Proteins in cerebrospinal fluid and plasma of the pouch young tammar wallaby (Macropus eugenii) during development

The concentrations of total protein and albumin in cerebrospinal fluid (CSF) and plasma of tammar wallaby pouch young (Macropus eugenii) from birth until leaving the pouch have been measured. Total protein in CSF increased from birth (about 240 mg/100 ml) to 15-20 days postnatal (about 400 mg/100 ml) after which it declined. Albumin showed a proportionately greater increase from around 40 mg/100 ml to over 130 mg/100 ml, followed by decline after 75 days. Total protein and albumin in plasma increased throughout the period studied. Other proteins identified in CSF and plasma were: fetuin, alpha 2-macroglobulin, transferrin, alpha-lipoprotein, beta-lipoprotein, immunoglobin G and fibrinogen. One protein was only present in early pouch young (up to about 40 days) and was presumed to be the tammar equivalent of alpha-fetoprotein.     

Transferrin in fetal sheep cerebrospinal fluid and plasma during gestation

1. Transferrin concentrations in fetal sheep CSF and plasma have been estimated between 31 and 125 days gestation and in the adult, using a radial immunodiffusion assay. 2. The plasma concentration was lowest (183 +/- 35 mg/100 ml) in the earliest fetuses examined (31 days). It increased to over 350 mg/100 ml by 35 days; thereafter it was around the adult value (580 mg/100 ml). 3. In CSF the transferrin concentration increased from 43 +/- 10 mg/100 ml at 31 days to a maximum of 163 +/- 14 mg/100 ml at 40 days gestation after which it decreased considerably to 6.1 +/- 0.7 mg/100 ml at 125 days and was even lower in the adult (1.1 +/- 0.2 mg/100 ml). 4. CSF: plasma ratios for transferrin especially when compared with those of other plasma proteins, are not compatible with passive leakage of protein from blood to CSF in the developing brain. The results may be explained by specific transfer of proteins into CSF but synthesis by the choroid plexus or brain has not been excluded.     

Development of cerebrospinal fluid and the blood-cerebrospinal fluid barrier in rabbits.

Blood plasma and cerebrospinal fluid (CSF) samples were collected from adult female rabbits (New Zealand White), newborn, and embryos at 18, 20, 24, and 28 days of gestation. Samples were analyzed for total protein using the Folin phenol reagent. During development, mean total protein of blood plasma rose sharply from 12.45 to 12.51 mg/ml at 18 to 20 days to 37.56 mg/ml at 28 days. Levels further increased to 54.06 mg/ml in the newborn and to 66.18 mg/ml in the adult. The protein concentration of cerebrospinal fluid was constant at 5.20 to 5.29 mg/ml between 18 and 20 days of gestation, but steadily decreased to 3.53 mg/ml at 28 days. By birth, the CSF protein concentration was further reduced to 2.08 mg/ml, and this level differed only slightly (P < 0.05) from CSF protein values determined for adults. These data indicate that the blood-cerebrospinal fluid barrier to proteins begins to function by 18 to 20 days of gestation, and the protein concentration of cerebrospinal fluid approaches the normal adult value soon after birth.     

Concentrations of Amino Acids in Extracellular Fluid After Opening of the Blood-Brain Barrier by Intracarotid Infusion of Protamine Sulfate

Abstract: This article evaluates the influence of an opening of the blood-brain barrier (BBB) on compounds in brain extracellular fluid. The concentrations of amino acids and some other primary amines were determined in dialysates sampled from the right parietal cortex of rats before and after an intracarotid infusion of protamine sulfate. Extravasated plasma proteins were visualized by Evans blue/albumin and immunohistochemistry. CSF albumin— an indicator of blood-CSF barrier opening—was quantified with immunoelectrophoresis. The brains were macroscopically edematous after 10 mg but not after 5 mg of protamine sulfate. The higher dose led to a 50% death rate. The concentrations of amino acids did not change 10 min after the BBB opening. No significant alterations in the amino acid concentrations were observed after the lower dose. The concentrations of glutamate, aspartate, GABA, glycine, taurine, and phosphoethanolamine increased significantly within 50–80 min after the infusion of 10 mg of protamine sulfate. CSF albumin levels were significantly increased 1 h after infusion. We conclude that a dysfunction of the BBB, of a degree known to induce brain edema (10 mg of protamine sulfate), significantly increases the extracellular concentration of excitatory amino acids, GABA, taurine, and phosphoethanolamine in the extracellular space.     

