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Use of the Posterior Lumbar Approach for Psoas Major Injection in Hip Flexor Spasticity

Published online by Cambridge University Press:  27 July 2020

Allen Duong*
Affiliation:
Division of Anatomy, Department of Surgery, Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada
Satyendra Sharma
Affiliation:
Division of Physical Medicine and Rehabilitation, Department of Medicine, Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada Division of Physical Medicine and Rehabilitation, Sunnybrook Health Sciences Center, Toronto, Ontario, Canada
Anne A.M. Agur
Affiliation:
Division of Anatomy, Department of Surgery, Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada Division of Physical Medicine and Rehabilitation, Department of Medicine, Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada
*
Correspondence to: Allen Duong, Division of Anatomy, University of Toronto, 1 King’s College Cir, Toronto, ON, CanadaM5S 3K1. Email: [email protected]
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Abstract:

Background:

Hip flexor spasticity in patients with upper motor neuron syndrome of multiple etiologies has been managed with botulinum neurotoxin injections mainly targeting the “iliopsoas” muscle. A lumbar approach to target psoas major (PM) has been described; however, it has not been incorporated into clinical practice due to perceived risk of injury to surrounding structures. This study will investigate the feasibility and accuracy of ultrasound-guided (UG)-PM injection using a lumbar approach by assessing the intra/extramuscular injectate spread in cadaveric specimens.

Methods:

In eight lightly embalmed specimens, toluidine blue dye/saline was injected into PM using a UG-posterior lumbar approach. The posterior abdominal wall was exposed, and dye spread and surrounding structures digitized and modeled in 3D. The area and vertebral level of dye spread, distance of dye to the inferior vena cava (IVC), and abdominal aorta (AA) and dye spread to adjacent organs were quantified.

Results:

The models enabled visualization of the dye spread in 3D. Mean area of dye spread was 24.4 ± 2.8 cm2; most commonly between L2 and L4 vertebral levels. Mean distance of the dye to AA was 3.2 ± 1.2 cm and to IVC was 1.8 ± 0.4 cm. Dye spread remained intramuscular in all but one specimen. No dye spread occurred to any adjacent organs.

Conclusions:

The injection of PM using the UG-posterior lumbar approach was consistent and without spread to surrounding structures. This technique alone or in addition to the anterior approach is expected to have better clinical outcomes in the treatment of hip flexor spasticity. Further clinical studies are required.

Résumé :

RÉSUMÉ :

Cibler la région lombaire postérieure dans des cas d’injection du grand psoas pour des patients atteints de spasticité des muscles fléchisseurs de la hanche.

Contexte :

La spasticité des muscles fléchisseurs de la hanche chez des patients atteints d’un syndrome du motoneurone supérieur (ou syndrome pyramidal) dont les étiologies sont multiples peut être prise en charge par des injections de neurotoxines botuliques ciblant principalement le grand psoas. L’approche qui consiste à se concentrer sur la région lombaire pour mieux cibler ce muscle a été décrite dans la littérature ; elle n’a toutefois pas été intégrée dans la pratique clinique en raison de la perception d’un risque de blessure pouvant affecter les structures avoisinantes. Cette étude entend donc examiner la praticabilité et la précision d’injections guidées par ultrasons ciblant le grand psoas en fonction d’une approche dite « lombaire postérieure ». Pour ce faire, nous avons évalué la propagation intramusculaire et extra-musculaire d’une substance injectée chez des spécimens cadavériques.

Méthodes :

Du bleu de toluidine dissous dans une solution saline a donc été injecté, tout en étant guidés par ultrasons, dans le grand psoas de 8 spécimens cadavériques légèrement embaumés. À noter que le mur abdominal postérieur de ces spécimens était exposé et que la propagation du colorant, ainsi que les structures avoisinantes, ont été numérisées et modélisées en 3D. La propagation du colorant selon la région vertébrale et le niveau des vertèbres, la distance du colorant par rapport à la veine cave inférieure (VCI) et l’aorte abdominale (AA) et la propagation du colorant vers les organes voisins ont également été quantifiées.

