Comparative aspects on nitric oxide in brain and its role as a cerebral vasodilator

Histological studies have detected nitric oxide (NO) synthase in the central nervous system of all vertebrates examined, from lampreys to mammals. However, there are still very few comparative physiological studies on the function of NO synthase in the brain of non-mammalian vertebrates. So far, we know that acetylcholine can cause an NO-dependent increase in brain blood flow in turtles and some fish species (crucian carp and rainbow trout), whereas some other fishes appear to lack such a mechanism. Hypercapnia can induce NO-dependent cerebral vasodilation in mammals, but such a mechanism appears to be lacking in the ectothermic vertebrates examined. The number of species studied needs to be expanded before we can draw any firm conclusions about the origin of NO-dependent brain blood flow regulation: if it has evolved more than once or if it has been occasionally lost during evolution. We conclude that NO synthase may be present in all vertebrate brains but that its functions can vary, as judged from its role in cerebral blood flow regulation. The diversity of functions that NO has proven to have within the mammalian brain is likely to be paralleled by the same degree of diversity of function between vertebrate groups.

Anoxic depression of light-evoked potentials in retina and optic tectum of crucian carp

The crucian carp is an exceptionally anoxia-tolerant vertebrate. For the brain, with its very high rate of ATP use, depression of energy use is likely to be an important strategy for anoxic survival. This study shows that the light-evoked response of the retina and the corresponding evoked potential in optic tectum decrease in amplitude by 69 and 75%, respectively, during 38 min of anoxia, and by about 90% after 1 h in anoxia. Both responses were restored upon reoxygenation. The length of light exposure (5 s or 100 ms) did not affect the degree of anoxic depression. These results are the first to show an anoxia-induced depression of central nervous system (CNS) activity in vivo in this species, and indicate that the crucian carp temporarily turns off its visual sense in order to reduce neural energy use during anoxic condition.

Brain Na+/K+-ATPase activity in two anoxia tolerant vertebrates: crucian carp and freshwater turtle

The crucian carp (Carassius carassius) and freshwater turtles (Trachemys scripta) are among the very few vertebrates that can survive extended periods of anoxia. The major problem for an anoxic brain is energy deficiency. In the brain, the Na+/K+-ATPase is the single most ATP consuming enzyme, being responsible for maintaining ion gradients. We here show that the Na+/K+-ATPase activity in the turtle brain is reduced by 31% in telencephalon and by 34% in cerebellum after 24 h of anoxia. Both changes were reversed upon reoxygenation. By contrast, the Na+/K+-ATPase activities were maintained in the anoxic crucian carp brain. These results support the notion that crucian carp and turtles use divergent strategies for anoxic survival. The fall in Na+/K+-ATPase activities displayed by the turtle is likely to be related to the strong depression of brain electric and metabolic activity utilized as an anoxic survival strategy by this species.

Serotonin as a regulator of hypothalamic-pituitary-interrenal activity in teleost fish

Evidence for the presence of a serotonin1A (5-HT1A) receptor subtype in the salmonid fish brain has recently been presented. In the present study the potent 5-HT1A receptor agonist, 8-hydroxy-2-(di-n-propylamino)-tetralin (8-OH-DPAT) was tested for its effect on plasma cortisol concentrations in rainbow trout (Oncorhynchus mykiss). Blood was sampled and 8-OH-DPAT administered through a catheter in the dorsal aorta. Thirty minutes after the injection of 40 microg of 8-OH-DPAT/kg, plasma cortisol levels had increased from 12 to 149 ng/ml, whereupon they fell, reaching baseline levels after 4 h. The effect of 1-40 microg 8-OH-DPAT/kg on plasma cortisol concentrations was dose-dependent. The results lends further support to the hypothesis that the brain serotonergic system plays a key role in integrating autonomic, behavioral and neuroendocrine stress-responses in fish as well as mammals, suggesting that not only the structural and biochemical organization, but also the function of the serotonergic system has been conserved during vertebrate evolution.