Elevation of Taurine in Hippocampal Extracellular Fluid and Cerebrospinal Fluid of Acutely Hypoosmotic Rats: Contribution by Influx from Blood?

Previous work has demonstrated that there is a selective increase in extracellular taurine in the brain during acute water intoxication. One aim of the present study was to investigate whether plasma taurine contributes to this increase. To this end, the concentrations of taurine, other amino acids, and ethanolamine (EA) were measured in plasma and CSF of urethane-anesthetized rats injected with 150 ml/kg body weight of distilled water. Blood pressure, blood gases, and pH, as well as plasma and CSF osmolality, were also measured. The CSF level of albumin was quantitated to study the function of the blood-CSF barrier. In separate experiments, hippocampal microdialysis was performed to determine the effects of acute plasma hypoosmolality on extracellular amino acids. Finally, the effect of water injection on hippocampal specific gravity and tissue amino acids was assessed. Blood gases and pH were essentially unchanged after water administration. Mean arterial blood pressure increased to peak levels approximately 50 mm Hg above control. Plasma osmolality decreased rapidly, whereas the depression of CSF osmolality was slower and less pronounced. The average volume of the hippocampus increased by 8%. Water injection was accompanied by a 25-fold elevation of taurine in plasma, whereas phosphoethanolamine (PEA) and EA increased moderately. A small fraction of the increase in plasma taurine might derive from blood cells because dilution of blood in vitro led to doubled plasma levels of the amino acid. Taurine, PEA, and EA increased consistently in CSF and hippocampal microdialysates. Plasma hypoosmolality transiently opened the blood-CSF barrier is reflected by augmented CSF concentrations of albumin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transport of alovudine (3'-fluorothymidine) into the brain and the cerebrospinal fluid of the rat, studied by microdialysis

Extracellular unbound concentrations of alovudine were sampled by microdialysis in order to study the transport of alovudine between the blood and the brain and the cerebrospinal fluid (CSF) in the rat. The AUC (area under the curve) ratio CSF/blood was higher than the brain/blood ratio after i.v. infusion of alovudine 25mg/kg/hr after a loading dose of 25 mg/kg in 5 minutes (n=4). Neither i.v. infusion of thymidine (25 mg/kg/hr, n=5; 100 mg/kg/hr, n=2) nor acetazolamide (50 mg/kg i.p. bolus followed by 25 mg/kg i.p. every second hour, n=3) influenced the brain/blood AUC ratio after alovudine 25 mg/kg s.c. injection compared to controls (n=5). Finally, perfusion through the microdialysis probe with thymidine (1000 microM, n=3) had also no effect on the brain/blood AUC ratio after alovudine 25 mg/kg s.c. Because neither thymidine nor acetazolamide has significant influence on the ability of alovudine to penetrate the blood-brain barrier in the rat, neither thymidine transport nor carboanhydrase dependent CSF production appear to be major determinants of the blood-brain concentration gradient. Thus, it is concluded that alovudine reaches the extracellular fluid of the brain not by cerebrospinal fluid, but via the cerebral capillaries and that the existence of a concentration gradient over both blood-brain and CSF-brain barrier can probably be explained by the presence of an active process pumping alovudine out from the brain.     

