Autofluorescence as a tool to study mucus secretion in Eisenia foetida.

Autofluorescence in living cells is due to the presence of endogenous substances that emit fluorescence upon excitation by incidental light. A type of fluorescence, bioluminescence, has been suggested to be linked to mucus secretion in earthworms; however, the origin and the physiological function of this fluorescence are not clear. The aims of this work were to describe autofluorescence in the earthworm Eisenia foetida by SEM, CLSM, and fluorescence microscopy and to examine the possible mechanism of mucus secretion by video microscopy. Earthworms were stimulated either chemically or electrically to induce the secretion of yellow mucus, which was subsequently studied by video microscopy. Mucus was released from the body wall and near the mouth. This phenomenon was associated with autofluorescence and involved at least four distinct stages: release of vesicles, formation of granules, muscular contraction, and organization of strands. The fluorescent molecules were stored in vesicles bound to the membranes. These vesicles were intact when shed from the body. The vesicles were stable but also changed to a granular material or formed strands. Video analyses demonstrated that secretion was dependent on the type of stimulus.

Experimental infection of swine and cat central nervous systems by the pig paramyxovirus of the blue eye disease.

This study analyses whether the pig paramyxovirus of blue eye disease (PPBED) infects the central nervous system (CNS) utilizing anterograde and retrograde peripheral nerve transport systems. The virus was injected into muscle and skin, and inoculated per nasum. The presence of PPBED was detected by an immunohistochemical method using polyclonal mouse antibodies against the whole inactivated virus, and was revealed with polyclonal rabbit antibodies against mouse immunoglobulin G (IgG) labelled with peroxidase. The PPBED injected into the pig medial gastrocnemius (MG) muscle was detected in a terminal branch innervating the MG muscle, in neural fibres of the sciatic nerve, in fibres of the ventral and dorsal spinal roots and in ventral horn neurones of the spinal cord. When PPBED was injected into the skin area innervated by the sural nerve, it was detected in neural fibres of the sural and sciatic nerves and in spinal cord dorsal horn neurones. The per nasum inoculum rapidly invaded the CNS through the olfactory nerve. The study concluded that, in order to invade the CNS, PPBED was transported retrogradely by peripheral cutaneous and muscular nerves, and anterogradely by the olfactory nerve. No PPBED was detected in either cat peripheral nerves or in cat CNS.

[Polyhydramnios and its relationship with congenital malformations: ultrasonographic diagnosis]. / Polihidramnios y su relación con malformaciones congénitas: diagnóstico ultrasonográfico.

We analyzed the occurrence of polyhydramnios during pregnancy and to indicate the association with congenital abnormalities of the product and maternal alterations. A retrospective descriptive and transversal study was performed which included 6087 pregnant patients who were submitted to ultrasonographic studies from January 1, 1991 to December 31, 1993. The final sample consisted of 72 patients with criteria of polyhydramnios and who had a complete, clinical history, specific data concerning the reproductive history and maternal risk factors associated with polyhydramnios and fetal malformations was compiled. The occurrence of polyhydramnios during pregnancy was 1.1% and the association with congenital malformations was 13.8%, being the majority neural tube defects. The maternal alterations were related in 13.7% to polyhydramnios, being primary cause gestational diabetes. Anencephalia presented a significant statistics (p < 0.05). The occurrence of polyhydramnios is low in obstetric patients. Neural tube defects such as anencephalia are the primary fetal defects. Gestational diabetes and multiple gestations are the more significant maternal alterations.

Efficacy of a putative GABA analog on synaptic transmission in the cat spinal cord.

