The debate about drag and reconfiguration of freshwater macrophytes: comparing results obtained by three recently discussed approaches

1. The paper by Sand‐Jensen (2003 , Freshwater Biology, 48 , 271–283) on drag and reconfiguration of freshwater macrophytes stimulated comments and a reply about the use of variables in assessments of the drag coefficient (C_d) or the Reynolds number (Re) of such plants. Although the physical argument in this debate starts from the same equations, it diverges into approaches that address differently the dynamic behaviour of flexible plants in the boundary layer flow (the typical condition experienced by lotic macrophytes). 2. We compared three (potentially among many more) such different approaches using some preliminary experiments with Egeria densa by measuring drag (and other physical variables of interest) on (1) a single shoot exposed to varying flume flows; (2) a single shoot exposed to a constant flume flow, from which we subsequently pruned off pieces from the distal end; and (3) multiple shoots exposed to a constant flume flow after they had experienced replicated flow disturbances (causing shoot reconfiguration). 3. These experiments illustrated that the three approaches can produce opposite trends in the relationship between C_d and Re and that, for a given plant and flow, the C_d values obtained by these approaches can differ by about two orders of magnitude. Thus, conventions about the use of variables are required for experiments on drag and reconfiguration of freshwater macrophytes, otherwise the field will be plagued by a multitude of incomparable results.     

Three-dimensional CFD analysis of the hand and forearm in swimming

The purpose of this study was to analyze the hydrodynamic characteristics of a realistic model of an elite swimmer hand/forearm using three-dimensional computational fluid dynamics techniques. A three-dimensional domain was designed to simulate the fluid flow around a swimmer hand and forearm model in different orientations (0°, 45°, and 90° for the three axes Ox, Oy and Oz). The hand/forearm model was obtained through computerized tomography scans. Steady-state analyses were performed using the commercial code Fluent. The drag coefficient presented higher values than the lift coefficient for all model orientations. The drag coefficient of the hand/forearm model increased with the angle of attack, with the maximum value of the force coefficient corresponding to an angle of attack of 90°. The drag coefficient obtained the highest value at an orientation of the hand plane in which the model was directly perpendicular to the direction of the flow. An important contribution of the lift coefficient was observed at an angle of attack of 45°, which could have an important role in the overall propulsive force production of the hand and forearm in swimming phases, when the angle of attack is near 45°.     

The effect of swimmer's hand/forearm acceleration on propulsive forces generation using computational fluid dynamics

Propulsive forces generated by swimmers hand/forearm, have been studied through experimental tests. However, there are serious doubts as to whether forces quantified in this way are accurate enough to be meaningful. In order to solve some experimental problems, some numerical techniques have been proposed using Computational Fluid Dynamics (CFD). The main purpose of the present work was threefold. First, disseminate the use of CFD as a new tool in swimming research. Second, apply the CFD method in the calculation of drag and lift coefficients resulting from the numerical resolution equations of the flow around the swimmers hand/forearm using the steady flow conditions. Third, evaluate the effect of hand/forearm acceleration on drag and lift coefficients. For these purposes three, two-dimensional (2D), models of a right male hand/forearm were studied. A frontal model (theta = 90 degrees, Phi = 90 degrees) and two lateral models, one with the thumb as leading edge (theta = 0 degrees, = 90 degrees), and the other with the small finger as the leading edge (theta = 0 degrees, Phi = 180 degrees). The governing system of equations considered was the incompressible Reynolds averaged Navier-Stokes equations with the standard k-epsilon model. The main results reported that, under the steady-state flow condition, the drag coefficient was the one that contributes more for propulsion, and was almost constant for the whole range of velocities, with a maximum value of 1.16 (Cd = 1.16). This is valid when the orientation of the hand/forearm is plane and the model is perpendicular to the direction of the flow. Under the hand /forearm acceleration condition, the measured values for propulsive forces calculation were approximately 22.5% (54.440 N) higher than the forces produced under the steady flow condition (44.428 N). By the results, pointed out, we can conclude that: (i) CFD can be considered an interesting new approach for hydrodynamic forces calculation on swimming, (ii) the acceleration of hand/forearm provides more propulsion to swimmers, confirming that some unsteady mechanism must be present in swimming propulsion.     

