99mTc(Cu)—mannitol complex: a new agent for dynamic renal function studies

Mannitol has been labelled with ^99mTc by using cuprous chloride as a reducing agent. Blood and kidney clearance of ^99mTc(Cu)-mannitol was slightly faster than that of ^99mTc(Sn)-DTPA in rat and maximum radioactivity ratio of kidneys to blood was 84.6 at 5 min. A comparative study of ^99mTc(Cu)-mannitol, ^99mTc(Sn)-DTPA was made in rabbits by taking serial images of kidneys and bladder with a γ camera. Results show superiority of ^99mTc(Cu)-mannitol over other agents for dynamic renal function studies.     

The effect of trehalose on autophagy-related proteins and cyst growth in a hypomorphic Pkd1 mouse model of autosomal dominant polycystic kidney disease

Autosomal dominant polycystic kidney disease (ADPKD) is a common inherited disorder characterized by kidney cyst growth often resulting in end-stage renal disease. There is growing attention on understanding the role of impaired autophagy in ADPKD. Trehalose (TRE) has been shown to increase both protein stability and aggregate clearance and induce autophagy in neurodegenerative diseases. TRE treatment in wild type mice compared to vehicle resulted in increased expression in the kidney of Atg12–5 complex and increased Rab9a, autophagy-related proteins that play a role in the formation of autophagosomes. Thus, the aim of the study was to determine the effect of TRE on cyst growth and autophagy-related proteins, in the hypomorphic Pkd1^RC/RC mouse model of ADPKD. Pkd1^RC/RC mice were treated 2% TRE in water from days 50 to 120 of age. TRE did not slow cyst growth or improve kidney function or affect proliferation and apoptosis in Pkd1^RC/RC kidneys. In Pkd1^RC/RC vs. wild type kidneys, expression of the Atg12–5 complex was inhibited by TRE resulting in increased free Atg12 and TRE was unable to rescue the deficiency of the Atg12–5 complex. Rab9a was decreased in Pkd1^RC/RC vs. wild type kidneys and unaffected by TRE. The TRE-induced increase in p62, a marker of autophagic cargo, that was seen in normal kidneys was blocked in Pkd1^RC/RC kidneys. In summary, the autophagy phenotype in Pkd1^RC/RC kidneys was characterized by decreases in crucial autophagy-related proteins (Atg12–5 complex, Atg5, Atg16L1), decreased Rab9a and increased mTORC1 (pS6^S240/244, pmTOR^S2448) proteins. TRE increased Atg12–5 complex, Rab9a and p62 in normal kidneys, but was unable to rescue the deficiency in autophagy proteins or suppress mTORC1 in Pkd1^RC/RC kidneys and did not protect against cyst growth.     

Water and electrolyte contents and extracellular space of rabbit kidneys after perfusion and storage for 24 hr at 4 °C

Rabbit kidneys were perfused with 50 ml of various solutions at 4 °C and then stored in the same solution at 4 °C for 24 hr. The solutions studied were as follows: WF1 was a balanced electrolyte solution resembling extracellular fluid; in WF2, sufficient glucose was added to raise the osmolality to 400 mosmol/kg; in WF3, one half (70 mmol) of the NaCl was omitted, but in this and in all subsequent solutions the total osmolality was maintained at 400 mosmol/kg by the inclusion of an appropriate amount of glucose; in WF4, 70 meq of Na⁺ was replaced by K⁺, in WF5, 70 meq of Na⁺ was replaced by Mg²⁺.After storage, cortical slices were cut from each kidney, and the extracellular space was measured with ⁵¹Cr-EDTA, water content by drying to constant weight, and total Na⁺ and K⁺ by flame photometry. Intracellular Na⁺ and K⁺ concentrations were calculated.It was found that the water content of all the perfused kidneys was increased but was lowest when the osmolality had been raised to 400 mosmol/kg with glucose, and the ionic strength was normal; the kidneys perfused with WF5 had the lowest water content. Gained water was generally distributed equally between the intracellular and the extracellular space, but cell swelling was prevented by the WF5 solution. All kidneys gained Na⁺ and all except those perfused with WF4 (the high-K⁺ solution) lost K⁺, but the loss was least with WF5.Overall, the changes during storage were least in the kidneys perfused with the highosmolality, high-Mg²⁺ solution, WF5. It is suggested that this solution may be useful as a washout fluid for short-term renal preservation.     

