Not long ago, we were all transfixed by 50th anniversary tributes to humankind’s most
daring achievement to date, the Apollo 11 moon landing. At 2 hours 44 minutes and
19 seconds after launch, the crew performed another jaw-dropping procedure. Translunar
injection, a 6-minute burst of Saturn V engines, thrust Apollo 11 out of a low, circular
parking orbit around Earth and catapulted it at 25,000 mph toward its precise target:
the Moon.
The 1969 Moon landing was a monumental feat of human perseverance, technological precision,
and risk management. But behind the thousands of protocols and backup systems were
hundreds of commands for “Mission Abort”. First and foremost was the safety of the
3 occupants.
Exploration of scientific frontiers involves detailed planning, precise execution,
and the awareness of when, for safety purposes, to say when. One of the most exciting
frontiers in our field is the healthy debate about kinematic alignment (KA), which
advocates positioning prosthetics relative to individual constitutional anatomy. Evidence
suggests a myriad of benefits over the previous mainstay, mechanical alignment (MA),
including significantly improved soft-tissue balance requiring fewer releases [[1],
[2], [3], [4], [5]] and enhanced restoration of physiologic gait patterns, adduction
moments, and native knee kinematics [[6], [7], [8]]. Comparative clinical studies
have demonstrated either equivalence or superiority to MA [3,[9], [10], [11], [12],
[13], [14]]. Single-surgeon series [15] and 7-year registry data [16] have alleviated
concerns of premature prosthetic failure.
So, is there a problem, Houston? It is certainly hard to argue against the survivorship
of MA, as 90% of MA patients still have a functioning prosthesis after 20 years [17,18]).
Is it too early to throw away this technique founded on the fundamental principle
of “first, do no harm”? Unfortunately, the one-size-fits-all approach of MA does not
consider the wide range of normal knee anatomy, often resulting in significant gap
asymmetry, soft-tissue imbalance, and unnatural joint line obliquities and heights.
These factors may well contribute to the nearly 20% dissatisfaction rates reported
by our MA patients.
So yes, Houston, we do have a problem …but truly unbounded KA is probably not the
answer either, particularly in patients with extreme anatomies. In these patients,
bony landmarks can no longer be trusted to provide a target for a patient’s constitutional
knee alignment.
Therefore, where to from here? Well, as with any scientific endeavor, accurate planning,
precise execution, and knowing when to abort must be the mantra as we explore options
such as restricted KA (rKA).
Detailed preoperative planning
Detailed premission planning in 1969 ensured Apollo 11 would enter lunar orbit with
pin-point accuracy. In 2021, preoperative planning using high-quality imaging (long
leg radiographs, computed tomography scans, magnetic resonance images) provides the
accuracy to hit the correct alignment targets.
This sort of imaging can quantify the 2 independent variables of joint line obliquity
and prearthritic limb alignment (arithmetic hip-knee-ankle angle) [19]. These parameters
define each patient’s Coronal Plane Alignment of the Knee phenotype [20], a critical
categorization for understanding how knee soft-tissue laxities will behave once implants
are positioned …in MA or KA. Furthermore, when target boundaries are imposed, these
data allow predictions for when minor soft-tissue releases will be required.
However, it is important to acknowledge that both MA and KA reference bony anatomy.
Future planning must go beyond describing constitutional phenotypes and, with the
assistance of intraoperative algorithms, begin quantifying native soft-tissue laxities.
Precise execution
Unfortunately, many current intraoperative techniques fall short of ideal execution
in total knee arthroplasty. Conventional cutting guides lack the required precision,
as 30% of knees will have errors >3° off target [21,22]. Patient-specific cutting
guides have not proven to be any more effective, and neither technique allows for
intraoperative resection validation or assessment of soft-tissue laxities [23].
Precision technologies can mitigate real-world risks. Apollo spacecrafts used 3 sophisticated
positioning systems to stay on target. Computer-assisted surgical navigation (CAS),
with or without the use of robotic cutting arms, is the current undisputed gold standard
for knee alignment precision, as it minimizes deviations from the intended target
[21,22]. Most robotic platforms also provide virtual gap balancing algorithms that
can restore native soft-tissue laxities and reduce the requirements for soft-tissue
releases before any bony resections. The risk of “Mission abort” is minimized now
that true precision is available in the operating room.
Restricted boundaries
Nevertheless, routine restoration of constitutional alignment should not be the goal
for every patient. For those with atypical anatomy (eg, trauma, extra-articular deformity),
KA without boundaries has the potential to inappropriately restore angles that are
biomechanically unsound (eg, constitutional varus of 9°). Worse, imprecise guides
can easily compound alignment errors, increasing the original deformity (say, to 12°).
rKA provides important protections by imposing “safe zone” alignment boundaries to
avoid extreme outliers [3,13,24]. With CAS or robotic techniques, we now use Food
and Drug Administration–approved boundaries of 6° varus to 3° valgus for final HKA
and tibial coronal resections; 6° valgus to 3° varus for distal femoral resections;
and ±6° to the surgical TEA for femoral rotation. These boundaries encompass 85% of
normal individuals [25]. With an rKA philosophy, preoperative planning and intraoperative
CAS validation will minimize implant failure risk and maximize chances that the correct
target alignments are achieved, bone resection thicknesses are minimized, and as a
result, normal soft-tissue laxities are restored.
Keep the journey on course
Full optical navigation, ideally with robotic cutting arms, allows for virtual implant
adjustments before any resections to optimize restoration of soft-tissue laxities.
Surgeon-defined assessment of soft-tissue balance has been shown to be a poor predictor
of the true state of knee balance [26,27], but pressure sensors and other balancing
instruments offer more objective means to quantify soft-tissue laxities.
Buzz Aldrin said, "Your mind is like a parachute: If it isn't open, it doesn't work."
We must keep an open mind in this evolving field of research as adoption of rKA increases.
High-quality randomized trials are needed to determine clinical effectiveness, and
registry surveillance is needed to track implant survivorship. We will all have the
fortune of working in a more reliable total knee arthroplasty universe when we use
modern imaging to understand more about our patients, modern surgical technologies
to precisely navigate the limb …and modern restricted boundaries to know when to abort.
Conflicts of interest
The authors declare that they have no known competing financial interests or personal
relationships that could have appeared to influence the work reported in this article.