Simultaneous Effects of p-Chloroamphetamine, d-Fenfluramine, and Reserpine on Free and Stored 5-Hydroxytryptamine in Brain and Blood

The effects of acute treatment with p-chloramphetamine, d-fenfluramine, and reserpine on intracellular (brain tissue and whole blood) and extracellular (CSF and platelet-free plasma) compartments of 5-hydroxytryptamine (5-HT) in the brain and blood of the same rats have been examined. These treatments affected 5-HT in brain tissue and whole blood similarly (r = 0.823). Reserpine significantly reduced both intracellular pools at 2 and 24 h. p-Chloroamphetamine and d-fenfluramine were more effective on brain tissue 5-HT. The concentration of 5-HT in CSF was significantly increased by all treatments. p-Chloroamphetamine induced a dramatic 70-fold increase of CSF 5-HT, paralleling a 42% decrease in brain tissue. d-Fenfluramine significantly increased CSF 5-HT to 212% of controls and reduced whole brain 5-HT (-23%). The effects of p-chloroamphetamine and d-fenfluramine on 5-HIAA in brain, CSF, and plasma were nonsignificant. Individual values of 5-hydroxyindoleacetic acid (5-HIAA) in CSF and brain were highly correlated (r = 0.855), indicating that CSF 5-HIAA reflects well the concentration of 5-HIAA in brain tissue. Yet the intra- and extracellular concentrations of 5-HIAA were unrelated to the 5-HT changes. This indicates that CSF 5-HIAA does not reflect the active (extracellular) compartment of 5-HT in brain.     

Angiotensinogen in Cerebrospinal Fluid Corresponds Chromatographically to the γ-Form of Plasma Angiotensinogen

Angiotensinogen (Aogen) (CA 11002-13-14), the prohormone of the neuro- and vasoactive peptide angiotensin II (Ang II) (CA 11128-99-7), is found in dog brain as well as in dog plasma. At 2-4 micrograms/ml CSF, Aogen comprises 1-2% of the total protein in dog CSF. Immunopurified CSF and plasma Aogen were compared by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and anion-exchange HPLC. Two major (alpha- and beta-) forms and one minor (gamma-) form of Aogen were observed in dog plasma. The majority of Aogen in dog CSF was chromatographically identical to the gamma-form of plasma Aogen; alpha- and beta-Aogen forms comprised less than 5% of the total CSF Aogen. The N-terminal amino acid sequences of alpha-, beta-, and gamma-Aogen identified these proteins as members of the Aogen family. The N-terminal amino acid sequence of CSF gamma-Aogen was Asp-Arg-Val-Tyr-Ile-His-Pro-Phe-Leu-Leu-Val-Tyr-Ser-Lys-Ser-Ser-(X)-Glu- . More basic than either alpha- or beta-Aogen, gamma-Aogen was shown to be a glycoprotein with an apparent molecular weight (Mr) of 58,000. CSF [des Ang I]-Aogen exhibited a greater anion-exchange HPLC retention. CSF, however, contained only minor amounts of [des Ang I]-Aogen. These analyses have demonstrated that brain overwhelmingly releases one particular Aogen into the CSF; however, very little of this brain Aogen is utilized for the production of Ang I.     

Synthesis and localization of plasma proteins in the developing human brain. Integrity of the fetal blood-brain barrier to endogenous proteins of hepatic origin

The distribution and possible origins of plasma proteins in the human embryonic and fetal brain at different stages of development have been investigated by a combination of isolation and translation of mRNAs and immunocytochemistry using specific antisera. As many as 23 plasma-like proteins have been identified using immunocytochemical methods at the light microscopical level. The presence of mRNAs for 13 of the immunocytochemically positive plasma proteins was demonstrated by in vitro and in ovo translation followed by crossed immunoelectrophoresis and autoradiography; this indicates in situ synthesis of these proteins (e.g., alpha-fetoprotein, alpha 1-antitrypsin, GC-globulin, alpha 2-macroglobulin, pseudocholinesterase, and transferrin) in some brain regions. The regional distribution of some proteins and the absence of some mRNAs suggest that the presence of certain plasma proteins in developing brain may be accounted for by uptake from csf or via nerve processes extending beyond the blood-brain barrier. In several cases, specific proteins appear to be associated with defined cell types, e.g., alpha-fetoprotein, GC-globulin, and ceruloplasmin with neurons, alpha 2-macroglobulin with endothelial cells, and ferritin with glial cells. Some proteins were associated with two or three cell types, e.g., alpha 1-antitrypsin with neurons and glia, and transferrin and alpha 2HS-glycoprotein with neurons, glia, and endothelial cells. Comparison of the expression of mRNAs from fetal brain and liver injected into Xenopus oocytes showed that a few proteins (transferrin and ceruloplasmin) were secreted when liver mRNA was injected, but not when brain mRNA was injected. This suggests that there may be an important difference in the structure and/or processing of these proteins in the brain which may reflect a function different from that associated with them when they originate from the liver. Staining was generally intracellular rather than extracellular; plasma proteins were not associated with the areas immediately around blood vessels although there was a strong immunoprecipitation for each protein within the lumen of cerebral blood vessels. These immunocytochemical findings together with the identification of mRNAs for a large number of plasma proteins in immature brain are discussed in relation to animal experimental work which suggests that the blood-brain barrier to protein is present even at very early stages of brain development.     

