El retículo endoplasmático liso en hepatocitos estimulados con distintas dosis de láser infrarrojo / The smooth endoplasmic reticulum in hepatocytes stimulated with different doses of infrared laser

Veinticuatro ratas hembras Sprague Dawley de 4 meses de vida con peso aproximado de 250 g, fueron divididas en cuatro grupos (A, B, C y D), donde el grupo A (control) no recibió estimulación infrarroja, B se irradió con láser infrarrojo 4 J/cm², C con dosis de 8 J/cm² y D con 16 J/cm². La estimulación infrarroja se realizó diariamente, por 15 días ininterrumpidos. Las ratas fueron sacrificadas y se extrajeron muestras tanto de hígado normal (control) como estimulado con las distintas dosis infrarrojas, las que fueron procesadas para microscopía electrónica de transmisión. De los hepatocitos normales y estimulados, se obtuvieron microfotografías con aumentos finales de hasta 36.500 X, que fueron sometidas a estudios morfométricos para determinar fracciones volumétricas con especial énfasis en el retículo endoplásmico liso (REL) y de los siguientes componentes celulares: retículo endoplasmático rugoso (RER), mitocondrias, glicógeno, eu y heterocromatina. De igual manera se cuantificaron las áreas celulares y nucleares. Del análisis de los resultados entre hepatocitos normales y estimulados con diferentes dosis infrarrojas, se visualiza que existen notables diferencias en todos los componentes celulares cuantificados particularmente el REL. Se concluye que las estimulaciones infrarrojas provocan una drástica transformación en la ultraestructura y morfología de los hepatocitos, lo que provocaría una variación funcional, representando de esta manera el efecto que estas estimulaciones provocan en este tipo celular.

A total of 24 female Sprague-Dawley rats aged 4 months and weighing approximately 250 g, were divided into four groups labeled A, B, C and D. Group A received no infrared stimulation and served as control. Group B was radiated with a dose of 4 J/cm² of infrared laser, Group C with doses of 8 J/cm² and Group D with 16 J/cm². This infrared stimulation was carried out daily for 15 days uninterrupted. The rats were then sacrificed and samples of both normal-control liver and liver stimulated with the different infrared doses were extracted for immediate processing via transmission electron microscopy. Transmission electron microphotographs were obtained at magnifications of 21300X from both normal and stimulated hepatocytes; these were subjected to morphometric studies to determine volumetric fractions with special emphasis on the smooth endoplasmic reticulum (SER) and the following cell components: rough endoplasmic reticulum (RER), mitochondria, glycogen, eu and heterochromatin. Likewise, cell and nuclear areas were quantified. Analysis of the results of normal and stimulated hepatocytes with different infrared doses showed considerable differences in all the quantified cell components and particularly from the SER it is concluded that the effects of these stimulations bring about a drastic transformation in the ultrastructure and morphology of the hepatocytes, which may ultimately translate into a functional variation, thus representing the effect that these stimulations cause in this cell type.

Pulsed radiofrequency effects on the lumbar ganglion of the rat dorsal root: a morphological light and transmission electron microscopy study at acute stage.

Since the dorsal root ganglia represent the first structure of pain modulation, they are the target of the newest therapies of neuropathic pain. Between these, pulsed radiofrequency (PRF) has been described among the promising non-invasive methods. Although the results encourage the clinical use of this procedure, their mechanism of action is still unclear. Aim of our study was to analyze acute effects of PRF on the rat lumbar ganglion and on nervous fibres running inside it. Clinical works describe PRF treatment as a technique without any visible neurological deficit. The few disposable histological works are contractictory: some describe no signs of cellular damage and some demonstrate visible intracellular modifications. A total of 20 male Wistar rats were deeply anesthesized. Ten were positioned in a stereotactic system, and exposed to PRF at 2 Hz for 30 s after exposition of paravertebral muscles and positioning of a stimulation needle on left L4 ganglion. The other ten were used as controls. After 1 h, the left dorsal root ganglions L3, L4, L5 of the 20 animals were explanted, fixed in 2.5% Karnowsky solution and prepared for light and transmission electron microscopy. At light microscopy no differences between treated and control animals were observed; at transmission electron microscopy, instead, it was possible to observe that T gangliar cells contained an abnormal abundant smooth reticulum with enlarged cisternae and numerous vacuoles; myelinated axons presented pathological features and their myelin coverage was not adherent. Instead, unmyelinated axons appeared normal in shape and dimension and the Schwann cells surrounding it had intact plasmamembrane. Our results, obtained at acute stage, reveal that the PRF procedure should destroy the myelin envelope of nervous fibres. Further future studies, at chronic stage, should give other information on the prognosis of the myelinic damage.