Sinclair Cleveland

Chronic inflammatory polyneuropathy: reduction of nerve conduction velocities in monkeys by systemic passive transfer of immunoglobulin G

In chronic (relapsing) inflammatory polyneuropathy (CRIP), successful treatment with plasma exchange has led to the concept of pathogenic humoral factors. In 6 patients with CRIP, 5 of whom improved after plasma exchange, the potential pathogenic role of circulating immunoglobulin (Ig) fractions was tested by applying the systemic passive transfer model to marmoset monkeys. After continuous treatment with intramuscular injections for 2-8 weeks, monkeys injected with the crude immunoglobulin fractions or with purified IgG from 5 of the 6 patients showed a significant and partially reversible reduction of the motor nerve conduction velocity (mean 34%, P less than 0.001) when compared with pre-treatment values. In control animals the reduction was 4%. Morphological examination revealed only minor ultrastructural changes of the myelin sheath. Immunocytochemistry revealed that human IgG was able to cross the blood-nerve barrier. It is concluded that the circulating IgG-fraction of patients with CRIP contains a factor that may contribute to the disordered nerve function after crossing the blood-nerve barrier. It may be the removal of this particular factor which is responsible for the rapid recovery of nerve conduction in patients after plasma exchange.

Contribution of single motoneurons to renshaw cell activity

Single spinal alpha motoneurons driven by injected current are shown to increase the activity of Renshaw cells. This fact is a necessary condition for the validity of hypotheses concerning the functional significance of recurrent inhibition which are based on the conception that individual motoneurons can interact with each other.

Quantitative relation between discharge frequencies of a Renshaw cell and an intracellularly depolarized motoneuron

We present the input-output frequency characteristics of a Renshaw cell which could be driven at various frequencies by the discharges of a motoneuron depolarized by intracellular current injection. Renshaw cell frequency was proportional to motoneuron discharge rate up to about 20 Hz.

Cardiac stunning in the clinic: the full picture

Cardiac stunning refers to different dysfunctional levels occurring after an episode of acute ischemia, despite blood flow is near normal or normal. The phenomenon was initially identified in animal models, where it has been very well characterized. After being established in the experimental setting, it remained unclear, whether a similar syndrome occurs in humans. In addition, it remained controversial, whether stunning was of any clinical relevance as it is spontaneously reversible. Hence, many studies continue to focus on the properties and mechanisms of stunning, although therapies seem more relevant for attenuating and treating myocardial ischemia/reperfusion (I/R) injury, i.e. to bridge until recovery. This article reviews the different facets of cardiac stunning, i.e. myocardial, vascular/microvascular/endothelial, metabolic, neural/neuronal, and electrical stunning. This review also displays where these facets exist and which clinical relevance they might have. Particular attention is directed to the different therapeutic interventions that the various facets of this I/R-induced cardiac injury might require. A final outlook considers possible alternatives to further reduce the detrimental consequences of brief episodes of ischemia and reperfusion.

Diving reflex: can the time course of heart rate reduction be quantified?

In this meta‐analysis of diving bradycardia in humans, we sought to quantify any heart rate (HR) reduction using a relatively simple mathematical function. Using the terms “diving reflex,”“diving bradycardia,”“diving response,”“diving plus heart rate,” databases were searched. Data from the studies were fitted using HR=c+aexp(−(t−t0)/τ), where c is the final HR, a is the HR decrease, τ is the time constant of HR decay, and t0 is the time delay. Of 890 studies, 220 were given closer scrutiny. Only eight of these provided data obtained under comparable conditions. Apneic facial immersion decreased HR with τ=10.4 s and in air alone it was less pronounced and slower (τ=16.2 s). The exponential function fitted the time course of HR decrease closely (r2>0.93). The fit was less adequate for apneic‐exercising volunteers. During apnea both with and without face immersion, HR decreases along a monoexponential function with a characteristic time constant. HR decrease during exercise with and without face immersion could not readily be described with a simple function: the parasympathetic reaction was partially offset by some sympathetic activity. Thus, we succeeded in quantifying the early time course of diving bradycardia. It is concluded that the diving reflex is useful to diagnose the integrity of efferent cardiovascular autonomic pathways.

Computer-assisted paranasal sinus operation induces diving bradycardia.

