Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT03282578 |
| Other study ID # |
MH 2017.165 |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
October 5, 2017 |
| Est. completion date |
November 25, 2018 |
Study information
| Verified date |
April 2019 |
| Source |
University of Melbourne |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Design:
Investigator Initiated Prospective Randomised Trial
Study Centre's:
Melbourne Private Hospital Royal Melbourne Hospital
Study Hypothesis:
Use of the SternaLock 360 will reduce the incidence of sternal motion > 2mm by absolute
difference of 40% at 6 weeks of surgery compared to stainless steel wiring.
Use of the SternaLock 360 will improve bone healing and quality of recovery after surgery
compared to stainless steel wiring
Study Objective:
To determine if the SternaLock 360 system reduces sternal instability, increases bone
healing, and improves quality of recovery compared to stainless steel wiring of the sternum,
after cardiac surgery involving median sternotomy
Inclusion Criteria:
Age ≥ 18 year old Elective cardiac surgery Primary cardiac surgical procedure No evidence of
infection at time of surgery Sufficient English language to complete the Postoperative
Quality of Recovery Survey
Exclusion Criteria:
Previous sternotomy (redo) Clinical sternal deformity Home locality preventing follow-up
(e.g. remote regional, interstate or overseas patient)
Number of Planned Subjects:
50
Description:
Introduction/Background Information Since the inception of cardiac surgery in the early
1960s, division of the sternum has provided the superior access to cardiac structures.
Cardiac surgery may involve treatment of the coronary arteries, valves or major vessels such
as the ascending aorta. In children, correction of congenital malformations is also
performed.
The conventional bone fixation during the 1960s was the placement of stainless steel wires
around or through the sternum, predominantly as single wires which were tensioned by
twisting. In the 1980s, it became fashionable for some cardiac surgeons to pass the wire
twice around the bone (as would be the case repairing a fence on a farm), so-called "figure
of 8" configuration and tensioning again occurring by twisting the wires. There have been no
adequate studies investigating which of these two techniques may be superior.
In simple terms, bone healing is promoted by
- Minimising movement of the bone edges at the fracture site and
- Improved alignment of the bone edges
The sternum is a connecting bone that moves in multiple planes to transfer load and position
the limbs in space during every day functional tasks and respond to the demands of
respiration. The healing of the sternum is in the context of many efforts by the treating
physicians and physiotherapists to encourage activities that might cause distracting forces
at the sternal fracture site. Additionally, simple everyday activities by the patient such as
coughing, deep breathing, sneezing, transferring in and out of bed, turning over in bed and
driving all lead to substantial distracting forces acting on the sternal fracture site1.
External fixation is not encouraged because the patient needs to have significant chest wall
movement in order to breathe and clear sputum as part of the recovery from surgery.
Also, ultrasound data suggests an additional mechanism by which sternal healing is
compromised with conventional sternal wiring techniques. The shape of the sternum is complex
1. The upper part is called the manubrium to which the clavicles and first rib join, and is
generally quite thick with a reasonably robust and cortex and strong marrow. By contrast, the
body of the sternum which forms the majority of the sternum is thinner and the marrow is
frequently less robust than for the manubrium. In both areas, the cortical bone is present
superficially (anterior) and deep (posterior) with the marrow between. When sternal wires are
used, and the two halves of the sternum brought together and tensioned by twisting the wires,
best efforts made to ensure that the cortical bone edges on either side are opposed or well
aligned (that is, that in the anterior and posterior direction that the two bone edges from
either side of well opposed). Generally, this is quite well achieved, but not always. Yet,
even with ultrasound studies performed 1 or 2 days after surgery, the alignment between the
anterior cortical bone edge on either side is lost as detected by the cortical bone of one
side overriding the cortical bone of the other side.
The implications of this ultrasound finding are twofold
1. Irrespective of the perfect alignment of the two sides of the sternal fracture at the
time of surgery under general anaesthetic, coughing and deep breathing usually leads to
distraction forces that results in one side of the divided sternum overriding the other
side, typically by a couple of millimetres or so. This must be because there is less
bone to bone force when the cortical bone edge is being forced against soft tissue or
against the marrow than it would be if it were forced against the cortical bone of the
other side. This is important because any distracting force caused by coughing or deep
breathing or indeed any other activity should logically, result in the two halves of the
sternal bone adopting a position of least force.
2. What this means is that the two halves of the sternum in combination (and after over
riding has occurred) are now less wide than they had been at the time that the sternal
wire was tensioned at the end of the surgical procedure, by the distance of the sternal
override detected by the ultrasound.
Consequences of poor sternal healing: Patients may feel movement of the sternum and that may
limit their activity. However, chronic sternal instability is associated with pain 2, which
may in turn affect other aspects of daily living, require long term medications and
predispose to depression.
SternaLock 360 system The SternaLock 360 system is a band and plating system designed to
improve sternal stability. 3 bands surround the sternum to oppose the bones (like wires), but
an additional 3 plate system prevents anterior posterior displacement and provides a rigid
fixation. CT scan follow up shows improved bone healing at 3 months after surgery compared to
conventional wires, but the CT scan is a poor measurement of dynamic movement. Quality of
recovery and functional status has not been adequately studied.
The unique design of the SternaLock 360 system, is that it combines a
1. Compressive force to the two sternal halves forcing them together (similar to the
principal of the sternal wires), thus counteracting lateral distracting forces.