LGR4 Is Required for the Cell Survival of the Peripheral Mesenchyme at the Embryonic Stages of Nephrogenesis

In mice, homozygous Lgr4 inactivation results in hypoplastic kidneys. To understand better the role of LGR4 in kidney development, we performed an analysis of kidneys in Lgr4 ^-/- embryos. We stained Lgr4 ^-/- kidneys with anti-WT1 and anti-Cleaved Caspase3 antibodies at E16.5, and observed that the structures of the cap mesenchyme were disrupted and that apoptosis increased. In addition, the expression of PAX2, an anti-apoptotic factor in kidney development, was also significantly decreased at E16.5. We found that the LGR4 defect caused an increase in apoptosis in the peripheral mesenchyme during kidney development.     

Influence of short-term hypothermia upon the normal or ischaemic dog kidney.

Dog kidneys were subjected to 1 hr of normothermic ischaemia, maintained for 3 hr in hypothermia with autologous heparinised blood, or underwent a combination of these two treatments and were examined either immediately after the trauma or at different periods up to 1 week after autotransplantation. Clearance tests, tubular amino acid and sugar transport, cortical Na⁺K⁺-ATPase levels, acid phosphatase liberated into the renal circulation, and morphology were investigated. The results obtained (i) confirmed the severe, but slowly and progressively reversible lesion after ischaemia; (ii) revealed the functional impairment with almost normal morphology after hypothermia; and (iii) indicated the immediate and irreparable deterioration of renal function after ischaemic kidneys were subjected to short-term hypothermic treatment of this type.     

Effect of acetate on transport of organic acid (fluorescein) in renal proximal tubules of frog

The effect of acetate on active fluorescein transport in intact proximal tubules of surviving frog kidney was studied. When the kidneys were incubated in a 120 mM Na⁺ medium, 10 mM acetate stimulated fluorescein uptake in the tubules. The stimulation was more pronounced if the kidneys had been previously preincubated for 3 h in the substrate-free solution. Lowering of the Na⁺ concentration in the bathing medium to 10 mM resulted in the disappearance of the acetate effect. Preincubation of the kidneys with acetate at 2–4°C gave rise to stimulation of the fluorescein transport only in the 120 mM Na⁺ acetate-free medium. The acetate effect on the fluorescein uptake was partially prevented by ouabain. The stimulation of the uptake by acetate in the 120 mM Na⁺ medium correlated with an increase in the extent of reduction of pyridine nucleotides in the tubules. The pyridine nucleotides were reduced more markedly after incubation of the kidneys in the 10 mM Na⁺ medium, when acetate had no effect on the fluorescein transport. In both the 120 mM and the 10 mM Na⁺ media, the cold preincubation of the kidneys with 2.5 mM ADP or 2.5 mM ATP resulted in only slight stimulation of the fluorescein uptake. But in both media the uptake was significantly enhanced after cold preincubation of the kidneys with 2 mM NADH. After the cold precincubation with ADP, stimulation of the fluorescein transport by acetate was observed in the case of the 10 mM Na⁺ medium also. The absence of any stimulatory effect of acetate on the organic acid transport in the 10 mM Na⁺ medium is explained as the result of the transformation of mitochondria in the tubular cells into the inactive state 4 due to a decrease in the intracellular ADP level. Reducing equivalents are supposed to take part in energization and/or regulation of transport processes in plasma membranes of the renal proximal tubules.     