Prediction of fluid forces acting on a hand model in unsteady flow conditions

The aim of this study was to develop a method to predict fluid forces acting on the human hand in unsteady flow swimming conditions. A mechanical system consisting of a pulley and chain mechanism and load cell was constructed to rotate a hand model in fluid flows. To measure the angular displacement of the hand model a potentiometer was attached to the axis of the rotation. The hand model was then fixed at various angles about the longitudinal axis of the hand model and rotated at different flow velocities in a swimming flume for 258 different trials to approximate a swimmer's stroke in unsteady flow conditions. Pressures were taken from 12 transducers embedded in the hand model at a sampling frequency of 200Hz. The resultant fluid force acting on the hand model was then determined on the basis of the kinetic and kinematic data taken from the mechanical system at the frequency of 200Hz. A stepwise regression analysis was applied to acquire higher order polynomial equations that predict the fluid force acting on the accelerating hand model from the 12 pressure values. The root mean square (RMS) difference between the resultant fluid force measured and that predicted from the single best-fit polynomial equation across all trials was 5N. The method developed in the present study accurately predicted the fluid forces acting on the hand model.     

Chemical Studies on the Antibiotic Esperin

Esperin is an acidic antibiotic with a molecular formula of C₃₉H₆₇N₅O₁₁ and, on hydrolysis with acid, it afforded l-aspartic acid, l-glutamic acid, l-valine, l-leucine, d-leucine and 2-tridecenoic acid. By treatment with alkali, esperin was transformed to esperinic acid, C₃₉H₆₉N₅O₁₂, which was shown to be β-hydroxytridecanoyl-glutamyl-aspartyl-valyl-leucyl-leucine. From chemical and physical studies, esperin was proved to be the lactone of esperinic acid, represented by the formula III.     

Flow-induced forces on free-floating macrophytes

Free-floating macrophytes have buoyant petioles and unanchored roots; certain species are highly invasive, owing to characteristics such as high growth rates and the formation of dense floating mats that drift on wind and water currents. Water hyacinth (Eichhornia crassipes) is one example; its invasion of tropical and subtropical freshwater systems worldwide harms native ecosystems and impedes human activities. This research examines flow-induced forces and biomechanical properties of E. crassipes to better understand flow interactions and transport mechanisms. Drag forces were measured in a flume and a wind tunnel for varying approach velocities and raft configurations; from this data, drag coefficients in water (C _D^w) and air (C _D^a) were developed. Over similar Reynolds number (Re _b ) regimes, C _D^w decrease as Re _b increases while C _D ^a are invariant. For the same raft tested in air and water, water drag exceeds air drag and the value of C _D^w approaches C _D^a at high Re _b . Force–velocity relationships indicate root canopies reconfigure by streamlining in higher flow velocities while leaf canopies do not. Root canopy streamlining is further explained through biomechanical testing: we found the major vegetative structures of E. crassipes (roots, stolons, and petioles) have similar moduli of elasticity but second moments of area are three orders of magnitude smaller in roots compared to stolons or petioles, leading to significantly lower flexural rigidity in roots than in stolons or petioles. Flow interactions with the root canopy differ for an individual plant compared to a raft assemblage. Laboratory results suggest that water currents are the dominant mechanism for E. crassipes dispersal.     

Influence of hydrodynamic forces on population structure of Pinna nobilis L., 1758 (Mollusca: Bivalvia): The critical combination of drag force, water depth, shell size and orientation