Résultats :

Nos modèles ont permis de visualiser la propagation du colorant en 3D. La région vertébrale moyenne de diffusion du bleu de toluidine a été de 24,4 ± 2,8 cm2, et ce, le plus souvent entre les niveaux L2 et L4. La distance moyenne de propagation par rapport à l’AA a été de 3,2 ± 1,2cm et de 1,8 ± 0,4 par rapport à la VCI. La propagation du colorant est demeurée intramusculaire dans tous les spécimens cadavériques sauf un. Enfin, aucune propagation de colorant n’est survenue dans les organes voisins.

Conclusions :

L’injection de bleu de toluidine dans le grand psoas au moyen de l’approche dite « lombaire postérieure » tout en étant guidé par ultrasons s’est révélée uniforme et sans signe de propagation vers des structures avoisinantes. Il est donc permis d’espérer que cette technique, seule ou en complément avec des approches antérieures, aura de meilleurs résultats cliniques dans le traitement de la spasticité des muscles fléchisseurs de la hanche. Cela dit, d’autres études cliniques demeurent nécessaires.

Type
Original Article
Copyright
© The Author(s), 2020. Published by Cambridge University Press on behalf of The Canadian Journal of Neurological Sciences Inc.

Severe hip flexor muscle spasticity can occur in upper motor neuron syndrome of multiple etiologies. It can be associated with cerebral palsy (CP), multiple sclerosis, spinal cord injuries, severe traumatic brain injuries, and late Parkinson’s disease with dementia and paratonia. In elderly bed confined patients, flexed hip position can cause serious skin complications and is a barrier to perineal care. Reference Jog, Wein and Bhogal1 Focal spasticity can be controlled well with botulinum neurotoxin (BoNT) injections, improving quality of life. Reference Jog, Wein and Bhogal1Reference Westhoff, Seller, Wild, Jaeger and Krauspe5 In cases of hip flexor spasticity in CP children, the common approach is to inject BoNT targeting “iliopsoas” muscle through the femoral (Scarpa’s) triangle. Reference Westhoff, Seller, Wild, Jaeger and Krauspe5Reference Willenborg, Shilt, Smith, Estrada, Castle and Koman7 However, using this femoral triangle approach, mostly the iliacus (ILC) is injected, as the psoas major (PM) is largely tendinous in this area. In order to optimize clinical outcomes, it has been reported that BoNT injection should be close to the motor end plate (MEP) zone of a muscle. Reference Gracies, Lugassy, Weisz, Vecchio, Flanagan and Simpson8 The MEP zone of PM has been found to be located proximally in the muscle belly, Reference Van Campenhout and Molenaers9,Reference Van Campenhout, Verhaegen, Pans and Molenaers10 which can be accessed better through a posterior lumbar approach. The posterior lumbar approach has been described in the literature Reference Farny, Girard and Drolet11Reference Koyama, Murakami, Suzuki and Suzaki13 ; however, it has not been incorporated into clinical practice due to a perceived risk of injury to the kidney, abdominal aorta (AA), and inferior vena cava (IVC). The L4–L5 transverse processes (TP) can be used as a landmark for ultrasound (US)-guided BoNT injection, as PM lies directly anterior to the TPs. The feasibility of using an US-guided posterior lumbar approach has not been assessed. The purpose of this cadaveric study was to investigate the feasibility and accuracy of US-guided PM injection using a posterior lumbar approach to assess the intra- and extramuscular spread of injectate in the surrounding structures.

Methods

Eight lightly embalmed cadavers with mean age 81.6 ± 10.2 (4M/4F) were used in this study. Cadavers had no visible signs of musculoskeletal pathology or previous surgery. Ethics approval was received from the University of Toronto Health Sciences Research Ethics Board (27210). For sonographic guidance of injections, a LOGIQ™ e (General Electric Healthcare, Chicago, IL, USA) real-time US scanner with a GE C1-5-RS (Convex) curved array probe was used. This probe was chosen for better resolution up to a depth of 8–12 cm. Imaging was optimal at a frequency of 4 MHz using B beam with contrast harmonic imaging (chi).