Effects of L-thyroxine on brain monoamines during parr-smolt transformation of Atlantic salmon (Salmo salar L.)

During spring, seaward migrating juvenile Atlantic salmon (Salmo salar) undergo parr-smolt transformation (PST) which involves changes in physiology, including one or two peaks in plasma thyroxine (T4). To investigate if changes in plasma T4 influence neural function, we measured levels of dopamine (DA) and its metabolites, 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA), and also measured serotonin (5-hydroxytryptamine, 5-HT) and its metabolite, 5-hydroxyindoleacetic acid (5-HIAA) in brain regions of two groups of Atlantic salmon parr on an 8:16 h light/dark photoperiod. One group was treated with ambient T4 to simulate the natural smolt peak in plasma T4. T4 treatment depressed DOPAC levels as well as DOPAC/DA and 5-HIAA/5-HT ratios in the olfactory system but with no changes in the optic tectum. We conclude that during PST monoaminergic functions in specific brain regions of juvenile Atlantic salmon are affected by T4 treatment.

Neurochemical mechanisms behind gill microcirculatory responses to hypoxia in trout: in vivo microscopy study

In vivo microscopy combined with systemic blood flow and pressure measurements were used to examine the hemodynamic and microcirculatory responses to hypoxia in gills of rainbow trout and to clarify if the underlying mechanisms are adrenergic, cholinergic, serotonergic, or adenosinergic. Hypoxia (P(O2) 1.07-1.33 kPa) reduced, halted, or reversed the blood flow in the distal portion of the efferent filamental artery (EFA). Simultaneously, a large overflow to the central venous system appeared, allowing a continuous flow through many of the secondary lamellae. No vasoconstriction could be observed in this portion of the filament, showing that a vasoconstriction occurred elsewhere, possibly at the EFA sphincter, because the gill resistance (R(G)) increased. These effects were mimicked by prebranchial injection of acetylcholine, a treatment that also strongly constricted the distal efferent filamental vasculature. Atropine blocked most of the hypoxia-induced hemodynamic changes, although a minor increase in R(G) remained. The latter appeared to be of a nonadrenergic noncholinergic origin, being unaffected by additional treatment with an alpha-adrenoreceptor antagonist. It was also unaffected by blockers of serotonin and adenosine-A1 receptors. Other responses seen included a cholinergic maintenance of the systemic resistance during hypoxia and an alpha-adrenoceptor-mediated posthypoxic hypertension. This study demonstrates that hypoxia evoked a cholinergic reflex vasoconstriction located at proximal parts of the efferent filamental vasculature.

Effects of inhibition of nitric oxide synthesis and of hypercapnia on blood pressure and brain blood flow in the turtle

In the mammalian brain, nitric oxide (NO) is responsible for a vasodilatory tonus as well as the elevation of cerebral blood flow (CBF) induced by hypercapnia. There have been few comparative studies of cerebral vasoregulation in lower vertebrates. Using epi-illumination microscopy in vivo to observe CBF velocity on the brain surface (cerebral cortex), we show that turtles (Trachemys scripta) exposed to hypercapnia (inspired PCO2 = 4.9 kPa) displayed a 62% increase in CBF velocity, while systemic blood pressure remains constant. Exposing turtles to a PCO2 of 14.9 kPa caused an additional increase in CBF velocity, to 104% above control values, as well as a 30% increase in systemic blood pressure. The elevated CBF velocity during hypercapnia could not be blocked by a systemic injection of the NO synthase (NOS) inhibitor NG-nitro-L-arginine (L-NA). However, L-NA injection caused a temporary stop in CBF as well as a persistent increase in systemic blood pressure, suggesting that there is a NO tonus that is attenuated by the NOS inhibitor and that CBF is strongly dependent on this tonus, although compensatory mechanisms exist. Thus, although the cerebrovascular reaction to hypercapnia appeared to be NO-independent, the results suggest that there is a NO-dependent vasodilatory tonus affecting both cerebral and systemic blood circulation in this species.

