Posterior Approach for Debridement of the Psoas Abscess

Emilio  E. Grau-Cruz; Ali Nourbakhsh

doi:10.3791/60796

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Summary

This is a cadaveric study investigating the landmarks for the posterior approach for irrigation and debridement of the psoas abscess. The interval between the transverse processes (TP) was used to access the substance of the psoas muscle.

Abstract

This method focuses on outlining a safe zone for irrigation and debridement of a psoas abscess through a posterior approach. Initially, an anterior approach to the spine was performed to ensure that the anterior longitudinal ligament and the psoas muscle could be visualized. All the abdominal organs were removed. Subsequently, a posterior approach was performed to remove the paraspinal muscles from L1–L5. The transverse processes, pars interarticularis and lamina of L1–L5 were identified. The exiting nerve root was identified between the transverse processes and followed into the substance of the psoas muscle. Using the anterior and posterior approach, the lumbar plexus was isolated from the substance of the psoas muscle. Before and after various steps of dissection, digital photographs were obtained. These images were uploaded into ImageJ and multiple measurements, including the distance between the lateral superior and inferior tip of each TP to the most lateral region of the plexus, the distance between the lateral superior and inferior tip of the TP to the lateral edge of the psoas, and the width of the lumbar plexus were recorded. The safe zone for entering the substance of the psoas muscle was defined between the lateral edge of the psoas muscle and the lateral edge of the lumbar plexus. The relationship of this interval to the tip of the transverse process at each level was measured and reported.

Introduction

A psoas abscess (PA) is a rare diagnosis reported in 0.4–1 per 10,000 admissions to the hospital¹^,². A PA can be caused by hematogenous spread, lymphatic spread from a distant infectious site, or by contiguous spread from adjacent organs³. Currently, percutaneous drainage under real-time computed tomography is a safe and first-line treatment for a PA⁴. Dietrich et al. found that it has a higher success rate compared to open surgery, offering a lower mortality rate and shorter hospital length of stay². However, Tabrizian et al. found that 44% of the patients treated with percutaneous drainage underwent open surgery to eradicate the infection⁵.

Given the rate of open surgeries performed for treatment of psoas abscesses, the aim of the method developed in this study is to find a "safe zone" for irrigation and debridement (I&D) of a psoas abscess via a dorsal approach. An initial ventral approach is taken to identify and isolate key anatomical structures, including the transverse processes (TP), psoas muscle, and lumbar plexus (LP). A dorsal approach is then taken to further isolate the TP and LP from the surrounding structures. Throughout the various steps of dissection, photographs are obtained. Once the dissection is complete, the images are uploaded to ImageJ (1.48v, National Institute of Health) and several measurements are taken to identify the relationship between the TP, LP, and psoas muscle. Finally, using the measurements obtained, a "safe zone" for entering the substance of the psoas and minimizing the risk of lumbar plexus injury is calculated. To our knowledge, this is the first work that uses the transverse processes as reference points for the purpose of finding a safe zone for I&D of a psoas abscess.

Protocol

The use of deceased human specimens, for the purposes of developing this method, has been approved by the WellStar Research Institute's institutional review board and conforms with the ethical guidelines established by the institution's ethics committee. The specimens used in this method were all formalin-fixed, transected at the T12 vertebral body, and had their abdominal organs and viscera removed.

1. Preparation of the cadaveric specimen and surgical field

Place the previously thawed cadaveric specimen on the surgical table in the supine position and illuminate the field with surgical lights. Cover the specimen with a blanket, sparing the upper and lower abdomen.

2. Isolation and identification of key anatomical structures using a ventral approach

Beginning with a ventral approach, use a blade to make a midline incision, cranial to caudal, down to the hypogastric region and directly perpendicular to the anterior-superior iliac spines. Make a transverse cut between the ASIS and proceed to use a surgical blade and scissors to reflect and remove the abdominal musculature and fascia. This will improve visualization and aid in measurement accuracy.
Identify the transverse processes, lamina, pars interarticularis of lumbar vertebrae L1–L5, psoas muscles, and the nerve roots of the LP exiting the neuroforamina. Ensure that they are intact and undamaged (Figure 1). If any obvious damage to the hemivertebrae or transverse process is found, do not use the specimen.
Once all key anatomic structures are identified, carefully turn over the specimen to begin the dorsal approach.