2. Additionally, by the placement of metal plates that cross the fracture and are fixed on
either side by screws, predominantly the plates acts to prevent anterior/posterior
distracting forces; longitudinal translation and thus better maintain the cortical bone
to cortical bone apposition between the two sides.
Pilot Data Our research group is experienced in assessing sternal motion with ultrasound 4.
We have conducted sternal ultrasound measurements of sternal motion after surgery as part of
clinical follow up.
Over all the SternaLock 360 results in a far greater rigid fixation as noted at the time of
surgical implantation. Subsequent pilot ultrasound studies performed during dynamic
distracting forces (such as coughing) reveal reduced or absent movement at the fracture site
and better preservation of fracture alignment. Ultrasounds have been performed at varying
intervals from Day 1 post-operative to 6 weeks post-operative, and ultrasounds of sternal
wire fixation have been performed at varying intervals after 10 months post-operative. Our
observations are that fewer than 10% of patients who have received the SternaLock 360 have
had motion >2 mm, whereas patients with conventional wiring have motion > 2 mm in more than
50%.
Evidence Gap The SternaLock 360 is an effective system for closing the sternum. There are few
comparative data investigating bone healing with CT scans, but the CT alone is a poor
indicator of sternal instability. There is no long term comparative data on sternal micro
motion, or quality of recovery outcomes to identify whether the SternaLock 360 system will
improve patient centred outcomes over and above improved bone healing.
Study Objectives Hypothesis Use of the SternaLock 360 will reduce the incidence of sternal
motion > 2mm by absolute difference of 40% at 6 weeks of surgery compared to stainless steel
wiring.
Use of the SternaLock 360 will improve bone healing and quality of recovery after surgery
compared to stainless steel wiring.
Study Aims To determine if the SternaLock 360 system reduces sternal instability, increases
bone healing, and improves quality of recovery compared to stainless steel wiring of the
sternum, after cardiac surgery involving median sternotomy.
Randomisation The randomization sequence will be produced using a computer generated
randomization sequence, in unequal blocks. Concealment will be by placing the card containing
the allocation information in double opaque sealed envelopes, and concealment will be
maintained until after recruitment and the patients is admitted to the operating theatre. The
treating surgical team will then open the envelopes to reveal the allocation after (1)
weaning from cardiopulmonary bypass and (2) final confirmation from the treating surgeon that
the patient is suitable to be randomised.
Statistical Methods Participants who are scheduled for cardiac surgery will be screened and
recruited from the cardiac surgery operation lists, surgeon's clinics and pre-operative ward.
The initial contact will be made in person during the first contact session prior to surgery.
In-patients scheduled for cardiac surgery will be screened on the ward.
Medical histories will be reviewed and screened for participant suitability and eligibility.
Once the patient's medical history has been reviewed and the patient's eligibility has been
confirmed, the patient is then approached by the research staff member and the process of
informed consent will proceed.
Power Calculation and Study Size Sample size estimates are based on the primary outcome of
sternal motion > 2 mm at any location at 6 weeks after surgery. From pilot data, fewer than
10% of patients who have received the SternaLock 360 have had motion >2 mm, whereas patients
with conventional wiring have motion > 2 mm in more than 50%. Based on a Fischer's Exact
test, Alpha of 0.05, power of 80% and two-tailed design, 25 participants are required in each
group to detect a difference of 50% to 10% between groups, favoring the SternaLock 360
system. The sample size will increase to 26 in each group to account for an estimated 5%
dropout rate. The total number will be 52 participants.
Statistical Methods To Be Undertaken The primary endpoint will be assessed using the Chi
Squared test on the incidence of sternal motion > 2 mm at 6 weeks after surgery.
Postoperative Quality of Recovery Variables of "recovery" are dichotomized to "recovered" or
"not recovered" based on whether they have returned to their baseline (preoperative) values
or a better result than their preoperative values; at each of the time points when
measurements are performed. A tolerance factor is included in the scoring of cognitive
recovery to allow for performance variability 6. The secondary outcomes of recovery over
time, analysis will be performed using the a general linear mixed model to investigate group
differences over time.
Continuous data will be analyzed using independent samples t test, or repeated measures
analysis of variance (RM ANOVA). A P[Symbol]0.05 will define statistical significance.
References
1. El-Ansary D, Waddington G, Adams R: Trunk stabilisation exercises reduce sternal
separation in chronic sternal instability after cardiac surgery: a randomised cross-over
trialAust J Physiother 2007; 53: 255-60
2. El-Ansary D, Waddington G, Adams R: Relationship between pain and upper limb movement in
patients with chronic sternal instability following cardiac surgery. Physiother Theory
Pract 2007; 23: 273-80
3. Nishimura T, Kurihara C, Sakano Y, Kyo S: Sternalock plating system for elderly
post-sternotomy patients. J Artif Organs 2014; 17: 288-90
4. El-Ansary D, Waddington G, Adams R: Measurement of non-physiological movement in sternal
instability by ultrasound. Ann Thorac Surg 2007; 83: 1513-6
5. Royse CF, Newman S, Chung F, Stygall J, McKay RE, Boldt J, Servin FS, Hurtado I,
Hannallah R, Yu B, Wilkinson DJ: Development and feasibility of a scale to assess
postoperative recovery: the post-operative quality recovery scale. Anesthesiology 2010;
113: 892-905
6. Royse CF, Newman S, Williams Z, Wilkinson DJ: A human volunteer study to identify
variability in performance in the cognitive domain of the postoperative quality of
recovery scale. Anesthesiology 2013; 119: 576-81