Superficial blood flow following photodynamic therapy of malignant non-melanoma skin tumours measured by laser Doppler perfusion imaging

Laser Doppler perfusion imaging offers a new modality for in vivo monitoring of the superficial blood perfusion in biological tissue. In this study, the superficial blood perfusion of malignant non-melanoma skin tumours and the surrounding normal skin was measured in conjunction with photodynamic therapy (PDT) using topical delta-aminolaevulinic acid (ALA)-induced protoporphyrin IX as a photosensitizer. The results clearly show that, in contradiction to PDT with the intravenously administered photosensitizer Photofrin, no direct vascular damage can be seen. With the topical sensitization the blood perfusion is increased immediately after the treatment irradiation. The increased blood flow is seen up to a week after treatment, in a similar way as for an inflammatory reaction. Despite this, all basal cell carcinoma and squamous cell carcinoma in situ lesions in this study healed without any sign of residual tumour after the treatment, suggesting an efficient direct tumour cell destruction induced by PDT.

Contrasting strategies for anoxic brain survival--glycolysis up or down

Anoxia-tolerant turtles and carp (Carassius) exhibit contrasting strategies for anoxic brain survival. In the turtle brain, the energy consumption is deeply depressed to the extent of producing a comatose-like state. Brain metabolic depression is brought about by activating channel arrest to reduce ion flux and through the release of inhibitory gamma-aminobutyric acid (GABA) and the upregulation of GABAA receptors. Key glycolytic enzymes are down-regulated during prolonged anoxia. The result is a suppression of neurotransmission and a substantial depression in brain electrical activity. By contrast, Carassius remain active during anoxia, though at a reduced level. As in the turtle, there is an adenosine-mediated increase in brain blood flow but, in contrast to the turtle, this increase is sustained throughout the anoxic period. Key glycolytic enzymes are up-regulated and anaerobic glycolysis is enhanced. There is no evidence of channel arrest in Carassius brain. The probable result is that electrical activity in the brain is not suppressed but instead maintained at a level sufficient to regulate and control the locomotory and sensory activities of the anoxic carp. The key adaptations permitting the continued high level of glycolysis in Carassius are the production and excretion of ethanol as the glycolytic end-product, which avoids self-pollution by lactate produced during glycolysis that occurs in other vertebrates.

A role for adenosine in metabolic depression in the marine invertebrate Sipunculus nudus

Involvement of neurotransmitters in metabolic depression under hypoxia and hypercapnia was examined in Sipunculus nudus. Concentration changes of several putative neurotransmitters in nervous tissue during anoxic or hypercapnic exposure or during combined anoxia and hypercapnia were determined. Among amino acids (gamma-aminobutyric acid, glutamate, glycine, taurine, serine, and aspartate) and monoamines (serotonin, dopamine, and norepinephrine), some changes were significant, but none were consistent with metabolic depression under all experimental conditions applied. Only the neuromodulator adenosine displayed concentration changes in accordance with metabolic depression under all experimental conditions. Levels increased during anoxia, during hypercapnia, and to an even greater extent during anoxic hypercapnia. Adenosine infusions into coelomic fluid via an indwelling catheter induced a significant depression of the normocapnic rate of O2 consumption from 0.36 +/- 0.04 to a minimum of 0.24 +/- 0.02 (SE) mumol.g-1.h-1 after 90 min (n = 6). Application of the adenosine antagonist theophylline caused a transient rise in O2 consumption 30 min after infusion during hypercapnia but not during normocapnia. Effects of adenosine and theophylline were observed in intact individuals but not in isolated body wall musculature. The results provide evidence for a role of adenosine in inducing metabolic depression in S. nudus, probably through the established effects of decreasing neuronal excitability and neurotransmitter release. In consideration of our previous finding that metabolic depression in isolated body wall musculature was elicited by extracellular acidosis, it is concluded that central and cellular mechanisms combine to contribute to the overall reduction in metabolic rate in S. nudus.