Unintentional mechanical manipulation anywhere in the distribution of the trigeminal nerve might activate a reflexive bradycardia. Neurosurgeons need to bear in mind detrimental consequences on cardiac function. A female patient (53 years) underwent a computer-assisted (CAS), paranasal sinus operation performed under general anesthesia. During left sided CAS and preparation of the sinus ethmoidalis, heart rate significantly fell from 68 to 32 /min, while systolic arterial blood pressure decreased from 105 to 75 mmHg. Continuation of the preparation again decreased heart rate progressing to transient asystole lasting for 15 s. After removal of the instruments, asystole terminated without medical support. As heart rate decreased after renewed insertion of the CAS probe, sinus ethmoidalis surgery was completed after atropine administration. During neurosurgical procedures, the incidence of the reflex varies between 10 and 18%. To the best of our knowledge, we report for the first time on a direct stimulation of the ethmoidal nerve with instruments (CAS probe) during paranasal surgery. Although normally cardioprotective, exaggeration of the diving reflex can be detrimental and has been implicated in cardiorespiratory disorders, including sudden death and the sudden infant death syndrome.

Effects of oxygen-enriched air on cognitive performance during SCUBA-diving – an open-water study

ABSTRACT Backround: Nitrogen narcosis impairs cognitive function, a fact relevant during SCUBA-diving. Oxygen-enriched air (nitrox) became popular in recreational diving, while evidence of its advantages over air is limited. Aim: Compare effects of nitrox28 and air on two psychometric tests. Methods: In this prospective, double-blind, open-water study, 108 advanced divers (38 females) were randomized to an air or a nitrox-group for a 60-min dive to 24 m salt water. Breathing gas effects on cognitive performance were assessed during the dive using a short- and long-term memory test and a number connection test. Results: Nitrox28 divers made fewer mistakes only on the long-term memory test (p = 0.038). Female divers remembered more items than male divers (p < 0.001). There were no significant differences in the number connection test between the groups. Conclusion: Likely owing to the comparatively low N2 reduction and the conservative dive, beneficial nitrox28 effects to diver performance were moderate but could contribute to diving safety.

Correlation between heterogeneous myocardial flow and oxidative metabolism in normoxic and stunned myocardium

Abstract Myocardial blood flow exhibits considerable heterogeneity. Consequently, oxygen supply to the myocardium is also heterogeneous, as is myocardial metabolism. Many lines of evidence show a close correlation between local flow and local metabolism in the normoxic myocardium. So far, myocardial metabolism has pre-dominantly been assessed indirectly by using labeled substrates. We used the 18O isotope, permitting analytical separation of H218O from the 18O isotope, as well as quantification of regional oxidative metabolism by measuring the tissue residue of oxidation water in the rabbit myocardium. Correlation of local flow with oxidative metabolism was significant in the normoxic myocardium. This correlation was lost in the postischemic/reperfused myocardium. Apart from the established mechanisms underlying myocardial stunning, a mismatch between local flow and oxidative metabolism might thus also contribute to the postischemic dysfunction.In the normoxic myocardium, function should correlate with metabolism and blood flow. For technical reasons, function has not been assessed on a very local scale. Nevertheless, some considerations are presented on the heterogeneity of function as well as on the scale on which heterogeneity should be investigated to convey physiologically meaningful information on regulatory cardiac mechanisms.

Sphenoid sinus barotrauma in diving: case series and review of the literature

ABSTRACT About 50% of scuba divers have suffered from barotrauma of the ears and about one-third from barotrauma of paranasal sinuses. The sphenoid sinuses are rarely involved. Vital structures, as internal carotid artery and optic nerve, adjoin the sphenoid sinus. Thus, barotrauma could lead to serious neurologic disorders, including blindness. After searching the literature (Medline) and other sources (Internet), we present some cases of sphenoid sinus barotrauma, because these injuries may be underreported and misdiagnosed due to the lack of awareness and knowledge. Therefore, information is provided, e.g. on anatomical and pathophysiological features. Divers and physicians should have in mind that occasional headache during or after diving sometimes signals serious neurological disorders like vision loss. We show that injuries can develop from both negative and positive pressures in the sinuses. Because visual recovery depends on prompt diagnosis and proper therapy, physicians like otolaryngologists, ophthalmologists and neurologists need to closely collaborate.

Dynamic properties of Renshaw cells: Responses to sinusoidal variation of input frequency

Abstract Sinusoidally modulated trains of impulses (frequency modulation) were applied to cut ventral roots of intercollicular decerebrate cats in order to determine the frequency response of Renshaw cells. On the average, the gain of the interneurons rose slowly with increasing modulation frequency (about 5 dB/decade), while the phase lag became greater. Gain was proportional to generator modulation depth. Negative feedback by way of Renshaw cells with the characteristics revealed by our experiments would explain the comparative lack of rate sensitivity in spinal alpha motoneurons.