The Nature and Composition of the Internal Environment of the Developing Brain

1. The fetal brain develops within its own environment, which is protected from free exchange of most molecules among its extracellular fluid, blood plasma, and cerebrospinal fluid (CSF) by a set of mechanisms described collectively as brain barriers.2. There are high concentrations of proteins in fetal CSF, which are due not to immaturity of the blood–CSF barrier (tight junctions between the epithelial cells of the choroid plexus), but to a specialized transcellular mechanism that specifically transfers some proteins across choroid plexus epithelial cells in the immature brain.3. The proteins in CSF are excluded from the extracellular fluid of the immature brain by the presence of barriers at the CSF–brain interfaces on the inner and outer surfaces of the immature brain. These barriers are not present in the adult.4. Some plasma proteins are present within the cells of the developing brain. Their presence may be explained by a combination of specific uptake from the CSF and synthesis in situ. 5. Information about the composition of the CSF (electrolytes as well as proteins) in the developing brain is of importance for the culture conditions used for experiments with fetal brain tissue in vitro, as neurons in the developing brain are exposed to relatively high concentrations of proteins only when they have cell surface membrane contact with CSF.6. The developmental importance of high protein concentrations in CSF of the immature brain is not understood but may be involved in providing the physical force (colloid osmotic pressure) for expansion of the cerebral ventricles during brain development, as well as possibly having nutritive and specific cell development functions.     

Homeostasis of Brain and Cerebrospinal Fluid Calcium Concentrations During Chronic Hypo-and Hypercalcemia

Three-week-old rats were made hypocalcemic or hypercalcemic by being fed diets low or high in Ca. Both total and ionized [Ca]s in the plasma decreased about 40% and remained depressed for 4 weeks in rats fed a low-Ca diet. Plasma [Ca]s in rats fed a high-Ca diet increased by 30% and remained elevated for 7 weeks. After 8 weeks on the diets, cerebrospinal fluid (CSF) [Ca] changed by less than 30% whereas brain [Ca] changed by less than 20% of the chronic changes in plasma ionized [Ca]. Assuming a brain extracellular volume of 20% and noting that brain extracellular volume equilibrates freely with CSF, the findings demonstrate only small perturbations in the Ca content of the brain cellular compartment during sustained hypo or hypercalcemia. Partial regulation of CSF and brain extracellular Ca suggests a role for the blood-brain barrier in regulating CNS [Ca] during chronic changes in plasma [Ca].     

Proteins of the Brain Extracellular Fluid: Evidence for Release of S-100 Protein

Abstract: Extracellular protein fractions were obtained (1) by mild, isotonic irrigation of freshly perfused brain tissue; (2) by collection of proteins released into super-fusing medium by physiologically viable slices of rat hippocampus; and (3) by sampling the CSF of anesthetized rats. Analysis of the S-100 protein content of these fractions gave values of 2.8, 4.2, and 1.8 μg S-100/mg protein, respectively. These values were three- to sixfold higher than the S-100 content of the soluble cytoplasmic protein fractions from the same tissue. This several-fold higher S-100 content of the extracellular protein fractions relative to the intracellular cytoplasmic protein fractions indicates that S-100 is selectively released into the extracellular spaces of the brain. We suggest that the biological function of this CNS protein may involve intercellular transfer.     