The specimens were placed in a semi-prone position supported by blocks to prevent movement during the procedure. To localize the site of injection, the following were identified and demarcated using a skin marker: midline (interspinous line), iliac crest (IC), and lateral border of erector spinae (ES) (Figure 1). The PM injection site was located in the angle between the posterior IC and the lateral border of ES, corresponding to vertebral level L4–L5 (Figure 1A). Prior to injection, using US scanning, the IC, TP of L4 and L5 vertebrae, and the inferior pole of the kidney were identified (Figure 1B).

Figure 1: Landmarking and site of injection. (A) Specimen with landmarking. Inset shows enlargement of site of injection. (B) Ultrasound scan showing needle position. L, lumbar vertebra; TP, transverse process.

PM injections were carried out using a 3″ cannulated, 27 gauge needle attached to a 3-ml syringe by the second author (S.S.), a physiatrist who has more than 27 years of experience in spasticity management and 3 years of experience using US guidance, and has been using electromyography (EMG) and US-guided injections in PM. The injectate consisted of 2 ml of saline mixed with toluidine blue, the volume commonly used in clinical practice (100 units of onabotulinumtoxinA using 2:1 dilution). In most specimens, the PM was reached at about a depth of 2″ (50 mm). The cadavers were lightly embalmed, but due to prolonged supine positioning, the adipose tissue at the back was observed to be condensed; therefore, PM was found more superficial compared to in vivo. Using US guidance with an out-of-plane approach, the needle was inserted at the injection site described above and directed inferiorly and medially between the TPs of L4 and L5 until reaching a plane anterior to the TPs in the muscle belly of PM. An out-of-plane US needle placement technique was used, as the in-plane approach was technically difficult in targeting the acoustic window of L4–L5 TP at an appropriate angle while maintaining the visibility of the needle.

Following injection, cadavers were placed in supine and the anterior abdominal wall reflected to reveal the abdominal organs. All structures and organs superficial to the kidneys were excised revealing the posterior abdominal wall. Next, the kidneys were inspected for any evidence of dye spread and removed. The PM, ILC, and quadratus lumborum (QL) muscles were identified and demarcated, and the AA and IVC were exposed from the diaphragm to their bifurcation. For landmarking purposes, the 12th ribs, lateral margins of T12–L5 vertebrae, intervertebral discs, and superior margin of the sacrum were exposed.

Using a Microscribe® FMLX Digitizer, the surface of PM, QL, AA, IVC, and bony landmarks were digitized. If the dye was visualized on the surface of PM, the outline of the visible dye was digitized. Fiber bundles were serially dissected and the dye spread digitized at each level until no longer present. However, if the dye was not visualized superficially, fiber bundles of PM were serially dissected until the dye could be demarcated and digitized.

The digitized data were imported into Autodesk® Maya® and modeled in 3D. The 3D models of each injection included the 12th rib, lumbar vertebrae and intervertebral disks, superior margin of the sacrum, IC, QL, PM, ILC, AA, IVC, and area of dye spread. The course of the femoral nerve was digitized in two specimens.

Data analysis included the documentation of the dye spread intramuscularly and extramuscularly relative to the digitized bony landmarks. The area of dye spread, the maximum length, maximum width, and the minimum distance of the dye from the AA on the left and IVC on the right were computed for each specimen.

Results

The dye spread was only found intramuscularly i.e., contained within the PM muscle belly, in seven out of eight specimens. In one specimen, the dye spread was found both intra- and extramuscularly. Extramuscular dye spread was directed posterolaterally, but with no spread to the kidney (Figure 2A–C).

Figure 2: Dissections and 3D models of dye spread. (A) Dissection, psoas major (PM), QL and ILC intact. Anterior view. (B) 3D model of the specimen in A, anterior view. (C) 3D model of specimen A, showing a transparent PM to demonstrate extent of dye spread, anterolateral view. Aorta and IVC removed. (D) Dissection of a specimen with PM fiber bundles removed to demonstrate intramuscular dye spread. (E) 3D model of specimen in D, anterior view. Dye spread cannot be seen as this shows the surface of PM. (F) 3D model of specimen in D, anterolateral view. Dye spread can be seen through transparent PM.