The effects of hydrodynamics on size, shape and distribution of benthic organisms are still not completely understood. Benthic organisms that inhabit wave-swept environments usually have small sizes and ethological adaptations to reduce drag and increase resistance force. Water speeds produced by waves in intertidal habitats can be more than 10 times higher than those in subtidal environments. However, comparatively small water speeds can produce high drag forces (F_d) on large subtidal organisms.Pinna nobilis is a subtidal epibenthic large bivalve-mollusc endemic to the Mediterranean Sea, a common inhabitant of Posidonia oceanica meadows. It lives partially buried in the seabed and shows a characteristic population structure. Small individuals are usually located at shallow sites whereas large individuals are only observed in deeper levels or sheltered locations. Also, some populations show a common orientation of the shell. These features are widespread throughout the Mediterranean, but their causes are unknown.The present work is a study on the relationship between population structure of P. nobilis and the habitat hydrodynamics. The main factor considered was Drag force due to the water flow produced by waves. Drag forces (F_d) supported by two populations located at different depths in the same P. oceanica meadow were estimated according to both the size and orientation of shells. Also, F_d acting on the individuals during the greatest storm recorded in the zone in the previous 9 years, were calculated. Drag coefficients (C_d), necessaries to estimate F_d, were estimated in the towing tank of the “Ecuela Técnica Superior de Ingenieros Navales (ETSIN)” of the Polytechnic University of Madrid.The results show significant differences in F_d acting in both populations. Despite the important increment of water speed with wave shoaling, individuals of the shallow population (SP), located at 6 m depth, withstand less F_d than those of the deep population (DP), at 13 m depth. The main reasons of this F_d reduction in SP are both the small size of the individuals and their common orientation, having the dorso-ventral side of the shell towards the main water flow. This fact, together with previous data showing higher mortality, less density of individuals, and less maximum asymptotic length, evidence that selective pressures regulate these population parameters, producing a trade-off between hydrodynamics, shell size and orientation, for each shore type and water depth.Combining the data of F_d supported by each population for different wave types, approximate values of the optimal mean F_d and the maximum dislodgement force withstood by P. nobilis were estimated (< 9 Newton (N) and ≈ 45 N respectively).     

Characterization of prolidase I and II purified from normal human erythrocytes: comparison with prolidase in erythrocytes from a patient with prolidase deficiency

The effect of various sulfur-containing amino acids on the activities of prolidase isoenzymes I and II isolated from erythrocytes of healthy individuals, and erythrocyte lysates from a patient with prolidase deficiency was investigated. The activity of prolidase I against glycylproline was strongly enhanced by d-methionine. l-Methionine and d,l-methionine slightly enhanced the activity at low concentration, but N-acetyl-l-methionine had no effect. d-Ethionine, l-ethionine, and d,l-ethionine also enhanced the activity of prolidase I. d,l-Homocysteine enhanced the activity at low concentration, but inhibited the activity at 50 mM. The activity of prolidase II against methionylproline was enhanced by d-methionine, d,l-methionine, and l-methionine, but N-acetyl-l-methionine had no effect. d-Ethionine and d,l-ethionine strongly enhanced the activity of prolidase II compared with l-ethionine; d,l-homocysteine weakly enhanced the activity. d,l-Homocysteine-thiolactone inhibited the activities of prolidase I and II in a concentration-dependent manner. The effect of various sulfur-containing amino acids on prolidase activity against methionylproline in erythrocyte lysates from a patient with prolidase deficiency was almost the same as that on prolidase II. The kinetics of the activities of prolidase I, II, and patient prolidase were also studied. Their K _m values were changed by adding sulfur-containing amino acids, but V _max values were unchanged.     

In situ kinetic measurements of d -amino acid oxidase in rat liver with respect to its substrate specificity

Summary d-Amino acid oxidase activity was demonstrated in peroxisomes of rat liver using unfixed cryostat sections and a histochemical technique using cerium ions as capture reagent for hydrogen peroxide and diaminobenzidine, cobalt ions and exogenous hydrogen peroxide to visualize the final reaction product for light microscopical analysis. Cytophotometric analysis of liver sections revealed similar zero-order reaction velocities of d-amino acid oxidase with activity twice as high in periportal areas as in pericentral areas of liver lobuli when using either d-proline or d,l-thiazolidine-2-carboxylic acid as substrates. On the other hand, a 4–5 times higher K _M value was found for d-proline than for d,l-thiazolidine-2-carboxylic acid. The K _M values in periportal and pericentral areas were similar for each substrate. These findings support the suggestion that the physiological substrate for d-amino acid oxidase may be d,l-thiazolidine-2-carboxylic acid, the adduct of cysteamine and glyoxylic acid. d-Amino acid oxidase may play a role in vivo in the production of oxalate which may participate in metabolic control processes as an intracellular messenger molecule.     

Biosynthesis and metabolism of l-ascorbic acid in virginia creeper (Parthenocissus quinquefolia L.)