Design,development, and performance of an electromagnetic illumination system for thawing cryopreserved kidneys of rabbits and dogs

Kidneys from rabbits and dogs were perfused with one of several DMSO concentrations (0.0, 0.7, 1.4, 2.1 m) in a K⁺-Mg²⁺-rich perfusate, frozen, and then thawed with equipment providing electromagnetic (EM) illumination. Electrical properties (dielectric constant and loss tangent) of kidneys were measured both before and after EM thawing. The kidneys thawed were evaluated by simple anatomical (macroscopic and microscopic) and physiological observations rather than by transplantation.Rabbit kidneys which are no thicker than 2 cm could be optimally (uniformly and rapidly) thawed by use of illumination at 2450 MHz, a frequency which has a penetration depth of 2.1 cm at 0 °C, Optimal thawing of canine kidneys, which are twice as thick as rabbit kidneys, required the insertion of steel spheres (electroseeds) into the renal pelvis prior to freezing and illumination at 7 MHz in addition to that at 2450 MHz. Increasing the DMSO concentration (0.0 to 2.1 m) in renal tissue illuminated with 2450 MHz increased the conductivity and the permittivity regardless of whether the renal tissue was frozen or thawed. The use of DMSO decreased the time for thawing with EM illumination and yielded kidneys with improved post-thaw morphology.     

Evaluation of kidney repair capacity using Tc-DMSA in ischemia/reperfusion injury models

Quantitative ^99mTc-DMSA renal uptake was studied in different renal ischemia/reperfusion (I/R) mice models for the assessment of renal repair capacity. Mice models of nephrectomy, uni- and bi-lateral I/R together with sham-operated mice were established. At 1 h, 1 d, 4 d, 1, 2 and 3 wk after I/R, ^99mTc-DMSA (27.7 ± 1.3 MBq) was injected via tail vein and after 3 h post-injection, the mice were scanned for 30 min with pinhole equipped gamma camera. Higher uptake of ^99mTc-DMSA was measured in normal kidneys of uni-lateral I/R model and nephrectomized kidney I/R model at 3 wk post-surgery. Comparing the restoration capacities of the affected kidneys of nephrectomy, uni- and bi-lateral I/R models, higher repair capacity was observed in the nephrectomized model followed by bi-lateral then uni-lateral models. The normal kidney may retard the restoration of damaged kidney in uni-lateral I/R model. Moreover, 3 wk after Uni-I/R, the size of injured kidney was significantly smaller than non-ischemic contralateral and sham operated kidneys, while nephrectomy I/R kidneys were significantly enlarged compared to all others at 3 wk post-surgery. Very strong correlation between ^99mTc-DMSA uptake and weight of dissected kidneys in I/R models was observed. Consistent with ^99mTc-DMSA uptake results, all histological results indicate that kidney recovery after injury is correlated with the amount of intact tubules and kidney sizes. In summary, our study showed good potentials of ^99mTc-DMSA scan as a promising non-invasive method for evaluation of kidney restoration after I/R injuries. Interestingly, mice with Bi-I/R injury showed faster repair capacity than those with uni-I/R.     

Radiosynthesis of [thiocarbonyl-11C]disulfiram and its first PET study in mice

[Thiocarbonyl-¹¹C]disulfiram ([¹¹C]DSF) was synthesized via iodine oxidation of [¹¹C]diethylcarbamodithioic acid ([¹¹C]DETC), which was prepared from [¹¹C]carbon disulfide and diethylamine. The decay-corrected isolated radiochemical yield (RCY) of [¹¹C]DSF was greatly affected by the addition of unlabeled carbon disulfide. In the presence of carbon disulfide, the RCY was increased up to 22% with low molar activity (A_m, 0.27 GBq/μmol). On the other hand, [¹¹C]DSF was obtained in 0.4% RCY with a high A_m value (95 GBq/μmol) in the absence of carbon disulfide. The radiochemical purity of [¹¹C]DSF was always >98%. The first PET study on [¹¹C]DSF was performed in mice. A high uptake of radioactivity was observed in the liver, kidneys, and gallbladder. The uptake level and distribution pattern in mice were not significantly affected by the A_m value of the [¹¹C]DSF sample used. In vivo metabolite analysis showed the rapid decomposition of [¹¹C]DSF in mouse plasma.     

