Tag Archives: musculoskeletal

The Potential of Elastography in MSK Ultrasound

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Elastography is a method of imaging that detects the compressibility or stiffness of tissues in the imaging field and then overlays a false-color map upon the greyscale image to indicate which tissues are hard/stiff versus soft/compressible. The science behind the technique is beyond the scope of a blog post, particularly as there are several methods by which elastography can be performed.  

In practical terms, elastography is useful in identifying lesions that are sonographically iso-dense compared to their surroundings. Such lesions, while they are therefore visually “iso-grey” (if you will tolerate a neologism), may not be iso-compressible despite their iso-density, and thus when their differential compressibility is identified by elastography it becomes possible to characterize a lesion whose greyscale appearance is not instructive. Among the most common current uses of elastography are the characterization of breast and liver lesions, and indeed the well-known Fibroscan device is, in essence, liver elastography.

There are several instances in the field of musculoskeletal (MSK)/rheumatologic ultrasound in which this technology is appealing, but more work is needed before widespread use will be advisable. I will mention only two of the most obvious examples here. 

Example One

The first example is in the interrogation of a symptomatic tendon or ligament. Such a structure, whose normal function involves incredible amounts of linear tension, when disrupted by trauma or disease, would be expected to lose integrity in the region of the insult and become softer/more compressible than normal in that area.

Traditionally, elastography is not used to measure tendons and ligaments despite the validity of the above statement. The reason for this is that the stiffness of tissue, when measured by elastography, can be expressed in terms of the speed at which a deformation (compression wave) in the tissue propagates, usually in meters per second (there are other units by which stiffness can be measured, but for simplicity’s sake, I will leave it at that).

In the classical case of breast and liver lesions, this is not an issue since the surrounding normal tissue is relatively soft and compressible, so the speed of the propagation of a compression wave is relatively slow. Thus, most elastography measurements top out at a propagation speed of about 10 meters per second, and most normal and abnormal breast/liver tissue will have stiffness values somewhat slower than this. Tendons and ligaments, on the other hand, are by nature very hard/noncompressible. Even in their “relaxed” state, these tissues are so bowstring-tight (relatively) that measuring a normal Achilles’ tendon, for example, will yield only a maxed-out value of “offscale hard” throughout the entire structure. 

It is tempting to say that one could simply recalibrate the machine to measure faster propagation speeds, but, unfortunately, we run into limitations of our current technology. It is simply not possible currently to measure velocities much faster than 10 m/s. 

While we await advancements in technology, the current workaround is to trust that a damaged region of tendon or ligament will be significantly softer, and thus transmit compression waves much more slowly. Therefore, we simply consider any propagation speed that falls out of “offscale” and into the measurable range to be an indicator of pathology.

Example Two

The second example of the potential rheumatologic utility of elastography is in the assessment of systemic sclerosis, commonly known as scleroderma. As the Greek name would suggest, this disease usually includes a characteristic hardening of the skin. The problem is that there is currently no reliable way to quantify skin stiffness. The existing gold standard is a semi-quantitative scoring of skin thickening performed by simple physical examination in which each of several predefined regions of the skin is palpated and assigned a value from 0 to 3. This results in an overall score known as the Modified Rodnan Skin Score (MRSS). Performing Rodnan scoring requires an experienced clinician, and since scleroderma is a rare disease, very few physicians have a large enough cohort in their practice to be able to consider themselves expert Rodnan scorers.

This leads to a host of problems, and one of the worst is that clinical trials in scleroderma (a devastating and potentially fatal disease for which no good treatment exists) are very difficult to conduct because one of the primary endpoints of any trial will be the degree of improvement found in this semi-quantitative and hard-to-perform examination, which is subject to severe inter-rater reliability problems.

When I first started as a rheumatology fellow, I agreed to help with a scleroderma clinical trial in the role of a blinded efficacy assessor. The sponsor brought a dozen or so of us to a hotel for training, and all morning long we cycled through a series of hotel meeting rooms, each containing a volunteer patient for us to score.

It was a disaster.

After lunch, the representative from the sponsor got up to the podium and told us to rip up our afternoon agendas—we were going back to the meeting rooms to examine the volunteers again in an effort to improve the scoring consensus.

Clearly, this situation screams for elastography. The objective measurement of skin stiffness is precisely the datum that is sorely needed. Sadly, our current technology again fails us, as present-day elastography has limitations in resolution and the skin by its anatomic location, will always be very nearly directly applied to the probe face, in a region outside the focal zone of the beam where the measurement physics work best. Further, one of the techniques for performing elastography is highly operator-dependent, because the compression waves being measured are generated by manually varying the pressure of the probe against the skin—definitely a skill that must be learned over time and one that opens the door once more to inter-rater variability.