4-Hydroxy-4-phenylcaproamide (HPhCA), at high doses or rates of IV injection depressed the ventral root reflexes elicited by nerve or dorsal root stimulation. The D (direct) and I (synaptic) ventral root waves and the antidromic (A) dorsal root wave evoked by intraspinal stimulation were also depressed. Similar effects were produced when HPhCA was applied topically on the cord dorsum. At 80 mg/kg and 8 mg/kg/min, the spinal reflexes and the I wave were facilitated for 4 to 6 h, but the D and A waves were depressed. Intracellular recordings from motoneurons showed that HPhCA injection produced: hyperpolarization that lasted several hours, short lasting (< 20 min) facilitation of both EPSPs and IPSPs as well as spike-like potentials (SLPs) that were triggered by EPSPs even though the neuron was hyperpolarized. SLPs may reach the threshold for full spikes. Our results suggest that the spinal depression results from hyperpolarization of motoneurons and the initial facilitation appears to be presynaptic. The late facilitation may be produced by SLPs. HPhCA does not appear to mimic the actions of GABA in primary afferents fibers and motoneurons.

Long-term enalapril and hydrochlorothiazide in radiation nephritis.

Radiation of the kidney often leads to renal failure. The contribution of arterial hypertension to the development of this complication is unclear. The aim of this study was to determine the renal effects of antihypertensive therapy in 1- and 2-kidney rat models of radiation nephritis. Five groups of Long Evans rats had X-irradiation of the left kidney. In groups 1 and 2, the right kidney was left undisturbed (2-kidney model). The rats in group 3, 4 and 5 underwent right nephrectomy 21 days before radiation (1-kidney model). Groups 1 and 3 received no drug treatment and served as controls for each model. Groups 2 and 4 had enalapril 50 mg/l in drinking water and group 5 hydrochlorothiazide (HCT) 200 mg/l, also in drinking water. Blood pressure increased significantly in both control groups and remained normal throughout the study in all treated groups. At the end of the study, mean urinary protein excretion was lower in the two enalapril-treated groups but not in HCT-treated animals. Groups 1 and 2 (2-kidney models) showed similar increments in plasma creatinine (PCreat), and, in both groups, the creatinine clearance (CCreat) dropped to the same extent. Among nephrectomized animals (1-kidney model), PCreat was lower and CCreat higher in the enalapril-treated group. Consistent with these findings, glomerular sclerosis was less severe in both enalapril-treated groups. We conclude that, in radiation nephritis, lowering blood pressure with enalapril exerts a beneficial effect on renal function and structure, whereas a similar reduction in blood pressure induced by HCT does not.

Monosynaptic and dorsal root reflexes during locomotion in normal and thalamic cats.

1. In normal and thalamic walking cats electrical stimulation of muscle nerves via chronically implanted electrodes produced electromyographic (EMG) and neurographic responses that were modulated in amplitude depending on the phase of the step cycle. These responses were examined for possible indications of effects of primary afferent depolarization (PAD) during stepping. 2. Monosynaptic reflexes (MSRs) produced by stimulating the lateral gastrocnemius (LG) and medial gastrocnemius (MG) nerves were recorded as EMGs in MG or LG muscles during treadmill locomotion in normal cats. These heteronymous MSR responses were greatest during the stance (extensor) phase. 3. In the same animals, after decerebration, similar modulation of the heteronymous ankle extensor MSRs occurred during spontaneous locomotion with the use of the same stimulus and recording sites. 4. In both normal and thalamic cats the amplitude of neurogram responses recorded from LG or MG nerve after stimulation of the other muscle nerve varied with phase of stepping but did not parallel the variations of the MSR measured as EMG amplitude in the same muscle. The nerve responses were largest during the flexion phase of the step cycle and had a calculated central latency of 0.6-1.0 ms. These are interpreted as arising from antidromic activity in large-caliber afferent nerve fibers (i.e., dorsal root reflexes). 5. Spontaneous antidromic activity in severed L7 dorsal rootlet fibers to triceps surae was observed in the thalamic cats during episodes of locomotion and was closely correlated with flexion phase EMG activity in semitendinosus, a bifunctional muscle. 6. In decerebrate cats, dorsal root reflexes (DRRs) in severed filaments of L4-L7 dorsal roots were produced by stimulation of saphenous and posterior tibial nerves. These DRRs were always smaller during locomotion than during rest and were smallest during the flexion phase. 7. The short-latency antidromic activity produced in muscle nerves by stimulating heteronymous muscle nerves thus appears to be a DRR produced in Group I terminal arborizations that are depolarized close to threshold during the flexion phase. Such PAD could account for changes in the MSR that do not always parallel the levels of recruitment of the motor pools as manifest by background EMG amplitude.