Tissue-specific changes in protein synthesis rates in vivo during anoxia in crucian carp

Mechanisms of anoxia tolerance were investigated in crucian carp. Rates of protein synthesis were calculated in selected tissues of normoxic and anoxic animals. Exposure to 48 h of anoxia resulted in a significant reduction in protein synthesis in the liver (> 95%), heart (53%), and red and white muscle (52 and 56%, respectively), whereas brain protein synthesis rates were unaffected. Seven days of anoxia produced similar results. After 24 h of recovery from a 48-h anoxic period, protein synthesis rates had virtually returned to normoxic values. The effect of anoxia on the amount of RNA (relative to protein) varied depending on the tissue and also the length of exposure (except in the brain, where it was consistently reduced). However, the effect on RNA translational efficiency was purely tissue specific (i.e., independent of exposure time) and was unaffected in the heart, reduced in the liver and red and white muscle, and increased in the brain. Downregulation of protein synthesis on a tissue-specific basis appears to be a significant mechanism for energy conservation as well as maintaining neural function, thus promoting survival during anoxia.

Laser Doppler perfusion imaging of eyelid skin

We report an initial laser Doppler perfusion study of the eyelids and compare the results with those of other cutaneous regions. Eleven healthy subjects with no prior medical or surgical history, or eyelid malposition underwent laser Doppler perfusion scanning of six skin locations: right forearm, right middle fingertip, right upper eyelid, right lower eyelid, left upper eyelid, and left lower eyelid. Cutaneous perfusion in the four eyelid locations and right middle fingertip were statistically similar to each other but significantly higher than that in the right forearm (p = 0.002). Also, mean perfusion in pretarsal skin was > 50% than that in preseptal skin (p = 0.002). In addition, in an eyelid with histopathologically documented basal cell carcinoma, cutaneous perfusion was significantly higher than the mean of the normal eyelids (p = 0.002). Eyelids are perfused at the same high rate as are other regions of the head, and significantly higher than low flow regions, such as the extremities. Future application of this laser Doppler perfusion scanning include assessing burn depth, postoperative monitoring of periorbital tissue transfer, distinguishing benign and malignant adnexal skin lesions, and establishing the pathologic margins of lid tumors.

Duplex laser Doppler perfusion imaging

A duplex mode for recoding of both spatial and temporal blood perfusion components has been developed and evaluated. This modality, which has been implemented as a software module in the laser Doppler perfusion imager, consists of various local area scan (LAS) configurations. These include single-point recording or multipoint recording after repeated movements of the laser beam in quadratic patterns including 2 x 2 or 4 x 4 measurement sites. For the 2 x 2 and 4 x 4 LAS, the output value constitutes the average perfusion of all values captured within the actual region of interest. The 2 x 2 local area scan is corrected by time shifting the sequentially recorded measurement values at consecutive tissue sites, while the 4 x 4 LAS is presented as a vector of the individual subimages. With the standard setting of 65 msec for the signal integration time at each measurement site, the 1 x 1 and 2 x 2 LAS configurations can capture and reproduce perfusion signals with maximal bandwidths of 7.7 and 1.9 Hz, respectively. System evaluation showed that the signal integration time can be reduced to 45 msec without impaired signal quality, thereby further increasing the system bandwidth with a factor of about 1.5. Skin recordings showed that averaged time traces of adjacent measurement sites improve the signal-to-noise ration and allow for a more reliable analysis of, for example, the reactive hyperemic response. Individual time-trace extraction, however, showed reperfusion patterns that differed markedly between sites.