3. Further isolation of the transverse processes and obtaining digital photographs for analysis

With the specimen now in the prone position, use a surgical blade, scissors, cobb elevator, and other surgical tools to resect the latissimus dorsi and paraspinal muscles, starting sequentially from the posterior spinous process until reaching the transverse processes.
Use the cobb elevator and other surgical tools to isolate the TPs from any remaining soft tissue attachments to aid in visualization and accurate measurements.
With the paraspinal muscles now removed, turn the specimen back to the supine position. Place a surgical ruler parallel to the surgical field and take digital photographs of the intact psoas muscle to demonstrate its relationship to the TP at each vertebral level.
Once all photographs are taken and deemed of good quality, use a surgical blade to strip the psoas muscle from its medial attachment at each lumbar body and perform a blunt dissection using blunt edged scissors or hemostats to carefully expose the entire lumbar plexus and reflect the psoas muscle laterally.
With the surgical ruler placed parallel to the surgical field, take additional photographs to capture the relationship of the lumbar plexus to the transverse process at each level.
Finally, turn the specimen on its side and take additional photographs to demonstrate the relationship of the TP to the LP in the sagittal plane.

4. Calibrating and taking measurements using ImageJ software

In the File tab in ImageJ (1.48v, National Institute of Health), select Open and, in the new window that appears, select the photograph to be analyzed.
With the desired image now open, use the "magnifying glass" tool to zoom in on the surgical ruler in the photograph. Use the line drawing tool to carefully draw a straight line between the margins of a 1-millimeter segment on the ruler.
Within the Analyze tab in ImageJ, select Set scale…. In the Set Scale window, set the known distance to 1.00 and the unit of length to mm. Place a check in the box next to Global and click OK. Your measurements will now be calibrated according to the number of pixels per millimeter on the ruler.

5. Calculating the "safe zone" for maximal I&D

Using the "line drawing" tool in ImageJ, draw a straight line between the lateral superior tip of each TP to the lateral edge of the psoas at the same level.
Once the lines are drawn, under the Analyze tab, select measure. A new Results window will open.
The measurements, in millimeters, will appear in the new window under the Length column in the order taken. Record these numbers.
Repeat steps 5.1–5.3 to obtain the following measurements:
-Lateral inferior tip of each TP to the lateral edge of the psoas muscle
-Lateral superior tip of each TP to the most lateral region of the lumbar plexus at the same level
-Lateral inferior tip of each TP to the most lateral region of the lumbar plexus at the same level
-Width of the lumbar plexus
-Depth of the lumbar plexus from the superior tip of each TP to the lumbar plexus at the same level using the lateral photographs
-Depth of the lumbar plexus from the inferior tip of each TP at the same level using the lateral photographs

6. Calculating the safe zone for maximal irrigation and debridement using the measurements obtained in Section 5

The safe zone for lateral to medial debridement is defined by the distance from the lateral edge of the lumbar plexus to the lateral edge of the psoas at the same level. To calculate this distance, subtract the distance from the superior and inferior tips of the TP to the lumbar plexus from the distance of the superior and inferior tips of the TP to the lateral edge of the psoas muscle. These values will correspond to the safe zone for lateral to medial debridement, in the coronal plane, at each corresponding level.
Define the zone of maximal irrigation and debridement in the sagittal plane as the depth of the lumbar plexus, in relation to the TP, at the corresponding level.

Results

Eleven formalin-fixed cadavers were included, with an average age of 80.5 years⁶. Two cadavers had damaged lumbar vertebrae on the right side and were removed. Thus, a total of 20 measurements were included, 13 female and 7 male. The medial border of the safe zone, defined by the most lateral aspect of the lumbar plexus, was found to be approximately 1 cm medial to the tip of the TP at L1–L3, but narrowed down to approximately 6 and 1 mm at L4 and L5, respect...

Discussion

The most critical steps for finding the safe zone for irrigation and debridement of a psoas muscle abscess through a dorsal approach are 1) careful blunt dissection of the lumbar plexus during the ventral and dorsal approach; 2) preservation of the transverse processes during their isolation, as they can be fragile, for better visualization; and 3) calibrating the ImageJ software with the surgical ruler and taking careful measurements to elucidate the relationship between the TP, LP, and psoas muscle.

Disclosures

The authors declare that they have no competing financial interests.

Acknowledgements

The authors would like to acknowledge all those who donate their bodies for research and keep impacting others after they have gone.

Materials

Name	Company	Catalog Number	Comments
Blunt ended dissecting scissors			To cover the specimens
Camera	Sony a7 III	ILCE-7
Cobb elevator	Sklar	40-6950	For isolation of TP and general dissection
Dissection table
Formalin fixed cadavers	Restore Life USA	N/A	Transected at T12 with abdominal organs removed
Hemostats
Retractors			For blunt dissection
Rongeur	Sklar	40-4085
Scissors	Sklar	15-2555
Surgical absorbent pads			Placed under the cadaver to absorb fluids
Surgical blades/scalpels	Dynarex	4110
Surgical drape/blanket			For blunt dissection
Surgical gauze sponges
Surgical lights
Surgical Ruler	Aspen Surgical Products	42182702
Tissue forceps
Tool tray

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