Excitability changes of ankle extensor group Ia and Ib fibers during fictive locomotion in the cat.

The present study examines the modulation of gastrocnemius-soleus (GS) monosynaptic reflexes as well as the intraspinal threshold changes of GS group I primary afferent terminals ending in the intermediate and motor nuclei during fictive locomotion in high decerebrate cats. The amplitude of the monosynaptic reflexes (MSR's) evoked in the medial gastrocnemius by stimulation of the lateral gastrocnemius nerve was increased during the extensor (E) phase, decreased during the flexion (F) phase of the step cycle and remained transiently increased after spontaneous episodes of fictive stepping. The intraspinal threshold of populations and of single group Ia GS afferent fibers ending in the motor pool, as well as of single Ia and Ib fibers ending in the intermediate nucleus, showed a sustained reduction during the episodes of fictive locomotion with superimposed cyclic changes in phase with the step cycle. During fictive walking and trotting the reduction of the intraspinal threshold of both Ia and Ib fiber terminals was maximal during the middle or late portion of the F-phase. During fictive gallop elicited by stimulation of the superficial peroneus nerve, the decrease in the intraspinal threshold of the Ia afferent fibers occurred however in phase with the activity of the GS motoneurons. During episodes of fictive locomotion slow, sustained negative DC potential shifts lasting tents of seconds, reflecting an increase in the extracellular potassium concentration were recorded at the base of the dorsal horn and in the intermediate nucleus. The present findings support the existence of tonic and phasic depolarization of the intraspinal terminals of GS group Ia and Ib primary afferents during spontaneous fictive locomotion. It is suggested that accumulation of potassium ions in the extracellular space contributes mainly to the sustained depolarization of group I fibers. The phasic depolarization would be mostly due to the activation of specific sets of interneurons and may, in the case of Ia fibers, contribute to the cyclic modulation of the MRS elicited during fictive locomotion.

Sites of action of segmental and descending control of transmission on pathways mediating PAD of Ia- and Ib-afferent fibers in cat spinal cord.

The present series of investigations was aimed to disclose the possible sites of action of excitatory and inhibitory inputs on tho-interneuron pathway mediating the primary afferent depolarization (PAD) of group I afferents of extensor muscles in the cat spinal cord. To this end we compared the effects produced by stimulation of segmental and descending pathways on the PAD generated either by stimulation of group I fibers of flexor muscles or by intraspinal microstimulation. It was assumed that under the appropriate conditions the PAD produced by intraspinal microstimulation results from the activation of the last-order interneurons in the PAD pathway and may, therefore, allow detection pathway. The PAD of single group I afferent fibers was determined in barbiturate-anesthetized preparations by measuring the test stimulus current required to maintain a constant probability of antidromic firing. This was achieved by means of a feedback system that continuously adjusted the test stimulus current to the required values. The PAD of individual group Ia gastrocnemius soleus (GS) fibers that is produced by activation of the low-threshold afferents of the posterior biceps and semitendinosus nerve was found to be inhibited by conditioning stimulation of the relatively low-threshold cutaneous fibers and also by stimulation of supraspinal structures such as the ipsilateral brain stem reticular formation, the contralateral red nucleus, and the contralateral pyramidal tract. In contrast, the PAD of group Ia fibers produced by microstimulation applied in the intermediate nucleus could be inhibited only by stimulation of the brain stem reticular formation but not by stimulation of the other descending inputs presently tested or by stimulation of cutaneous nerves. PAD of group Ia fibers was produced also by microstimulation applied within the motor nucleus. However, in most fibers the resulting PAD could not be inhibited either by stimulation of the brain stem reticular formation, the red nucleus, the pyramidal tract, or cutaneous nerves. Stimulation of cutaneous and of flexor muscle nerves of the brain stem reticular formation, the red nucleus, and the pyramidal tract all produced PAD of the group Ib GS fibers.(ABSTRACT TRUNCATED AT 400 WORDS)