90Y-resin particles—Animal experiments on pigs with regard to the introduction of superselective embolization therapy

Resin particles (diameter 45–75 μm) were labelled with ⁹⁰Y, suspended in a glucose/dextran solution and infused into the kidneys of 3-month-old pigs (tumour model). Both kidneys of each animal were embolized with particles, but only one with active (⁹⁰Y loaded) particles and the other, for comparison, with inactive particles. The organ measurements showed < 1% of injected activity in bone, bone marrow, liver and lung compared to > 99% retention by the kidneys. Only minimal shunted activity was found in blood (<0.27%) and urine (<0.07%). There was a clear shrinkage of the ⁹⁰Y-treated kidneys with a reduction in weight of up to 50%. Histologically, the ischaemic lesions (infarcts and atrophy) were clearly more pronounced and extensive in the ⁹⁰Y-embolized kidneys than in the non-radioactive embolized kidneys. Furthermore, severe arterial wall changes and fibrotic necrosis due to radiation damage were observed in the ⁹⁰Y-treated kidneys. It is concluded that with intra-arterially applied particles a dose of about 100 Gy is sufficient to completely destroy tissue-specific structures. Complications due to acute necrosis or inflammatory reactions were not observed, and there were no shunt related alterations seen in the liver or lungs. The ⁹⁰Y-loaded resin particles are considered suitable for a super selective intra-arterial radioembolization.     

Control of renal and extrarenal salt and water excretion by plasma angiotensin II in the kelp gull (Larus dominicanus)

Summary The osmoregulatory effects of intravenously (i.v.) administered angiotensin II (AII) at dose rates of 5, 15 and 45 ng · kg^–1 · min^–1 were examined in kelp gulls utilizing salt glands and/or kidneys as excretory organs.In birds given i.v. infusion of 1200 mOsmolal NaCl at 0.3 ml · min^–1 and utilizing only the salt glands to excrete the load, infusion of AII for 30 min consistently inhibited salt gland function in a dose-dependent manner.In birds given i.v. infusion of 500 mOsmolal NaCl at 0.72 ml · min^–1 and utilizing both salt glands and kidneys to excrete the load, each dose of AII given for 2 h inhibited salt gland function but stimulated the kidney, so that the overall outputs of salt and water were enhanced and showed significant (2P<0.01) positive correlations with plasma AII.In birds given i.v. infusion of 200 mOsmolal glucose at 0.5 ml · min^–1 and utilizing only the kidneys to excrete the load, low doses of AII (5 and 15 ng · kg^–1 · min^–1) caused renal salt and water retention, whereas a high dose (45 ng · kg^–1 · min^–1) stimulated salt and water output.The actions of plasma AII in kelp gulls support the concept that this hormone plays a vital role in avian osmoregulation, having effects on both salt gland and kidney function. Elevation of plasma AII consistently inhibits actively secreting salt glands, but its effects upon renal excretion depend primarily on the osmotic status as well as on the plasma AII concentration. In conditions of salt and volume loading doses of AII stimulate sodium and water excretion. With salt and volume depletion, the action of AII is bi-phasic with low doses promoting renal sodium and water retention but high circulating levels causing natriuresis and diuresis.     

Radiosynthesis,radiochemical, and biological characterization of 177Lu-labeled diethylenetriamine penta-acetic acid

Diethylenetriamine penta-acetic acid (DTPA), when complexed with a gamma (γ)-emitter radioisotope like ^99mTc, is used for renal function diagnosis and many other diagnostic applications. The main aim of this study was to develop a novel and versatile single-step methodology for the synthesis of a new ¹⁷⁷Lu-labeled radiopharmaceutical with high radiochemical yield, which can be used for diagnostic purposes and therapeutic purposes also. The single and well-defined ¹⁷⁷Lu-DTPA complex was radiochemically characterized by paper chromatography, thin-layer chromatography, high-performance liquid chromatography, and electrophoresis techniques. Dependence of the labeling yield of ¹⁷⁷Lu-DTPA complex on different factors was studied in detail. Biological evaluation was also performed in a normal rabbit by developing images under a γ camera at various time intervals. More than 99% labeling yield was obtained by reacting DTPA with ¹⁷⁷Lu at specific conditions (pH 7.0, 15 minutes reaction time at 100 °C). ¹⁷⁷Lu-DTPA complex showed high stability both at room temperature and in vitro. Biodistribution studies in normal mice indicated the fractional renal uptake of intravenously administered ¹⁷⁷Lu-DTPA complex, which reached in the kidneys within 2-3 minutes. Scintigraphy showed rapid clearance from the body. Based on these results, we propose that ¹⁷⁷Lu-DTPA complex might be used as an ideal candidate for functional evaluation of kidneys and the urinary tract, especially when needed to be transported to long-range consumer sites, because of its suitable half-life.     