Overall, elastography holds great promise for MSK/rheumatologic applications in the future, as described in the two examples above. For now, however, it’s currently a technology that is “not ready for prime time” in this field.

This post is intended as a companion to “What Rheumatologists Really Need for Ultrasound Is…”, which discusses advances in ultrasound technology that are sorely needed in the field of MSK ultrasound, and specifically in rheumatology.

Dr. Mandelin is an academic rheumatologist, registered in MSK ultrasound (RhMSUS) by the American College of Rheumatology and certified in MSK ultrasound (RMSK) by the Alliance for Physician Certification & Advancement. He currently serves the AIUM as secretary of the High-Frequency Clinical and Preclinical Imaging Community. Connect with him on Twitter @NU_Rheum_MSK_US.

Ultrasound in Orthopedic Practice

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Point-of-care ultrasound brings great value to patient care in orthopedic practice, especially for soft tissue problems. It offers safe, cost-effective, and real-time evaluation for soft tissue pathologies and helps narrow down the differential diagnosis.Pic1

There are a variety of soft tissue lesions in orthopedic practice with a classic clinical presentation that may not necessitate ultrasound examination for confirmation of diagnosis, for example, ganglion cyst. However, there is value in performing an ultrasound scan for these common soft tissue lesions.

Ganglion cyst on the dorsum of the wrist or radial-volar aspect of the wrist are confirmed based on clinical examination and presentation. Adding ultrasound examination can help differentiate classic ganglion cyst from some rare findings like Lipoma, anomalous muscles, or soft tissue tumors. Ultrasound examination may also be helpful in finding the source of the ganglion cyst or the stalk of the ganglion cyst. This can help pre-surgical planning if resection of the ganglion cyst is desired by the patient and recommended by the surgeon, because arthroscopic or traditional surgical approach may be needed based on the location of the stalk or neck of the cyst.

Images 1 and 2 show examples of two different patients with a similar presentation of slow-growing mass on the digit. Image 1 from patient 1 shows a solid tumor overlying the flexor tendons of the digit, where the mass was palpated. Image 2 from patient 2, shows a cystic mass overlying the tendons of the digit. In both of the cases, masses were painless and slow growing with minimal to no discomfort. Ultrasound is a great tool in differentiating solid vs cystic lesions and can help avoid attempted aspiration of a solid mass when the mass is presented in an area of classic ganglion cyst’s usual presentation.

Another soft tissue problem, where ultrasound is a superior imaging tool is tendon pathology. Ultrasound can help differentiate tendinosis, tenosynovitis, or tendon tears.

In tenosynovitis, tendon by itself shows normal echotexture and uniform appearance but the tenosynovium that surrounds the tendon gets inflamed and appears as hypoechoic halo around the tendon, for example, in image 3, tendons of the first dorsal compartment of the wrist show uniform thickness and fibrillar echotexture, however there is hypoechoic swelling around the tendons, this is an example of tenosynovitis of first dorsal compartment of the wrist.

In tendinosis, tendon loses its fibrillar pattern and appears swollen and may show vascularity on color ultrasound, which is suggestive of neoangiogenesis or angiofibroblastic proliferation. For example, in Image 4, the tendons of the first dorsal compartment of the wrist show focal enlargement, hypoechoic swelling, and loss of normal fibrillar echotexture and tendon appears disorganized with evidence of increased vascularity on color ultrasound. This is an example of tendinopathy or tendinosis.

Focal tendon tears appear as anechoic or hypoechoic focal defects in tendon substance. Image 5 shows a partial tear of the triceps tendon from the olecranon process. The partial tear appears as a focal hypoechoic defect in the tendon, which is confirmed in the long and short axis scan of the tendon.

In full-thickness tears, the tendon is seen retracted proximally with no fiber attachment at the tendon footprint. Image 6 shows an example of a full thickness complete tear of the supraspinatus tendon from its bony attachment at the greater tubercle. The tendon has retracted proximally and the retracted stump is not visible on ultrasound examination.

Image 6

Point-of-care ultrasound adds significant value to clinical examination in an orthopedic setting. It enhances the understanding of a patient’s problem, increases confidence in the care provided, and high patient satisfaction is reported.

In what unexpected ways do you find ultrasound to be useful? Do you have additional tips for using ultrasound in orthopedics?  Comment below or let us know on Twitter: @AIUM_Ultrasound.