Dye spread was found to span between the superior margin of L2 to the inferior margin of L4 vertebra in three specimens with left-sided injection, and two specimens with right-sided injections (Figure 3). In two specimens, one with left-sided and one with right-sided injection, the dye spread was confined between the superior margin of L3 and the inferior margin of L5. The most extensive dye spread spanning between L2 and L5 vertebral level was found in one right-sided injection.

Figure 3: Quantification of dye spread. (Left) Graph showing vertebral level (L2 to S1) of dye spread. Red bars denote left side of specimen (Sp). Blue bars denote right side of Sp. (Right) Summary of dye spread parameters.

The mean area of dye spread of both left and right sides were 24.4 ± 2.8 cm2. When separated into the left and right sides, both sides were similar, 24.0 ± 3.7 cm2 and 24.7 ± 2.1 cm2, respectively (Figure 3). The area of dye spread was not indicative of the number of vertebral levels of spread. For example, in specimen 6, the dye spread was two vertebral levels, but had the greatest area of spread (29.51 cm2), whereas specimen 5 had a smaller area of dye spread (26.77 cm2) that spanned four vertebral levels longitudinally along fewer fascicles.

The mean maximum length and mean maximum width of dye spread on the left and right sides were also similar. The extent and shape of the dye spread varied between specimens (Figure 2A and D). The dye spread from its closest point to the AA with left-sided injections was on average 3.2 ± 1.2 cm (1.67–4.69 cm) (Figure 3). In contrast, the mean distance from the dye spread and its closest point from the IVC with right-sided injections was on average 1.8 ± 0.4 cm (1.41–2.32 cm).

Discussion

In the current anatomical study, using the US-guided lumbar approach, it has been shown that the injection can consistently be placed in the proximal PM without affecting the AA, IVC, or kidney. Additionally, the injection into the proximal PM occurred in the region of greatest concentration of MEPs, as defined by Van Campenhout. Reference Van Campenhout and Molenaers9,Reference Van Campenhout, Verhaegen, Pans and Molenaers10

In common practice of hip flexor spasticity management, it is incorrectly assumed by many clinicians that iliopsoas is muscular in the femoral triangle where BoNT injections are usually placed. Anatomically, however, the two main muscles forming the iliopsoas, the PM and ILC, have differing musculotendinous architecture which could impact efficacy of the chemodenervation. These muscles have distinct origins but share a common site of insertion in the region of lesser trochanter of the femur Reference Williams, Warwick, Dyson and Bannister14 (Figure 4). The fiber bundles of PM originate proximally from: (1) the vertebral bodies/intervertebral disks (T12–L5), (2) tendinous arches that bridge the lateral aspect of L1–L4 vertebrae, and (3) from the inferior border and anterior surface of the TPs of the lumbar vertebrae. Reference Grant and Scheffer15 The fiber bundles descend inferolaterally and form the muscle belly of PM, which extends distally along the margins of the vertebral bodies to insert into lesser trochanter of the femur. Reference Williams, Warwick, Dyson and Bannister14Reference Tatu, Parratte, Vuillier, Diop and Monnier16 Slightly superior to the inguinal ligament, PM becomes tendinous and remains so until its insertion. In contrast, ILC has a fan-shaped origin that is divided into a medial and lateral part. The medial part originates from the medial 2/3 of the iliac fossa and IL, and the lateral part arises from the lateral 1/3 of the iliac fossa/crest and anterior border of the ilium Reference Grant and Scheffer15 (Figure 4). As fiber bundles of the medial part course distally, they insert into the lateral side of the PM tendon. Reference Grant and Scheffer15 In contrast, fiber bundles of the lateral part course inferiorly as a distinct belly to insert into the lesser trochanter via a short tendon Reference Tatu, Parratte, Vuillier, Diop and Monnier16 (Figure 4). Gomez-Hoyos, in a cadaveric study of the insertion of the tendinous footprint of ILC and PM onto the lesser trochanter, found that 70% of specimens had a divided footprint, whereas only 30% had a conjoint tendon (single footprint). Reference Gómez-Hoyos, Schröder, Palmer, Reddy, Khoury and Martin17

Figure 4: Anatomy of iliopsoas, anterior views. (A) Relationship of PM to medial and lateral parts of ILC. (B) Enlargement of PM tendon and medial and lateral parts of ILC showing attachment sites to the lesser trochanter. A, anterior superior iliac spine; F, femur; IC, iliac crest; Lat, lateral part of ILC; Med, medial part of ILC; T, tendon of PM; PS, pubic symphysis; *, tendon of ILC merging with T; white arrow, lesser trochanter; red arrow, fiber bundle attachments of medial part of ILC to PM tendon.

