Spinal cord stimulation (SCS) applied between T8 and T11 segments has been shown to be effective for the treatment of chronic pain of the lower back and limbs. However, the mechanism of the analgesic effect at these medullary levels remains unclear. Numerous studies relate glial cells with development and maintenance of chronic neuropathic pain. Glial cells are electrically excitable, which makes them a potential therapeutic target using SCS. The aim of this study is to report glia to neuron ratio in thoracic segments relevant to SCS, as well as to characterize the glia cell population at these levels. Dissections from gray and white matter of posterior spinal cord segments (T8, T9, intersection T9/T10, T10 and T11) were obtained from 11 human cadavers for histological analyses. Neuronal bodies and glial cells (microglia, astrocytes and oligodendrocytes) were immunostained, microphotographed and counted using image analysis software. Statistical analyses were carried out to establish significant differences of neuronal and glial populations among the selected segments, between the glial cells in a segment, and glial cells in white and gray matter. Results show that glia to neuron ratio in the posterior gray matter of the human spinal cord within the T8–T11 vertebral region is in the range 11 : 1 to 13 : 1, although not significantly different among vertebral segments. Glia cells are more abundant in gray matter than in white matter, whereas astrocytes and oligodendrocytes are more abundant than microglia (40 : 40 : 20). Interestingly, the population of oligodendrocytes in the T9/T10 intersection is significantly larger than in any other segment. In conclusion, glial cells are the predominant bodies in the posterior gray and white matter of the T8–T11 segments of the human spinal cord. Given the crucial role of glial cells in the development and maintenance of neuropathic pain, and their electrophysiological characteristics, anatomical determination of the ratio of different cell populations in spinal segments commonly exposed to SCS is fundamental to understand fully the biological effects observed with this therapy.
Background: Epidural steroid injection (ESI) is a common practice for pain treatment since 1953. In 2014, the FDA issued a warning about ESI. Studies have focused on the effect of the particle size and their ability to generate harmful aggregates. Although steroid aggregates provide longer times for reabsorption, therefore a longer anti-inflammatory effect, they are potentially harmful to the central nervous system via embolic mechanisms. Previous studies have established that steroidal aggregates with asizes over 100 μm are potentially able to occlude blood vessels. Studies by Tiso et al and Benzon et al addressed the role of steroids on CNS adverse events, with similar outcomes. The main difference was on the role of aggregates with a size over 100 μm, which Benzon et al. attributed to the ability of certain steroid preparations to rapidly precipitate and form large aggregates. Objectives: Studying the effect of the time elapsed between mixing the steroid preparation and injection on the number and size of aggregates with sizes above 100 μm. Study Design: Original study in basic science. Setting: Basic science Methods: Steroids evaluated are commonly used in Spain for ESI: betamethasone, triamcinolone, and dexamethasone. The size and number of the aggregates was determined for undiluted commercial steroid preparations in the usual amount for a single and double dosage used for ESI. Samples were examined with a Leica TCS-SP2 microscope at the first, the fifth and the 30th minute after shaking the preparations. Aggregates observed in the different preparations were manually counted and grouped in the following size range: 0-20, 20-50, 50-100, 100-300, 300-500 and > 500 μm. Statistical analysis was carried out using the R software. Nonparametric techniques were used in the comparison of aggregate size. Global comparison of the groups using the Kruskal-Wallis test and post-hoc comparisons using the Wilcoxon test, adjusting P-values by the Holm method for multiple comparisons Results: Aggregates present in triamcinolone and betamethasone samples were statistically larger than in dexamethasone samples. Triamcinolone suspensions produced significantly larger aggregates than betamethasone five minutes after mixing. Triamcinolone preparations produced greater particle aggregates (> 500 μm), which were not present in dexamethasone and betamethasone preparations. Limitations: Study how the human internal factors like blood elements and spinal fluid could interact with steroids and influence the size of the aggregates formed. Conclusions: This study demonstrates that the size of the particles injected depends on the type of steroid and the time allowed between mixing and injecting. The results demonstrate that waiting longer than 5 minutes between mixing and injecting can predispose the formation of potentially harmful aggregates in triamcinolone and betamethasone samples. The presence of greater particle aggregates (> 500 μm) may occlude some important vessels and arteries with serious adverse results. Vigorous shaking of the injectable could prevent such events. Key words. Epidural steroid injection. Triamcinolone. Betamethasone. Dexamethasone. Steroid aggregates.
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