Detached leaves of Parthenocissus quinquefolia L., Vitaceae convert d-glucose to l-ascorbic acid with conservation of the carbon chain sequence and with retention of the hydroxymethyl group at carbon 6. l-Ascorbic acid is cleaved between carbons 4 and 5. The C₄ fragment is converted to l-tartaric acid. The C₂ fragment, possibly glycolaldehyde, recycles into products of hexose phosphate metabolism. During the metabolic period a relatively high portion of carbon-1 of l-ascorbic acid, as compared with carbon-4, was released as CO₂. These studies demonstrate the usefulness of Virginia Creeper for yeararound research on ascorbic-acid metabolism and tartaric-acid biosynthesis in Vitaceae-type plants.Abbreviation AA l-Ascorbic Acid     

Propulsive forces on the flagellum during locomotion of Chlamydomonas reinhardtii

The distributed propulsive forces exerted on the flagellum of the swimming alga Chlamydomonas reinhardtii by surrounding fluid were estimated from experimental image data. Images of uniflagellate mutant Chlamydomonas cells were obtained at 350 frames/s with 125-nm spatial resolution, and the motion of the cell body and the flagellum were analyzed in the context of low-Reynolds-number fluid mechanics. Wild-type uniflagellate cells, as well as uniflagellate cells lacking inner dynein arms (ida3) or outer dynein arms (oda2) were studied. Ida3 cells exhibit stunted flagellar waveforms, whereas oda2 cells beat with lower frequency. Image registration and sorting algorithms provided high-resolution estimates of the motion of the cell body, as well as detailed kinematics of the flagellum. The swimming cell was modeled as an ellipsoid in Stokes flow, propelled by viscous forces on the flagellum. The normal and tangential components of force on the flagellum (f_N and f_T) were related by resistive coefficients (C_N and C_T) to the corresponding components of velocity (V_N and V_T).The values of these coefficients were estimated by satisfying equilibrium requirements for force and torque on the cell. The estimated values of the resistive coefficients are consistent among all three genotypes and similar to theoretical predictions.     

Purification and properties of D-gluconate dehydratase fromAchromobacter

d-Gluconate dehydratase fromAchromobacter, grown ond-gluconate, was purified 100-fold by a procedure involving ammonium sulfate fractionation and preparative acrylamide gel electrophoresis. The purified enzyme appeared to be homogeneous by disc gel electrophoresis. It is an inducible enzyme with an optimal activity in the pH region 8.4–8.8, a Km value of 2.08 × 10^–2 m ford-gluconate and a molecular weight of 270,000 ± 25,000. Only C₅ and C₆ aldonic acids possessing al-threo configuration at C₂ and C₃ are dehydrated. The dehydration products ofd-gluconate,d-xylonate,d-galactonate,d-fuconate andl-arabonate were identified as 2-keto-3-deoxy compounds by specific colour reactions and thin layer chromatography. Onemm Mg^{+ +} is a powerful activator, 0.1 mm Mn^{+ +} activates poorly and EDTA inhibits. Glutatione, dithiothreitol and mercaptoethanol had no effect, althoughp-chloromercuribenzoate (0.01 mm) decreased enzyme activity.We wish to thank Mr D. Dewettinck for skilful technical assistance. The senior author (J.D.L.) is indebted to the Fonds voor Kollektief en Fundamenteel Onderzoek (Belgium) for research and personnel grants. J.K.-M. is indebted to the Belgian government for a travel and study grant.     

Dose-dependent significance of monosaccharides on intracellular α-l-rhamnosidase activity from Pseudoalteromonas sp.

Intracellular α-l-rhamnosidase (EC 3.2.1.40) from the psychrotolerant Pseudoalteromonas sp. 005NJ showed a dose-dependent inhibition for l-rhamnose (IC₅₀ = 20 mM) and d-ribose (IC₅₀ = 95 mM), whereas d-glucose and l-fucose presented a lower inhibition, with IC₅₀ values as high as >0.5 and >0.2 M, respectively. On the other hand, d-fructose enhanced enzyme activity threefold, reaching a plateau of maximum specific activity between 0.2 and 0.4 M of this monosaccharide. Both effects, low inhibition and stimulation, caused by key fruit sugars (glucose and fructose), make this biocatalyst an interesting system in terms of its potential application for debittering fruit juices.     