The anatomy suggests that a BoNT injection using the anterior approach would mostly target the ILC as the PM is primarily tendinous in this region. In a clinical study of children with CP, Ward reported that BoNT injection using a lumbar approach, through the paralumbar muscles without EMG or US guidance, was beneficial resulting in “a direct association between injecting PM muscles in spastic diplegics with hip flexor and adductor restriction, and the outcomes measured.” Reference Ward18,Reference Ward19 In our cadaveric study, using the US-guided lumbar approach, the injectate was localized within the PM muscle belly in all specimens, with one exception where there was minor extramuscular extension posteriorly which did not encroach any important structures. Furthermore, the injectate was within the region of the MEP zone between vertebral levels L3 and S1. Reference Van Campenhout and Molenaers9,Reference Van Campenhout, Verhaegen, Pans and Molenaers10 This provides additional support that the lumbar approach is superior in targeting the PM muscle belly consistently in the desired region of MEPs. In order to get the maximum control of the hip flexor spasticity, the combination of the anterior approach to capture the ILC and lumbar approach for PM would appear to be more effective. Further clinical studies are necessary to determine if the anterior approach or the lumbar approach or a combination of the two approaches provide the best outcome.

The perceived risk of injury to the AA, IVC, and/or kidneys has been a deterrent in the clinical use of the lumbar approach. Our study provided a unique opportunity to assess and visualize the injectate spread and affirmed that no vital structures listed above, particularly the AA and IVC, lying in close relationship to the vertebral column, were punctured or encroached by the dye spread. Earlier clinical studies used a blind injection technique; Reference Ward19 however, Westhoff et al. in a study of the anterior approach reported that US-guided injection provided better delineation of the relevant anatomy and allowed for visualization of needle advancement and injectate spread in real time. Reference Westhoff, Seller, Wild, Jaeger and Krauspe5 Furthermore, Karmakar et al. in a study of lumbar plexus block suggested that the use of US guidance could limit needle-related complications. Reference Karmakar, Ho, Li, Kwok, Tsang and Ngan Kee12

A limitation of this study is the small sample size. However, the labor-intensive and time-consuming process of dissection and digitization of dye spread prohibited a larger sample size. Also, the spread of injectate may not exactly replicate BoNT in vivo, although in the literature it has been reported that lightly embalmed specimens have similar tissue qualities to that in vivo. Reference Tsui, Dillane, Pillay, Ramji and Walji20 The recumbency versus upright position and physical movement of patients are the subjects of further studies as these factors can influence the characteristic spread of the injectate.

Conclusion

The injection of chemodenervation agents, such as BoNT, using the US-guided lumbar approach could target the proximal PM consistently without injury or spread to the AA, IVC, and/or kidneys. It is also expected, that in addition to the conventional anterior approach of injecting “iliopsoas,” the PM injection through lumbar approach could maximize the outcome of severe hip flexor muscle hypertonia/spasticity. This technique would be particularly useful in cases with severe hip flexion deformity which denies adequate access to the femoral triangle. Further clinical studies to compare the outcome of injecting ILC using the anterior approach alone, PM using the lumbar approach alone, and a combination of the two approaches are recommended to determine the optimal clinical protocol.

Acknowledgments

The authors would like to acknowledge the individuals and families who graciously donated their bodies and tissues for the advancement of education and research.

Conflict of interest

Dr. Anne Agur and Dr. Satyendra Sharma are anatomy faculty members of the Allergan Academy of Excellence. This affiliation is for teaching purposes only and has no relationship to the current study. Allen Duong has no disclosures.