The chemistry of insect hemolymph; organic components of the hemolymph of the silkworm,Bombyx mori,and two other species

1. Hemolymph was collected for analysis from the silkworm, Bombyx mori, in a series of developmental stages ranging from the second molt to the late pupa. The mean pH of larval hemolymph after collection was found to be 6.45, that of pupal hemolymph, 6.57; in vivo values may be slightly lower. Total dry solids ranged from 5.4 to 10.6 per cent. Total protein ranged from 1.2 to 5.3 per cent, increasing rapidly during the fifth instar. 2. Free amino acids were separated chromatographically and estimated. Of 19 amino acids identified, amounting collectively to 823 to 1497 mg. per 100 ml., glutamine, histidine, and lysine generally occurred in greatest amount. Tryptophan was not detected, and cystine (or cysteine) was found in only one sample. The total free amino acids account for 35 to 55 per cent of the non-protein nitrogen of the plasma. 3. Free sugars, estimated semiquantitatively on chromatograms, comprise glucose, fructose, and sucrose in total amount ranging from about 5 to 40 mg. per 100 ml. Total acid-soluble, ultrafiltrable carbohydrate, estimated as glucose by the anthrone reaction, ranged from 166 to 635 mg. per 100 ml., indicating the presence of low molecular weight sugar derivatives. 4. Inorganic phosphate amounted to 5 to 15 mg. per 100 ml., and acid-soluble organic phosphate to 100 to 200 mg. per 100 ml. The latter fraction includes several substances, of which one was tentatively identified as glucose-6-phosphate and the remainder are as yet unidentified. 5. Single samples of hemolymph were also taken from larvae of the wax moth, Galleria mellonella, and the spruce sawfly, Diprion hercyniae. These contained even higher concentrations of solutes than the silkworm samples, but with a generally similar distribution. The proportions of the free amino acids were different in each species.     

Insulin-like growth factor-1 and growth hormone (GH) levels in canine cerebrospinal fluid are unaffected by GH or GH secretagogue (MK-0677) administration.

Elevation in circulating GH levels results in a dose-related increase in serum insulin-like growth factor-1 (IGF-1) levels in dogs. However, it is not known whether elevations in systemic IGF-1 and GH levels contribute to the cerebrospinal fluid (CSF) levels of these hormones. Therefore, a study was designed in dogs to determine if elevated circulating GH levels was a result of a GH secretagogue (MK-0677) or if exogenous GH administration resulted in increased IGF-1 and GH levels in the CSF of dogs. A total of 12 normal, young adult male dogs were randomized to three treatment groups (4 dogs/group) based on body weight. There were 4 vehicle control dogs. A group of 4 dogs were dosed orally with MK-0677 (5 mg/kg/day) dissolved in deionized water. A third group of 4 dogs received subcutaneous injections of porcine GH (pGH) at a dose of 0.1 IU/kg/day. From all dogs, blood and CSF samples were collected prior to the initiation of treatment and on days 7 and 15 of treatment. All samples were assayed using a validated radioimmunoassay. Administration of MK-0677 or pGH resulted in a statistically significant (P < or = 0.05) increased body weight gain and increased serum IGF-1 and GH levels. In contrast, administration of MK-0677 resulted in no significant (P > 0.05) increase in CSF IGF-1 or GH levels on days 7 or 15 of the study. The CSF IGF-1 values ranged from 1.2 to 2.0 ng/ml with minimal variation among three separate samples taken during the course of the study from each dog. Similarly, the CSF GH levels were very low (< 0.98 ng/ml to 2.4 ng/ml) in all dogs irrespective of treatment group. This study has demonstrated that there is no correlation between the circulating levels of IGF-1 or GH and the levels of these hormones in the CSF of normal dogs. An approximately 100-fold difference between serum and CSF IGF-1 levels in vehicle control dogs suggest that there is a blood-brain barrier for the circulating IGF-1. Similarly, failure to see an elevation in CSF GH levels despite increases in serum GH levels shows that there is a blood-brain barrier for GH in normal dogs. These results suggest that the likely source of GH and IGF-1 in the CSF of dogs is from the CNS.     