Studies on the metabolic fate of 111In-labeled antibodies

Indium-111-labeled antibodies, though providing superior photon flux to iodine-labeled antibodies, can exhibit high levels of accumulation in some non-target organs. In an effort to understand the nature of this non-target uptake we have evaluated the molecular weight of ¹¹¹In species retained in several tissues by radio-FPLC (sizing chromatography) following injection of [¹¹¹In]DTPA 5G6.4, a murine monoclonal antibody, into normal mice. Blood, liver and kidneys were removed, and liver and kidneys were homogenized at several time points after antibody injection. The proportion of ¹¹¹In-containing species was found to vary with the tissue and with time. Analysis of blood showed only radiolabeled antibody. In the liver, several ¹¹¹In species were identified with molecular weights compatible with intact antibody, [¹¹¹In]transferrin, and low molecular weight complexes, with an increase in the proportion of [¹¹¹In]transferrin and low molecular weight species occurring over time. While the same molecular weight species were also identified in the kidneys, the kidneys contained the largest percentage of low molecular weight species which increased over time. When ¹²⁵I-labeled 5G6.4 was injected and the tissues similarly analyzed, only radioactive material with the molecular weight of intact antibody was detected. Comparison of two methods of purification of [¹¹¹In]labeled antibody after labeling revealed a significant difference in the organ uptake of radiolabeled products for ¹¹¹In. Although dialysis was sufficient for the removal of labile ¹¹¹In, as determined by TLC, subsequent sizing chromatography on Bio-Gel P-60 dramatically dropped the hepatic and renal uptake of ¹¹¹In relative to blood and diminished the proportion of the low molecular weight species present on sizing FPLC of extracts from tissues. These data indicate that low and intermediate molecular weight ¹¹¹In compounds are accreted in the liver and kidneys following the i.p. injection of ¹¹¹In-labeled monoclonal antibodies and that their uptake can be diminished by more stringent radioantibody purification. This knowledge may be valuable in developing methods for reducing non-target ¹¹¹In uptake.     

Transplantation of rabbit kidneys perfused with glycerol solutions at 10 degrees C.

Experiments are described in which rabbit kidneys were perfused with solutions containing 2, 3, or 4 m glycerol and then were autografted in order to measure any functional impairment. The basic perfusate contained Haemaccel (17.5 g/litre) and mannitol (111 mm) and had a total osmolality of 400 mosmol/kg. The perfusion temperature was 10 °C. Glycerol concentration was slowly increased at a rate of 30 mm min^?1 to 2, 3, or 4 m, was held at the maximum concentration for 30 min, and was then decreased to < 0.1 m at 30 mm min^?1. An immediate contralateral nephrectomy was carried out, and the function of the perfused kidney was assessed by serial measurements of blood urea and serum creatinine, by the determination of 24-hr endogenous creatinine clearance at 1 month and by histological examination. It was found that a concentration of 3 m glycerol was readily tolerated.     

Carbon accumulation, distribution and water use of Danthonia richardsonii swards in response to CO2 and nitrogen supply over four years of growth

