderate to High |
|
|
3D correction |
Mild to Moderate |
Moderate to High |
|
|
Length of Hospital Stay |
3 days |
3 days |
|
|
Risk of Complications |
Low |
Low |
|
|
After Discharge |
|||
|
Return to Sports |
6 weeks to 3 months |
6 months |
|
|
Loss of Flexibility |
Little |
Moderate, depends on fusion length |
|
|
Risk of Reoperation |
>20% |
<3% |
|
|
Curve correction over time |
Low to High |
None |
|
|
Risk of Implants Breaking |
100% |
<1% |
|
|
Predictability of Outcome |
Uncertain |
High |
|
|
Long-term Outcome |
Uncertain |
Good |
Thanks to Dr. Mike Vitale, Columbia University in New York,
for discussing this topic and providing the concept idea at the ICEOS meeting
in Salt Lake City.