Stimulation of prolactin secretion by L-3,4-dihydroxyphenyl-serine (L-DOPS) via central norepinephrine in the rat

Intracerebroventricular (icv) injection of L-3,4-dihydroxyphenylserine (L-DOPS) (50 and 250 micrograms/rat) raised in a dose-related manner both plasma prolactin (PRL) and CSF norepinephrine (NE) in urethane-anesthetized male rats. Intravenous (iv) injection of larger doses of L-DOPS (5 and 10 mg/100 g BW) slightly but significantly increased plasma PRL and CSF NE. L-DOPS injection (50 micrograms/rat, icv or 5 mg/100 g BW, iv) also raised plasma PRL in conscious rats. There was a good correlation (r = 0.74) between CSF NE and peak plasma PRL in the anesthetized animals. Propranolol (100 micrograms/100 g BW, iv) inhibited plasma PRL responses to L-DOPS (50 micrograms/rat, icv) and NE injection (1 microgram/rat, icv) raised plasma PRL in anesthetized animals. These findings indicate that L-DOPS stimulates PRL secretion via central noradrenergic mechanisms in the rat.     

Putative apolipoprotein B-100 in the freshwater turtle Chrysemys picta: effects of estrogen and progesterone.

1. The isolation and purification of a putative apolipoprotein B-100 in the plasma of the freshwater turtle Chrysemys picta is described. 2. The protein was purified through differential ultracentrifugation and subsequent Sepharose 6B column chromatography. 3. The molecular weight of the protein determined by electrophoresis was approximately 350 kDa. 4. An antibody to chicken apolipoprotein B-100 specifically recognizes this 350 kDa protein in Western blots, suggesting its identity with apolipoprotein B-100. 5. An antibody to the putative Chrysemys apolipoprotein B-100-like protein was developed and used in an ELISA to quantitate protein levels in plasma. 6. Acute estrogen treatment increased levels of apolipoprotein B-100 (7.64 +/- 0.79 mg/ml plasma) over that of control animals (5.07 +/- 1.74 mg/ml plasma). 7. In contrast, chronic estrogen treatment reduced apolipoprotein B-100 significantly to 2.94 +/- 0.53 mg/ml plasma (P < 0.05).     

Small Rises in Plasma Choline Reverse the Negative Arteriovenous Difference of Brain Choline

The concentrations of free choline in blood plasma from a peripheral artery and from the transverse sinus, in the CSF, and in total brain homogenate, have been measured in untreated rats and in rats after acute intraperitoneal administration of choline chloride. In untreated rats, the arteriovenous difference of brain choline was related to the arterial choline level. At low arterial blood levels (less than 10 microM) as observed under fasting conditions, the arteriovenous difference was negative (about -2 microM), indicating a net release of choline from the brain of about 1.6 nmol/g/min. In rats with spontaneously high arterial blood levels (greater than 15 microM), the arteriovenous difference was positive, implying a marked net uptake of choline by the brain (3.1 nmol/g/min). The CSF choline concentration, which reflects changes in the extracellular choline concentration, also increased with increasing plasma levels and closely paralleled the gradually rising net uptake. Acute administration of 6, 20, or 60 mg of choline chloride/kg caused, in a dose-dependent manner, a sharp rise of the arterial blood levels and the CSF choline, and reversed the arteriovenous difference of choline to markedly positive values. The total free choline in the brain rose only initially and to a quantitatively negligible extent. Thus, the amount of choline taken up by the brain within 30 min was stored almost completely in a metabolized form and was sufficient to sustain the release of choline from the brain as long as the plasma level remained low. We conclude that the extracellular choline concentration of the brain closely parallels fluctuations in the plasma level of choline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Profiling neurosteroids in cerebrospinal fluids and plasma by gas chromatography/electron capture negative chemical ionization mass spectrometry