Statement of authorship

AD performed the dissection and data collection, data analysis, and contributed in the writing of this manuscript. SS provided the framework for the pursual of this project, conducted the injections on the specimens, and contributed in the writing of this manuscript. AAMA has provided the equipment necessary for the pursual of this project, oversaw the data analysis, and contributed in the revision and writing of this manuscript.

References

Jog, M, Wein, T, Bhogal, M, et al. Real-world, long-term quality of life following therapeutic onabotulinumtoxina treatment. Can J Neurol Sci. 2016;43(5):687–96. https://doi.org/10.1017/cjn.2016.262 CrossRefGoogle ScholarPubMed
Ward, AB, Wissel, J, Borg, J, et al. Functional goal achievement in post-stroke spasticity patients: the Botox® Economic Spasticity Trial (BEST). J Rehabil Med. 2014;46(6):504–13. https://doi.org/10.2340/16501977-1817 CrossRefGoogle Scholar
Gracies, JM, Esquenazi, A, Brashear, A, et al. Efficacy and safety of abobotulinumtoxinA in spastic lower limb: randomized trial and extension. Neurology. 2017;89(22):2245–53. https://doi.org/10.1212/WNL.0000000000004687 CrossRefGoogle Scholar
Pullman, SL. Approach to the treatment of limb disorders with botulinum toxin A. Arch Neurol. 1996;53(7):617. https://doi.org/10.1001/archneur.1996.00550070055012 CrossRefGoogle ScholarPubMed
Westhoff, B, Seller, K, Wild, A, Jaeger, M, Krauspe, R. Ultrasound-guided botulinum toxin injection technique for the iliopsoas muscle. Dev Med Child Neurol. 2003;45(12):829–32. https://doi.org/10.1111/j.1469-8749.2003.tb00898.x CrossRefGoogle ScholarPubMed
Depedibi, R, Ünlü, E, Çevikol, A, et al. Ultrasound-guided botulinum toxin type A injection to the iliopsoas muscle in the management of children with cerebral palsy. NeuroRehabilitation. 2008;23(3):199205. https://doi.org/10.3233/NRE-2008-23301 CrossRefGoogle ScholarPubMed
Willenborg, MJ, Shilt, JS, Smith, BP, Estrada, RL, Castle, JA, Koman, LA. Technique for iliopsoas ultrasound-guided active electromyography-directed botulinum A toxin injection in cerebral palsy. J Pediatr Orthop. 2002;22(2):165–8. https://doi.org/10.1097/00004694-200203000-00005 CrossRefGoogle ScholarPubMed
Gracies, JM, Lugassy, M, Weisz, DJ, Vecchio, M, Flanagan, S, Simpson, DM. Botulinum toxin dilution and endplate targeting in spasticity: a double-blind controlled study. Arch Phys Med Rehabil. 2009;90(1):916.e2. https://doi.org/10.1016/j.apmr.2008.04.030 CrossRefGoogle ScholarPubMed
Van Campenhout, A, Molenaers, G. Localization of the motor endplate zone in human skeletal muscles of the lower limb: anatomical guidelines for injection with botulinum toxin. Dev Med Child Neurol. 2011;53(2):108–19. https://doi.org/10.1111/j.1469-8749.2010.03816.x CrossRefGoogle ScholarPubMed
Van Campenhout, A, Verhaegen, A, Pans, S, Molenaers, G. Botulinum toxin type A injections in the psoas muscle of children with cerebral palsy: muscle atrophy after motor end plate-targeted injections. Res Dev Disabil. 2013;34(3):1052–8. https://doi.org/10.1016/j.ridd.2012.11.016 CrossRefGoogle ScholarPubMed
Farny, J, Girard, M, Drolet, P. Posterior approach to the lumbar plexus combined with a sciatic nerve block using lidocaine. Can J Anaesth. 1994;41(6):486–91. https://doi.org/10.1007/BF03011542 CrossRefGoogle ScholarPubMed
Karmakar, MK, Ho, AMH, Li, X, Kwok, WH, Tsang, K, Ngan Kee, WD. Ultrasound-guided lumbar plexus block through the acoustic window of the lumbar ultrasound trident. Br J Anaesth. 2008;100(4):533–7. https://doi.org/10.1093/bja/aen026 CrossRefGoogle ScholarPubMed
Koyama, H, Murakami, K, Suzuki, T, Suzaki, K. Phenol block for hip flexor muscle spasticity under ultrasonic monitoring. Arch Phys Med Rehabil. 1992;73(11):1040–3. https://doi.org/10.5555/uri:pii:000399939290168V Google ScholarPubMed
Williams, PL, Warwick, R, Dyson, M, Bannister, LH. Gray’s anatomy, 37th ed. London: Churchill Livingstone; 1989.Google Scholar
Grant, JCB. The musculature. In: Scheffer, JP, editor. Morris’ human anatomy: a complete systematic treatise, 10th ed. New York: The Blakiston Company; 1942, pp. 522–3.Google Scholar
Tatu, L, Parratte, B, Vuillier, F, Diop, M, Monnier, G. Descriptive anatomy of the femoral portion of the iliopsoas muscle: anatomical basis of anterior snapping of the hip. Surg Radiol Anat. 2002;23(6):371–4. https://doi.org/10.1007/s00276-001-0371-9 CrossRefGoogle Scholar
Gómez-Hoyos, J, Schröder, R, Palmer, IJ, Reddy, M, Khoury, A, Martin, HD. Iliopsoas tendon insertion footprint with surgical implications in lesser trochanterplasty for treating ischiofemoral impingement: an anatomic study. J Hip Preserv Surg. 2015;2(4):hnv060. doi: 10.1093/jhps/hnv060 Google Scholar
Ward, AB. The use of botulinum toxin type A in spastic diplegia due to cerebral palsy. Eur J Neurol. 1999;6(Suppl 4):s958. https://doi.org/10.1111/j.1468-1331.1999.tb00043.x CrossRefGoogle Scholar
Ward, AB. Botulinum toxin type A treatment of hip and thigh spasticity: a technique for injection of psoas major muscle. Eur J Neurol. 1999;6(Suppl 4):s913. https://doi.org/10.1111/j.1468-1331.1999.tb00042.x CrossRefGoogle Scholar
Tsui, BCH, Dillane, D, Pillay, J, Ramji, AK, Walji, AH. Cadaveric ultrasound imaging for training in ultrasound-guided peripheral nerve blocks: lower extremity. Can J Anesth. 2007;54(6):475–80. https://doi.org/10.1007/BF03022035 CrossRefGoogle ScholarPubMed
Figure 0