Mohini Rawat, DPT, MS, ECS, OCS, RMSK, is program director of Fellowship in Musculoskeletal Ultrasonography at Hands On Diagnostics and owner of Acumen Diagnostics. She is ABPTS Board-Certified in Clinical Electrophysiology; ABPTS Board-Certified in Orthopedics; registered in Musculoskeletal Sonography, APCA; and has an added Point-of-Care MSK Soft Tissue Clinical Certificate.

Ultrasound-Guided Musculoskeletal Injections

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I began using Musculoskeletal (MSK) ultrasound (US) in 2010. It has been incredibly exciting to observe the growth of applications of this amazing technology for both myself personally as well as for the entire MSK US practicing community. MSK US has become an integral part of my Sports Medicine practice and I certainly anticipate its’ role to continue to expand and be able to provide cutting-edge medical care to my patients.IMG_8265

There is great variability with which MSK US is used among practitioners. Some providers do complete diagnostic scans of the shoulder, for example, to evaluate the extent of a potential rotator cuff tear to guide with potential surgical decision making, while others perform selective nerve blocks and finally, some practitioners simply use it to assist with the accuracy of various MSK joint and soft tissue injections. I would like to illustrate to all of you the applications for which I most commonly use MSK US to improve patient care.

Probably the most common application for which I use MSK US is to assist with the accuracy of joint and soft tissue injections. It has been clearly documented that MSK US improves the accuracy of certain MSK injections. While I do not use MSK US for all injections, ie, simple knee intra-articular and shoulder sub-acromial injection, I routinely employ MSK US to assist with certain injections. Common joints and soft tissue areas for which I employ MSK US for either cortisone or pro-inflammatory injections like Platelet Rich Plasma (PRP) are:

Shoulder: Glenohumeral and acromioclavicular joint and long head biceps tendon sheath

Hip: Femoroacetabular, hamstring origin (tendon or bursa), mid-portion hamstring, pubic symphysis, gluteal tendons and bursa, iliopsoas bursa and tendon

Knee: Pes anserine and iliotibial bursae, patella and quadriceps tendons, Baker’s cyst aspiration

Wrist: Triangular fibro cartilage complex (TFCC), various wrist extensor and flexor tendons, aspirate ganglion cysts, numerous hand and wrist joints

Elbow: Lateral and medial epicondyle area, triceps insertion, olecranon bursitis, distal biceps and intra articular

Ankle: Achilles, tibialis posterior, peroneal tendons, numerous foot and ankle joints, plantar fascia

Back: Sacroiliac joint

I would also like to illustrate some interesting recent cases supporting the utility of MSK US in a Sports Medicine practice.

I am consulted numerous times a week by my orthopedic surgeon colleagues for diagnostic joint injections. Oftentimes, a patient’s hip pain may be multifactorial or difficult to specifically isolate. I will perform an intra-articular injection to see if it alleviates that patient’s pain, thus identifying that the area in which I placed the injection as the pain generating location. Correct identification of the pain generating source will help to assist with treatment considerations.

I also recently had a patient with greater than 1 year of hip pain. He had seen 8 different providers and had an extensive workup with imaging and injections only to have continued pain. He had hip joint and hamstring origin injections and felt no improvement. I was able to use the US to identify and isolate the obturator internus as the source of his pain by providing a diagnostic injection. This injection helped to make the appropriate diagnosis and ultimately influenced treatment.

Last month, an orthopedic surgeon asked me to evaluate a patient for refractory symptoms from a Baker’s cyst. The cyst persisted despite multiple intra articular-injections. I evaluated the cyst with US and noted that it was multilobulated. I was able to specifically aspirate each of the loculations and the patient has remained symptom-free.

I was also asked to see one of our varsity basketball players for refractory lateral knee pain. His athletic trainer was treating him with rehabilitation and multiple modalities but the pain persisted and was affecting the athletes’ ability to play. I was able to identify an inflamed Iliotibial band bursa with the US and subsequently inject it. He became pain-free and was able to play in that weeks’ game as well as the rest of the season.

Another exciting application of MSK US that has piqued my interest recently is the use of the US to assist with appropriately identifying the compartments of the lower extremity for chronic exertional compartment testing. I can employ the US to guarantee that I am in the appropriate anatomic compartment for testing.

With any new technology, the application and utility of MSK US can be user-dependent and it can be affected by a somewhat steep learning curve. MSK US curriculums are frequently being added to Sports Medicine fellowships to train some of the future leaders of medicine. I certainly anticipate that this technology with continue to evolve and its’ treatment applications will continue to expand.

How do you use MSK US? How has it improved your practice? Comment below or let us know on Twitter: @AIUM_Ultrasound.