Branchial and systemic roles of adenosine receptors in rainbow trout: an in vivo microscopy study

The purinergic branchial vasomotor control in rainbow trout (Oncorhynchus mykiss) was studied using an epi-illumination microscope equipped with a water-immersion objective. Cardiac output (Q), heart rate, and dorsal (PDA) and ventral (PVA) aortic pressures were recorded simultaneously. Prebranchial injection of adenosine or the A1-receptor agonist N6-cyclopentyl-adenosine (CPA) constricted the distal portion of the filament vasculature, which coincided with an increase of PVA. The A2-receptor agonist PD-125944 was without effect. After adenosine and CPA injection, an overflow of blood to the secondary system was repeatedly observed unless blood flow came to a complete stop. The lack of a concomitant reduction of Q suggested a redistribution of blood to the secondary system and to more proximal parts of the filament. The branchial effects of adenosine and CPA were completely blocked by the unspecific adenosine receptor antagonist amino-phylline and the specific A1-receptor antagonist N6-cyclopen-tyltheophylline. The results suggest that A1-receptors alone mediate the branchial vasoconstriction observed. Thus the responses of the branchial vasculature to adenosine include a vasoconstriction of the filament vasculature mediated via specific A1 receptors and a redistribution of blood flow to the secondary system and to proximal parts of the filament. Additional cardiovascular effects of adenosine included decreased systemic vascular resistance and heart rate.

Role of nitric oxide in the elevation of cerebral blood flow induced by acetylcholine and anoxia in the turtle

Nitric oxide (NO)-dependent regulation of brain blood flow has hitherto not been studied in reptiles. By observing the brain surface (telencephalon) of the freshwater turtle (Trachemys scripta) with epiillumination microscopy, we show that topical application of acetylcholine (ACh) induces an increase in CBF velocity that can be completely blocked by the NO synthase inhibitor N(G)-nitro-L-arginine methyl ester (L-NAME). The effect of L-NAME was reversed by L-arginine. Also, sodium nitroprusside (SNP), which decomposes to liberate NO, caused an increase in CBF velocity. By contrast, L-NAME could not block the increase in blood flow velocity caused by anoxia. Interestingly, superfusing the brain with ACh or SNP during anoxia had no effect on the blood flow velocity. The results suggest that NO is an endogenous vasodilator in the turtle brain, mediating the effects of ACh during normoxia. By contrast, anoxia does not rely on NO as a vasodilator.

Agonistic interactions affect brain serotonergic activity in an acanthopterygiian fish: the bicolor damselfish (Pomacentrus partitus)

Bicolor damselfish were allowed to interact in pairs for 15 min a day during a five-day period. Agonistic behaviour was quantified, and at the end of the experimental series, concentrations of serotonin (5-HT), 5-hydroxyindoleacetic acid (5-HIAA) and tryptophan (TRP, the amino acid precursor of 5-HT) were measured, and 5-HIAA/5-HT ratios (an index of 5-HT activity) were calculated in the telencephalon, hypothalamus and brain stem. Socially interacting fish, dominant as well as subordinate, showed higher telencephalic 5-HIAA/5-HT ratios than isolated controls. Social interaction also decreased telencephalic TRP concentrations in subordinate fish but did not affect 5-HT concentrations in any of the brain parts. In subordinate fish, 5-HIAA/5-HT ratios in the telencephalon were positively correlated with the number of aggressive acts received. Moreover, in dominant fish 5-HIAA/5-HT ratios in the hypothalamus were positively correlated with the number of aggressive acts performed. These results indicate that the brain serotonergic system is involved in intraspecific aggression and/or stress reactions in bicolor damselfish.

Anoxia tolerant animals from a neurobiological perspective

This paper discusses the mechanisms for brain anoxia survival seen in crucian carp (Carassius carassius) and a few species of freshwater turtle (Chrysemys and Trachemys species). Comparisons are made with the hypoxic tolerant mammalian neonate brain. In the anoxic tolerant species the basic strategy for anoxia survival appears to be the maintenance of ion gradients, and thereby the avoidance of anoxic depolarization. Important facilitating factors involve having huge glycogen stores, increased blood supply to the brain, the suppression of electrical activity, increased release of inhibitory neuromodulators and neurotransmitters, upregulation of inhibitory neuroreceptors, the down-regulation of excitatory ion conductance and the down-regulation of Ca2+ channels. By contrast, for the mammalian neonate the most important causes of its increased hypoxia tolerance may be just simple consequences of the comparatively undifferentiated state of the brain of the newborn, with its lower energy requirements, slower decline in ATP and lower excitability levels acting to delay depolarization.

