Evans blue staining of cardiomyocytes induced by myocardial contrast echocardiography in rats: evidence for necrosis instead of apoptosis.
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High mechanical index (MI) echocardiography with contrast agent has been shown to induce Evans blue staining of cardiomyocytes, seen 1 d after exposure, in addition to contraction band necrosis, seen immediately after exposure. This research examined the roles of necrosis vs. apoptosis in these bioeffects. Myocardial contrast echocardiography at high MI with 1:4 electrocardiogram triggering was performed in anesthetized rats at 1.5 MHz. Histologically observable cell injury was accumulated by infusing a high dose of 50 microL/kg ultrasound contrast media via tail vein for 5 min at the start of 10 min of scanning. Evans blue dye or propidium iodide was injected as an indicator of cardiomyocyte plasma membrane integrity. Histologic sections were stained using the terminal dUTP nick-end labeling (TUNEL) method for labeling nuclei with DNA degradation (e.g., apoptosis). Evans blue fluorescent cells were counted on frozen sections or on hematoxylin-stained and TUNEL-labeled paraffin sections. In addition, transmission electron microscopy was used to assess potential apoptotic nuclei. Hypercontraction and propidium iodide staining were observed immediately after imaging exposure. Although TUNEL-positive cells were evident after 4 h, these also had indications of contraction band necrosis, and features of apoptosis were not confirmed by electron microscopy. Inflammatory cell infiltration was evident after 24 h. A second, more subtle injury was recognized by Evans blue staining, with minimal inflammatory cell infiltration at the morphologically intact stained cells after 24 h. Apoptosis was not detected by the TUNEL method in the cardiomyocytes stained with Evans blue at 24 h. However, Evans blue-stained cell numbers declined after 48 h, with continued inflammatory cell infiltration. The initial insult for Evans blue-stained cardiomyocytes apparently induced partial permeability of the plasma membrane, which led to gradual degeneration (but not apoptosis) and necrosis after 24 to 48 h. (+info)
Effects of environmental enrichment on thermal sensitivity in an operant orofacial pain assay.
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Environmental enrichment reduces reactivity to stressor and could also modulate pain perception. In this study we sought to compare the effects of enriched and standard housing on temperature perception. In an operant assay, rats housed in an enriched environment exhibited significantly lower sensitivities to thermal stimuli and displayed less exploratory behavior in a rearing chamber. These findings indicate that environmental enrichment can significantly affect temperature perception, likely through stress-related mechanisms. (+info)
Analysis of skin disposition of flurbiprofen after topical application using dual agar gel discs-inserted rats.
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Most of the drug fraction penetrating the skin after topical application is taken up by the cutaneous blood flow, although the rest directly migrates into deeper tissues such as the subcutis and muscle. A new in situ experimental hairless rat model was designed to distinguish these fractions of topically applied drugs. Flurbiprofen, a non-steroidal anti-inflammatory drug, was selected as the model drug. In this model, two agar gel discs were subcutaneously inserted into the abdominal region of hairless rats as a drug receptor, and a topical formulation containing the drug was placed above either side of the gel disc. Plasma and agar levels of flurbiprofen were followed every 2 h over 10 h. The migration fraction of the drug into the systemic circulation and that directly to subcutaneous tissues were calculated to be 99.8% and 0.2% against the total amount which penetrated the skin, and the drug ratios into agar gel from the systemic circulation and not from the systemic circulation (i.e. directly migrated from the formulation) were 16.0% and 84.0%, respectively, at 10 h. This in situ drug disposition profile in skin was similar to the in vivo profile calculated from the in vivo muscle amount of flurbiprofen using muscle clearance. These results clearly suggest that the present in situ experimental model is a valuable tool for easy analysis of the skin disposition of topically applied drugs. (+info)
Investigation of drug delivery by iontophoresis in a surgical wound utilizing microdialysis.
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PURPOSE: This study investigated the penetration of lidocaine around and through a sutured incision following the application of iontophoretic and passive patches in the CD Hairless rat. MATERIALS AND METHODS: Concentrations in localized areas (suture, dermis, subcutaneous, and vascular) were determined using microdialysis sampling followed by analysis using liquid chromatography with UV detection. RESULTS: Iontophoresis significantly enhanced the dermal penetration of lidocaine. In an intact skin model, dermal concentrations were 40 times greater following iontophoretic delivery compared to passive delivery. In a sutured incision model, iontophoresis enhanced localized concentrations in the dermis, suture, and subcutaneous regions by 6-, 15-, and 20-fold, respectively. Iontophoretic delivery to a region containing a sutured incision was focused to the incision resulting in a greater increase in the suture concentration and in the subcutaneous region directly below the incision. CONCLUSIONS: The four microdialysis probe design was successful in the determination of localized drug penetration in a sutured incision model. Iontophoresis enhanced skin penetration and allowed for site specific delivery when applied to a sutured incision. (+info)
Analysis of skin disposition and metabolism of ethyl nicotinate after topical application using dual agar gel disc-inserted rats.
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The skin disposition and metabolism of topically applied ethyl nicotinate (EN) were evaluated in dual agar gel disc-inserted hairless rats, which have two agar gel discs subcutaneously inserted into the abdominal region as drug receptors, and a topical formulation containing EN placed on either side of the gel disc through the skin. Plasma and agar levels of EN and its metabolite, nicotinic acid (NA), were followed every 2 h over 6 h. EN permeated through the skin barrier and partly metabolized to NA with 89.4% of the metabolite ratio [NA/(EN+NA)] at 6 h. Some EN and NA in the skin moved to the systemic circulation, and the remainder migrated into the agar gel below the formulation. The total amount (EN+NA) in the skin that distributed from the formulation directly to the systemic circulation and the application side of the gel corresponded to 95.2% and 4.8% of the total skin permeation at 6 h, respectively. Only NA was distributed from the systemic circulation to both agar gel discs. The NA fraction in the application side of the gel from the circulation was only 1% of the total amount in the agar gel. The metabolite ratio on the application side of the agar gel was higher than that in the receiver for the in vitro skin permeation using excised hairless rat skin. This difference was probably related to a lower EN ratio in viable skin in situ than in vitro. These results suggest that the present in situ method is useful to evaluate the skin disposition and metabolism of topically applied drugs. (+info)
MDI 301, a nonirritating retinoid, improves abrasion wound healing in damaged/atrophic skin.
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