Microcosms of Danthonia richardsonii (Cashmore) accumulated more carbon when grown under CO₂ enrichment (719 μL L^–1 cf. 359 μL L^–1) over a four-year period, even when nitrogen availability severely restricted productivity (enhancement ratios for total microcosm C accumulation of 1.21, 1.14 and 1.29 for mineral N supplies of 2.2, 6.7 and 19.8 g N m^–2 y^–1, respectively). The effect of CO₂ enrichment on total system carbon content did not diminish with time. Increased carbon accumulation occurred despite the development over time of a lower leaf area index and less carbon in the green leaf fraction at high CO₂. The extra carbon accumulated at high CO₂ in the soil, senesced leaf and leaf litter fractions at all N levels, and in root at high-N, while at low-and mid-N less carbon accumulated in the root fraction at high CO₂. The rate of leaf turnover was increased under CO₂ enrichment, as indicated by increases in the carbon mass ratio of senesced to green leaf lamina. Microcosm evapotranspiration rates were lower at high CO₂ when water was in abundant supply, resulting in higher average soil water contents. The higher soil water contents at high CO₂ have important implications for microcosm function, and may have contributed significantly to the increased carbon accumulation at high CO₂. These results indicate that CO₂ enrichment can increase carbon accumulation by a simple soil–plant system, and that any increase in whole system carbon accumulation may not be evident from snapshot measurements of live plant carbon.     

Functional preservation of the mammalian kidney. IV. Functional effects of perfusion with dimethyl sulfoxide (DMSO) at normothermia

Rabbit kidneys were perfused at 37 °C with various concentrations of DMSO in a K⁺-Mg²⁺-rich perfusate. The effects of DMSO on various functional parameters of the rabbit kidney perfused for 60 min were compared with the functional effects of perfusion without DMSO under the same conditions. DMSO produced deviations in vascular resistance and perfusate flow rate from control values. In kidneys perfused with 1.4 and 2.8 m DMSO these vascular changes resulted in changes in GFR at relatively unchanged filtration fractions. The closely parallel relationship between changes in GFR and urine flow rate in all groups indicates that perfusion per se or perfusion with DMSO may shift the regulation of urine flow rate from tubular reabsorption, which obtains in the in vivo situation, to glomerular filtration. This view was supported by the relatively unchanged parameters of Na⁺ reabsorption and fractional water excretion during perfusion with all concentrations of DMSO. Additionally, DMSO perfusion resulted in significantly greater weight gains than those observed in kidneys perfused without DMSO, and significantly depressed clearances of PAH, with 2.1 and 2.8 m DMSO.     

Dynamics of carbon stocks in soils and detritus across chronosequences of different forest types in the Pacific Northwest, USA

We investigated variation in carbon stock in soils and detritus (forest floor and woody debris) in chronosequences that represent the range of forest types in the US Pacific Northwest. Stands range in age from <13 to >600 years. Soil carbon, to a depth of 100 cm, was highest in coastal Sitka spruce/western hemlock forests (36±10 kg C m^?2) and lowest in semiarid ponderosa pine forests (7±10 kg C m^?2). Forests distributed across the Cascade Mountains had intermediate values between 10 and 25 kg C m^?2. Soil carbon stocks were best described as a linear function of net primary productivity (r²=0.52), annual precipitation (r²=0.51), and a power function of forest floor mean residence time (r²=0.67). The highest rates of soil and detritus carbon turnover were recorded on mesic sites of Douglas‐fir/western hemlock forests in the Cascade Mountains with lower rates in wetter and drier habitats, similar to the pattern of site productivity. The relative contribution of soil and detritus carbon to total ecosystem carbon decreased as a negative exponential function of stand age to a value of ～35% between 150 and 200 years across the forest types. These age‐dependent trends in the portioning of carbon between biomass and necromass were not different among forest types. Model estimates of soil carbon storage based on decomposition of legacy carbon and carbon accumulation following stand‐replacing disturbance showed that soil carbon storage reached an asymptote between 150 and 200 years, which has significant implications to modeling carbon dynamics of the temperate coniferous forests following a stand‐replacing disturbance.     