Figure 1: Landmarking and site of injection. (A) Specimen with landmarking. Inset shows enlargement of site of injection. (B) Ultrasound scan showing needle position. L, lumbar vertebra; TP, transverse process.

Figure 1

Figure 2: Dissections and 3D models of dye spread. (A) Dissection, psoas major (PM), QL and ILC intact. Anterior view. (B) 3D model of the specimen in A, anterior view. (C) 3D model of specimen A, showing a transparent PM to demonstrate extent of dye spread, anterolateral view. Aorta and IVC removed. (D) Dissection of a specimen with PM fiber bundles removed to demonstrate intramuscular dye spread. (E) 3D model of specimen in D, anterior view. Dye spread cannot be seen as this shows the surface of PM. (F) 3D model of specimen in D, anterolateral view. Dye spread can be seen through transparent PM.

Figure 2

Figure 3: Quantification of dye spread. (Left) Graph showing vertebral level (L2 to S1) of dye spread. Red bars denote left side of specimen (Sp). Blue bars denote right side of Sp. (Right) Summary of dye spread parameters.

Figure 3

Figure 4: Anatomy of iliopsoas, anterior views. (A) Relationship of PM to medial and lateral parts of ILC. (B) Enlargement of PM tendon and medial and lateral parts of ILC showing attachment sites to the lesser trochanter. A, anterior superior iliac spine; F, femur; IC, iliac crest; Lat, lateral part of ILC; Med, medial part of ILC; T, tendon of PM; PS, pubic symphysis; *, tendon of ILC merging with T; white arrow, lesser trochanter; red arrow, fiber bundle attachments of medial part of ILC to PM tendon.