Anoxic brain failure in an ectothermic vertebrate: release of amino acids and K+ in rainbow trout thalamus

The release of excitatory amino acids such as glutamate contributes greatly to anoxic and/or ischemic brain damage in mammals. However, for anoxia-intolerant ectothermic vertebrates, there has been no information on how anoxia affects extracellular amino acid levels, or how such changes relate temporally to major ion movements. We have investigated the effects of environmental anoxia on extracellular amino acid and K+ concentrations in rainbow trout thalamus in vivo at 15 degrees C, using microdialysis and K(+)-selective microelectrodes. Systemic blood pressure was also monitored. In separate experiments, endogenous neurotransmitter release was provoked by perfusing the microdialysis probe with a high-K+ Ringer solution, thereby establishing which amino acids are released by depolarization. Anoxia exposure resulted in the release of several amino acids, including glutamate, aspartate, gamma-aminobutyric acid (GABA), glycine, and taurine. GABA release appeared to be delayed compared with that of glutamate, for example. The loss of ion homeostasis (starting after 23 min) preceded the release of amino acids (starting after > or = 45 min). The amino acid release had no apparent effect on the rate of increase in extracellular K+. Thus, if these events are interrelated, the loss of ion homeostasis is likely to trigger the amino acid release but not vice versa.

Nitric oxide synthase inhibitor blocks acetylcholine induced increase in brain blood flow in rainbow trout

Nitric oxide (NO) dependent regulation of blood flow has hitherto not been demonstrated in rainbow trout or other salmonid fish. Through in vivo observations of the brain surface (optic lobes) of rainbow trout (Oncorhynchus mykiss) with epi-illumination microscopy, we show that application of acetylcholine (ACh) to the brain surface induces an increase in cerebral blood flow velocity that can be completely blocked by the NO synthase inhibitor NG-nitro-L-arginine. Also sodium nitroprusside, which decomposes to form NO, stimulated cerebral blood flow velocity. The results indicate that NO is a vasodilator in rainbow trout brain, mediating the effect of ACh.

Control of gill filament blood flow by serotonin in the rainbow trout, Oncorhynchus mykiss

The effects of exogenously applied serotonin [5-hydroxytryptamine (5-HT)] on the distal arterial vasculature of gill filaments were observed using an epi-illumination microscope equipped with a water-immersion objective and connected to a video camera. In addition, ventral aortic flow (Q) and celiac artery pressure (PCA) were measured. Intra-arterial injection of serotonin (100 nmol/kg) completely stopped the blood flow in the distal part of the filaments and caused a rapid decrease of PCA. Repeatedly, the flow reduction was found to coincide with a constriction of the distal portion of the efferent filamental vasculature. Because there was no concomitant reduction in Q, it is concluded that a redistribution of blood to more proximal parts of the filaments occurred. After treatment with the serotonergic receptor antagonist methysergide, the vasoconstrictor effect of serotonin on the filamental vasculature was eliminated, while a decrease in PCA was still observed. The results demonstrate a specific site(s) for the serotonergic vasoconstriction in the distal portion of the filament.