Seasonal soil‐surface carbon fluxes from the root systems of young Pinus radiata trees growing at ambient and elevated CO2 concentration

Elevated atmospheric CO₂ concentration may result in increased below‐ground carbon allocation by trees, thereby altering soil carbon cycling. Seasonal estimates of soil surface carbon flux were made to determine whether carbon losses from Pinus radiata trees growing at elevated CO₂ concentration were higher than those at ambient CO₂ concentration, and whether this was related to increased fine root growth. Monthly soil surface carbon flux density (f) measurements were made on plots with trees growing at ambient (350) and elevated (650 μmol mol^?1) CO₂ concentration in large open‐top chambers. Prior to planting the soil carbon concentration (0.1%) and f (0.28 μmol m^?2 s^?1 at 15 °C) were low. A function describing the radial pattern of f with distance from tree stems was used to estimate the annual carbon flux from tree plots. Seasonal estimates of fine root production were made from minirhizotrons and the radial distribution of roots compared with radial measurements of f. A one‐dimensional gas diffusion model was used to estimate f from soil CO₂ concentrations at four depths. For the second year of growth, the annual carbon flux from the plots was 1671 g y^?1 and 1895 g y^?1 at ambient and elevated CO₂ concentrations, respectively, although this was not a significant difference. Higher f at elevated CO₂ concentration was largely explained by increased fine root biomass. Fine root biomass and stem production were both positively related to f. Both root length density and f declined exponentially with distance from the stem, and had similar length scales. Diurnal changes in f were largely explained by changes in soil temperature at a depth of 0.05 m. Ignoring the change of f with increasing distance from tree stems when scaling to a unit ground area basis from measurements with individual trees could result in under‐ or overestimates of soil‐surface carbon fluxes, especially in young stands when fine roots are unevenly distributed.     

Perfusion of rabbit kidneys with glycerol solutions at 5 °C

The long-term preservation of whole organs will almost certainly require the use of subzero temperatures and cryoprotectants. An essential part of such a technique is the ability to add a cryoprotectant in adequate concentration and subsequently to remove it without damage to the organ. In this study rabbit kidneys have been perfused with solutions containing 3% dextran and 2 m glycerol at 5 °C, and their function has been measured after removal of the glycerol. The assay technique involved the measurement of glomerular filtration rate, protein leakage, and tubular reabsorption of sodium and glucose. The results indicate that the inclusion in the perfusate of an impermeant solute (mannitol) and limitation of the rate of change of glycerol concentration (to 30 mm min^?1) permits rabbit kidneys to retain a degree of function similar to that found in perfused control kidneys, although somewhat reduced in comparison with freshly isolated kidneys.     

Nuclear magnetic resonance-based metabolomics of OCT-embedded frozen kidney samples in mouse and man following standardized pre-analytics

Introduction

Pre-analytical processing significantly affects tissue metabolomes. Since most frozen kidney samples are stored after embedding, standardization of cryoprotective medium removal before metabolomics is essential.

Objectives

We used rodent and human kidney samples to develop an easy and robust pre-analytical procedure compatible with ¹H-nuclear magnetic resonance (NMR)-based metabolomics.

Methods

In mice, renal ischemia was induced for 30 min, followed by 48-h reperfusion (I/R, n?=?6). Right kidneys were transversally cut in two fragments, and snap-frozen in liquid nitrogen (LN2) or in Optimal Cutting Temperature ^® (OCT) fixative. In man, double kidney biopsies were simultaneously obtained before transplantation (n?=?15), and snap-frozen in LN2 or OCT.

Results

¹H-NMR spectrum of pure OCT highlighted two major peaks, i.e. from 3.4 to 4.2 ppm (47.2%) and from 1.2 to 2.2 ppm (42.5%). ¹H-NMR spectra of mouse OCT kidneys were biased at 3.7. By contrast, ¹H-NMR analyses of mouse OCT kidneys iteratively rinsed in saline significantly discriminated sham versus I/R groups, with Q² at 0.695 (to be compared with Q² at 0.866 for LN2 sham vs. I/R kidneys). Discriminant metabolites were analogous in both OCT and LN2 kidneys, with a correlation coefficient of 0.83. In man, iteratively rinsing OCT kidneys in saline eliminated the spectral 3.7-peak, thereby making metabolomes of OCT kidneys interpretable and similar to LN2 samples, with a correlation coefficient of 0.73.

Conclusion

NMR metabolomics using OCT-frozen kidney samples is valuable in mouse and man, following standardized OCT removal. This may help use residual biobanked human tissues to better understand renal pathophysiology.