A quantitative method for the determination of allopregnanolone (5alpha,3alpha-THP) and related neurosteroids in CSF and plasma was established using gas chromatography/electron capture negative chemical ionization mass spectrometry (GC/ECNCI/MS). Neurosteroids were converted to carboxymethoxime, pentafluorobenzyl and trimethylsilyl derivatives and detected as intense (M-181)(-) fragment ions generated under the negative ion chemical ionization process. The response curves constructed using d(4)-dihydrotestosterone (DHT) and d(4)-5alpha,3alpha-THP as internal standards showed linearity in the concentration range of 10-1000 pg/ml. The variation of response ratios determined against internal standards over a 2-month period was less than 10%. Instrumental detection limits for most neurosteroids were in the low picogram range with the exception of progesterone and dihydroprogesterone (DHP) which were detected with approximately 10 times less sensitivity in comparison to other steroids. In conjunction with solid-phase extraction, this method allowed the quantification of at least four neurosteroids, including androsterone, testosterone, 5alpha,3alpha-THP, and pregnenolone in 1-2 ml of human cerebrospinal fluid (CSF). While the level of 5alpha, 3alpha-THP in human CSF was comparable to that in the human plasma, other steroid levels were significantly lower. Although individual CSF and plasma samples showed widely varying neurosteroid levels, species specificity appeared to exist. The levels of 5alpha, 3alpha-THP and pregnenolone in human CSF were higher than those of monkey CSF where these steroids were often not detected with our current detection limit. In comparison to human plasma, rat plasma samples contained considerably lower levels of androsterone and pregnenolone. Among THP stereoisomers, 5beta,3alpha-THP and 5alpha, 3beta-THP were observed only in human plasma, while 5beta,3beta-THP was detected only in rat plasma.     

Differential changes in alpha2-macroglobulin and hemopexin in brain and liver in response to acute inflammation.

Changes in serum and cerebrospinal fluid (CSF) proteins following generalized acute inflammation induced by fermented yeast in the rat was examined by concanavalin A-blotting, immunoblotting, and radioimmunoassay. Using alpha2-macroglobulin (alpha2-M) and hemopexin (HPX) as marker proteins, the concentration alpha2-M was found to increase in serum and CSF by 150- and 5-fold, respectively, whereas the concentration of HPX increased by about 4-fold in both fluids following yeast-induced inflammation. The lesser increase in alpha2-M in the CSF versus the systemic circulation is not likely to be the result of changes in the permeability of the blood--brain barrier, since no change in the total protein content of CSF was detected in inflamed rats when compared to control animals. These results, however, illustrate the regulation of the same protein, such as alpha2-M, in two separate organs within the same animal can be drastically different. These results also suggest a possible protective role of alpha2-M in the brain during acute inflammation. Moreover, these observations are consistent with the previous observation that there is a differential response in the level of alpha2-M between the testis and the systemic circulation during inflammation.     

Brain and cerebrospinal fluid uptake of zidovudine (AZT) in rats after intravenous injection

Uptake kinetics of zidovudine into cerebrospinal fluid (CSF) and brain tissue were determined in adult Sprague Dawley male rats after single intravenous injection of 6.7 mg/kg (25 mumol/kg). The drug kinetics in plasma followed biexponential disposition with an initial distribution half-life of approximately 11 minutes and an elimination half-life of 40 minutes. Over the plasma concentration range of 0.2 to 10 micrograms/ml, the cerebrospinal fluid to plasma ratio averaged 14.8 +/- 1.9% whereas the mean brain tissue to plasma ratio was 8.2 +/- 1.2% (uncorrected) or 2.3 +/- 1.8% (corrected) for the brain vascular space contribution. Simultaneous nonlinear regression analysis of brain, CSF and plasma concentration data indicate that the overall rate constant for efflux of drug from brain is approximately 75-fold higher and from CSF is 8-fold higher than the respective rate constants for influx. Thus, the ratio of the efflux to influx appears to be the predominant factor in determining the net accumulation of drug into CSF and brain parenchymal tissue.