Evidence that acetylcholine mediates increased cerebral blood flow velocity in crucian carp through a nitric oxide-dependent mechanism

Nitric oxide (NO)-dependent regulation of brain blood flow has not been proved to exist in fish or other ectothermic vertebrates. Using epi-illumination microscopy on the brain surface (optic lobes) of crucian carp (Carassius carassius), we show that superfusing the brain with acetylcholine (ACh) induces an increase in cerebral blood flow velocity that can be completely blocked by the NO synthase inhibitors NG-nitro-L-arginine methylester (L-NAME) and NG-nitro-L-arginine. Also, sodium nitroprusside, which decomposes to liberate NO, causes an increase in cerebral blood flow velocity. By contrast, L-NAME does not block the increase in blood flow velocity caused by anoxia. The results suggest that NO is an endogenous vasodilator in crucian carp brain that mediates the effects of ACh. Because teleost fish deviated from other vertebrates 400 million years ago, these results suggest that NO-dependent brain blood flow regulation was an early event in vertebrate evolution.

Time course of anoxia-induced increase in cerebral blood flow rate in turtles: evidence for a role of adenosine

The exceptional ability of the turtle brain to survive prolonged anoxia makes it a unique model for studying anoxic survival mechanisms. We have used epi-illumination microscopy to record blood flow rate in venules on the cortical surface of turtles (Trachemys scripta). During anoxia, blood flow rate increased 1.7 times after 45-75 min, whereupon it fell back, reaching preanoxic values after 115 min of anoxia. Topical superfusion with adenosine (50 microM) during normoxia caused a 3.8-fold increase in flow rate. Superfusing the brain with the adenosine receptor blocker aminophylline (250 microM) totally inhibited the effects of both adenosine and anoxia, while aminophylline had no effect on normoxic flow rate. None of the treatments affected systemic blood pressure. These results indicate an initial adenosine-mediated increase in cerebral blood flow rate during anoxia, probably representing an emergency response before deep metabolic depression sets in.

Anoxia and adenosine induce increased cerebral blood flow rate in crucian carp

The crucian carp (Carassius carassius) has the rare ability to survive prolonged anoxia, indicating an extraordinary capacity for glycolytic ATP production, especially in a highly energy-consuming organ like the brain. For the brain to be able to increase its glycolytic flux during anoxia and profit from the large liver glycogen store, an increased glucose delivery from the blood would be expected. Nevertheless, the effect of anoxia on brain blood flow in crucian carp has never been studied previously. We have used epireflection microscopy to directly observe and measure blood flow rate on the brain surface (optic lobes) during normoxia and anoxia in crucian carp. We have also examined the possibility that adenosine participates in the regulation of brain blood flow rate in crucian carp. The results showed a 2.16-fold increase in brain blood flow rate during anoxia. A similar increase was seen after topical application of adenosine during normoxia, while adenosine was without effect during anoxia. Moreover, superfusing the brain with the adenosine receptor blocker aminophylline inhibited the effect of anoxia on brain blood flow rate, clearly suggesting a mediatory role of adenosine in the anoxia-induced increase in brain blood flow rate.

Spatial heterogeneity in normal skin perfusion recorded with laser Doppler imaging and flowmetry

Spatial and temporal variations in forearm skin perfusion captured by laser Doppler perfusion imaging (LDI) have been compared with topographic maps recorded by laser Doppler flowmetry. In order to determine the shortest LDI sampling time required at each measurement site, with an adequate signal-to-noise ratio and with the ability to display the heterogeneity in skin perfusion, the noise-limited resolution of the LDI system as well as various sampling times were tested. The noise-limited resolution for medium and high light intensities were less than 0.5% (temporal) and 0.3% (spatial) of full scale. A sampling time of 1 sec was selected and image presentation was made by performing bilinear interpolation between perfusion values. The same area (10 x 10 mm) was mapped with LDI and topographic mapping at seven different sites. In addition, a larger area covering the surrounding skin was recorded with LDI. The small area recordings with LDI and topographic mapping could be identified in the larger LDI image. High-and low-perfusion spots coincided between the two systems. Temporal variations were studied by repeated LDI recordings of the same areas as above. Small spots were selected in the areas and plotted versus time. Without provocation, the total perfusion changes at each spot showed large variations, but the relative perfusion levels between neighboring spots persisted. Provocation with heat increased the perfusion in all spots.