Bryant Walrod, MD, CAQSM, is Assistant Professor: Clinical at Ohio State University, is Team Physician for the Ohio State Athletics, and practices at The Ohio State University Wexner Medical Center.

Interdisciplinary Education and Training in MSK Ultrasound

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In my primary specialty of occupational medicine there is a need for practical education in musculoskeletal ultrasound for both diagnostic evaluation and therapeutic interventional guidance. Incorporation of this into education has begun recently and is continuing in the specialty. A wide variety of specialties are represented in occupational medicine, including many specialists who move into the field after a mid-career transition.

Interestingly, over the last few years, clinicians have approached me and asked me to help them learn musculoskeletal ultrasound from many different disciplines outside of occupational medicine. These have included emergency medicine, orthopedics, rheumatology, sports medicine, family medicine, radiology, palliative care, and physical medicine and rehabilitation. When inquiring into why these clinicians are seeking training in this modality it seems that the consistent answer is thdr-sayeedat medical students are graduating and insisting on using ultrasound in their residency training. It would seem that many of our medical students are learning ultrasound at a rate that will outpace attending physician knowledge, exposure, and experience. Indeed, when teaching ultrasound to many of the medical students at West Virginia University as part of their medical education, I was astounded to see how proficient they were at using the machine, the transducer, and correctly identifying both normal and pathologic anatomy. It’s my understanding that many universities have included medical ultrasound into the academic curricula as a bridge to their respective gross anatomy courses and in their general clinical medical education.

Ultrasound is a modality utilized by many medical specialties for various indications. Several specialties outside of radiology, including the ones above, utilize ultrasound. Increasingly, residency programs are integrating ultrasound into their ACGME-accredited curriculum and, importantly, medical students are also learning the benefits of using the modality. It seems clear that despite the number of pitfalls, hurdles, and difficulties using ultrasound, the modality has proven to be an asset in clinical settings and has become a permanent fixture in hospital and clinical settings. The benefits of utilizing ultrasound have been well documented across many academic medical journals. I believe that medicine, as a whole, has done well to embrace the modality, however, there seems to be another vital step to take in the education arena to more fully integrate the modality into our patient’s care.

Currently, most education models for teaching ultrasound, whether it is for residents or medical students, involves grouping like kind together. Emergency residents learn it in the emergency medicine didactics. Physical medicine and rehabilitation (PM&R) residents learn it from demonstrations in their own didactics, and so on. Perhaps approaching the curriculum from a more inclusive perspective, however, would be more beneficial for residents and fellows. I, personally, had experience teaching an integrated musculoskeletal course at West Virginia University. The idea, admittedly, was born out of necessity. Physicians experienced in ultrasound from sports medicine, emergency medicine and occupational medicine created and executed a curriculum to teach musculoskeletal ultrasound and invited residents from other specialties. The interest we were able to garner quite frankly surprised me. Although the curriculum was targeted to occupational medicine residents the interest in using musculoskeletal ultrasound was widespread. Residents from specialties like emergency medicine, radiology, family medicine, internal medicine, and orthopedics attended our sessions.

While the course was a success, introducing an integrated curriculum across medical specialties posed a new set of challenges. My specialty was able to use dedicated didactic time for the education but many other specialties have disparate educational time. Many residents could not make all of the sessions and many more could not make any sessions because of fixed residency schedules. This makes coordination very difficult. As I have pondered this over the last few months I believe that educational leaders should begin to form structured educational collaborative time for activities like education in musculoskeletal ultrasound. Each discipline will be able to contribute to teaching to ensure high quality evidence-based curriculum for residents learning ultrasound. Each discipline has their individual strengths and collaboration ensures coordination and even learning amongst instructors. Integrating medicine has been a goal of thought leaders in medicine at the very highest levels and can be replicated for the instruction and training of our resident physicians.

Another option is to allow residents to attend the American Institute of Ultrasound in Medicine’s annual conference where interdisciplinary education in ultrasound occurs. This conference even has a day for collegial competition among medical students and schools. In fact, the courses are created to encourage engagement in the education and training of clinicians at all levels of training. The overall goal is to advance the education and training in this modality and hope that education leaders begin to encourage collaboration in a much larger scale thus achieving integrated medical care that provides a building block to lead to high quality evidence-based medical care for our patients, families, and communities.

What other areas of ultrasound education have room to grow? How would you recommend making changes? Do you have any stories from your own education to share? Comment below or let us know on Twitter: @AIUM_Ultrasound.

Yusef Sayeed, MD, MPH, MEng, CPH, is a Fellow at Deuk Spine Institute, Melbourne, FL.