Spinal Cord Mass Arising From Neural Stem Cell Therapy
Embargo expired: 8-Jul-2014 4:00 AM EDT
Source Newsroom: Journal of Neurosurgery
Newswise — Charlottesville, VA (July 8, 2014). A spinal mass was identified in a young woman with complete spinal cord injury 8 years after she had undergone implantation of olfactory mucosal cells in the hopes of regaining sensory and motor function. The case is reported and discussed in “Autograft-derived spinal cord mass following olfactory mucosal cell transplantation in a spinal cord injury patient. Case report,” by Brian J. Dlouhy, MD, Olatilewa Awe, MD, Rajesh C. Rao, MD, Patricia A. Kirby, MD, and Patrick W. Hitchon, MD, published today online, ahead of print, in the Journal of Neurosurgery: Spine (http://thejns.org/doi/full/10.3171/2014.5.SPINE13992). The authors state that this is the first report of a spinal cord mass arising from spinal cord cell transplantation and neural stem cell therapy, and they caution that physicians should be vigilant in their follow-up of patients who undergo stem cell interventions.
In its natural state, the olfactory mucosa lines the roof of the nasal cavity, adjacent to the respiratory mucosa that lines the lower nasal cavity. In addition to smell receptor neurons, the olfactory mucosa contains progenitor cells (also known as adult stem cells) and olfactory ensheathing cells—both of which have been shown to aid in the repair of the injured spinal cord in laboratory studies and in humans. The respiratory mucosa, on the other hand contains mucus-secreting goblet cells and mucus and serous fluid¬–producing cells.
The patient was 18 years old when she sustained a fracture dislocation at the 10th and 11th thoracic vertebral level in a motor vehicle accident. Despite surgery to stabilize the spine, the injury rendered the patient paraplegic. Three years later, in the hopes of regaining sensory and motor function in her lower limbs, the young woman underwent additional surgery at an institution outside the United States, during which an autograft of olfactory mucosa was placed in her spinal canal at the site of injury. Eight years after the experimental therapy, the woman sought medical care for mid- to lower-back pain at the University of Iowa Hospitals and Clinics. On neurological examination, she showed no sign of clinical improvement from the olfactory mucosal cell implantation, and imaging studies revealed a mass in her spinal canal pressing against the spinal cord. This mass was the source of the patient’s pain.
Following surgery to remove the symptom-producing mass at the University of Iowa, a tissue analysis showed that the mass contained a small proportion of nonfunctional tiny nerve branches, whose appearance led the authors to suspect the nerve branches developed from transplanted neural stem-like cells. The tissue analysis also demonstrated that most of the mass consisted of multiple cysts lined with respiratory mucosa and underlying submucosal glands and goblet cells. Abundant mucus-like material was also found in the mass. Accumulation of this material over time produced the patient’s symptoms.
The authors describe various ways of extracting olfactory mucosa cells for implantation. In this particular case, a portion of olfactory mucosa was transplanted; in other trials, olfactory ensheathing cells have been extracted from olfactory mucosa and purified prior to implantation. The authors suggest that the choice of bulk olfactory mucosa rather than purified olfactory ensheathing cells or stem cells as an autograft may lead to the development of a mass containing functional respiratory mucosal cells.
The authors point out that a rare case of spinal cord complication such as this should not discourage stem cell research and/or the transition of promising research to the clinical setting. However, the authors indicate the need for a better understanding of what can occur and urge clinicians to extend the monitoring period in patients treated with neural stem cell therapy for many years in case an adverse event such as this should arise. In summarizing the take-away message of the paper, Dr. Brian Dlouhy stated: "Exhaustive research on how transplanted cells divide, differentiate, and organize in animal models of disease, especially spinal cord injury, is critical to providing safe and effective treatments in humans."
Dlouhy BJ, Awe O, Rao RC, Kirby PA, Hitchon PW. Autograft-derived spinal cord mass following olfactory mucosal cell transplantation in a spinal cord injury patient. Case report. Journal of Neurosurgery: Spine, published online, ahead of print, July 8, 2014; DOI: 10.3171/2014.5.SPINE13992.
Disclosure: The authors report no conflict of interest concerning the materials or methods used in this study or the findings specified in this paper.
The authors are located at the University of Iowa Hospitals and Clinics (Drs. Dlouhy, Awe, Kirby, and Hitchon) and the University of Michigan Medical School (Dr. Rao).
Accompanying this paper is an editorial highlighting the potential dangers of cell transplantation in the injured spinal cord and the need for formal follow-up and reporting: Heary RF. Editorial: Autograft-derived spinal cord mass following olfactory mucosal cell transplantation, Journal of Neurosurgery: Spine, published online, ahead of print, July 8, 2014; DOI: 10.3171/2014.2.SPINE131172.
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The Journal of Neurosurgery: Spine is a monthly peer-reviewed journal focused on neurosurgical approaches to treatment of diseases and disorders of the spine. It contains a variety of articles, including descriptions of preclinical and clinical research as well as case reports and technical notes. The Journal of Neurosurgery: Spine is one of four monthly journals published by the JNS Publishing Group, the scholarly journal division of the American Association of Neurological Surgeons. Other peer-reviewed journals published by the JNS Publishing Group each month include the Journal of Neurosurgery, Neurosurgical Focus, and the Journal of Neurosurgery: Pediatrics. All four journals can be accessed at www.thejns.org.
Founded in 1931 as the Harvey Cushing Society, the American Association of Neurological Surgeons (AANS) is a scientific and educational association with more than 8,300 members worldwide. The AANS is dedicated to advancing the specialty of neurological surgery in order to provide the highest quality of neurosurgical care to the public. All active members of the AANS are certified by the American Board of Neurological Surgery, the Royal College of Physicians and Surgeons (Neurosurgery) of Canada or the Mexican Council of Neurological Surgery, AC. Neurological surgery is the medical specialty concerned with the prevention, diagnosis, treatment and rehabilitation of disorders that affect the entire nervous system including the brain, spinal column, spinal cord, and peripheral nerves. For more information, visit www.AANS.org.