Compartment Syndrome Clinical Trial
Official title:
Management of Compartment Syndrome With Ultrafiltration
This study will test the safety of a new treatment method called tissue ultrafiltration. We
will test this method in the treatment of compartment syndrome, a condition that occurs when
pressure within the muscles builds to dangerous levels. In the legs and other parts of the
body, a tough, stiff membrane covers groups of muscles and the nerves and blood vessels that
run next to and through them. The entire unit is called a compartment. The causes of
compartment syndrome include traumatic leg injuries and loss of blood supply. In tissue
ultrafiltration, a doctor places hollow probes, or catheters, directly into the muscle
compartment in the injured area of the lower leg. The probes remove fluid from the
compartment (extra fluid can cause increased pressure).
We will do an initial safety study in a group of patients who have had surgery for a broken
tibia (the inner, larger bone of the lower leg) and are at high risk for developing
compartment syndrome. The goals of this initial study are to show that inserting tissue
ultrafiltration catheters in the muscle compartment is safe and can be done repeatedly
without problems; to show that tissue ultrafiltration can be used to monitor the biochemical
environment inside tissues; and to show that the catheter apparatus provides an accurate
measurement of pressure in the compartment.
The human clinical trials are organized as a series of consecutive studies designed to
demonstrate the safety and efficacy of ultrafiltration in the management of compartment
syndrome (CS). The first study is a cohort study of patients with tibial shaft fractures
that will test the safety of the catheters as well as demonstrate that ultrafiltration
fibers provide an improved method for monitoring myofascial compartment physiology. The
goals of this study are to (1) demonstrate that inserting ultrafiltration (UF) catheters is
safe and reproducible; (2) show that CSUF allows for biochemical assessment of cellular
function; and (3) show that the CSUF apparatus provides an accurate measurement of
intracompartmental pressure.
The study population will consist of 10 patients with closed or open Gustilo grade I, grade
II, or grade IIIa tibial shaft fractures that require surgical stabilization. We will
recruit patients for the study at the study centers. Data collected during this study will
be numerical values for the biochemical measurements and for the intramuscular pressure
(IMP) measurements. We will compare the CSUF system values for intramuscular pressure with
IMP measured with a Stryker device. Finally, we will correlate serial changes in the
biochemical measures to any changes in IMP. The metabolic assay will show increased UF
levels compared to serum levels.
We will consider fasciotomy when the IMP is within 30 mmHg of the patient's diastolic blood
pressure, or when the clinical examination of the patient demands. We will make repeat IMP
measurements at the time of fasciotomy and record the interval to and reasons for
fasciotomy.
Following the operative stabilization of the tibial fracture and before the final closure of
any traumatic wounds, we will insert multiple UF catheters into the anterior, lateral, and
posterior (superficial and deep) compartments of the leg. Techniques used for catheter
insertion will be similar to existing methods for the insertion of drainage catheters and we
do not anticipate any specific difficulties with this step.
To measure intramuscular pressure, we will connect one of the catheters designed for this
purpose to a standard pressure transducer and will use it to monitor intracompartmental
pressure (IMP) in real-time. In addition, we will use a standard wick catheter, inserted
separately, for control measurements.
For biochemical measurements, we will analyze samples of the interstitial fluid removed by
CSUF for levels of creatine phosphokinase (CPK), lactic acid, lactate dehydrogenase (LDH),
osmolarity, pH, and pO2. We will obtain fluid every 4 hours for up to 48 hours. The assays
will be performed by standard clinical laboratory techniques.
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Allocation: Non-Randomized, Endpoint Classification: Safety Study, Intervention Model: Single Group Assignment, Masking: Open Label, Primary Purpose: Treatment
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