A Model to Estimate Potential Submersed Aquatic Vegetation Habitat Based on Studies in Lake Pontchartrain, Louisiana

The depth distribution of submersed aquatic vegetation (SAV) was studied in Lake Pontchartrain, Louisiana, to develop a model to predict changes in SAV abundance from changes in environmental quality. We conducted annual line‐intercept surveys from 1997 through 2001 and monitored monthly photosynthetically active radiation at four sites with different shoreface slopes. The following relationships between SAV distribution and environmental factors were used as model parameters: (1) water clarity controls SAV colonization depth; (2) fluctuation in annual mean water level and wave mixing determines SAV minimum colonization depth; and (3) site differences in SAV areal coverage under the comparable water quality conditions are due to shoreface slope differences. These parameters expressed as mathematical components of the model are as follows: mean water clarity determines SAV colonization depth (Z_max= 2.3/K_d); mean water level and wave mixing controls SAV minimum depth (Z_min= 0.3 m); and shoreface slope angle (θ) determines the distance from Z_min to Z_max. The equation developed for the potential SAV habitat (PSAV) model is PSAV = (2.3 ? 0.3 ×K_d)/(sinθ×K_d). The model was validated by comparing empirical values from the dataset to values predicted by the model. Although the model was developed to predict the PSAV in Lake Pontchartrain, it can be applied to other coastal habitats if local SAV light requirements are substituted for Lake Pontchartrain values. This model is a useful tool in selecting potential restoration sites and in predicting the extent of SAV habitat gain after restoration.     

Nocturnal and seasonal patterns of carbon isotope composition of leaf dark-respired carbon dioxide differ among dominant species in a semiarid savanna

The C isotope composition of leaf dark-respired CO₂ (δ¹³C_l) integrates short-term metabolic responses to environmental change and is potentially recorded in the isotopic signature of ecosystem-level respiration. Species differences in photosynthetic pathway, resource acquisition and allocation patterns, and associated isotopic fractionations at metabolic branch points can influence δ¹³C_l, and differences are likely to be modified by seasonal variation in drought intensity. We measured δ¹³C_l in two deep-rooted C₃ trees (Prosopis velutina and Celtis reticulata), and two relatively shallow-rooted perennial herbs (a C₃ dicot Viguiera dentata and a C₄ grass Sporobolus wrightii) in a floodplain savanna ecosystem in southeastern Arizona, USA during the dry pre-monsoon and wet monsoon seasons. δ¹³C_l decreased during the nighttime and reached minimum values at pre-dawn in all species. The magnitude of nocturnal shift in δ¹³C_l differed among species and between pre-monsoon and monsoon seasons. During the pre-monsoon season, the magnitude of the nocturnal shift in δ¹³C_l in the deep-rooted C₃ trees P. velutina (2.8 ± 0.4‰) and C. reticulata (2.9 ± 0.2‰) was greater than in the C₃ herb V. dentata (1.8 ± 0.4‰) and C₄ grass S. wrightii (2.2 ± 0.4‰). The nocturnal shift in δ¹³C_l in V. dentata and S. wrightii increased to 3.2 ± 0.1‰ and 4.6 ± 0.6‰, respectively, during the monsoon season, but in C₃ trees did not change significantly from pre-monsoon values. Cumulative daytime net CO₂ uptake was positively correlated with the magnitude of the nocturnal decline in δ¹³C_l across all species, suggesting that nocturnal δ¹³C_l may be controlled by ¹³C/¹²C fractionations associated with C substrate availability and C metabolite partitioning. Nocturnal patterns of δ¹³C_l in dominant plant species in the semiarid savanna apparently have predictable responses to seasonal changes in water availability, which is important for interpreting and modeling the C isotope signature of ecosystem-respired CO₂.     

Quasielastic light scattering from solutions of lollipop-shaped particles

An expression is derived for the field correlation function of the light scattered from a solution of lollipop-shaped particles. Such particles are a tractable model of certain bacteriophages. They are assumed to consist of an ellipsoidal head containing optically anisotropic scattering material and a tail which does not scatter. Because of the tail, Brownian rotational movement occurs around a center of rotational friction which is at a distance r₀ from the center of the head. The dependence of the field correlation function C(τ) on the rotational diffusion coefficient D_R is given by the factor Σ_lB_l exp[?l(l + 1)D_Rτ]. It is shown that the tail causes the coefficients B_l to be different from zero for all values of l. Therefore, C(τ) contains a term proportional to exp(?2D_Rτ), which is not present when r₀ = 0. We give plots of B_l for various combinations of parameters. It turns out that dynamic light scattering may be used to measure r₀.     

Enzymatic production of l-phenylalanine from the racemic mixture of d,l-phenyllactate

Summary The production of l-phenylalanine from the racemate d,l-phenyllactate in an enzyme membrane reactor has been examined. In a first step the racemate is dehydrogenated to the prochiral intermediate phenylpyruvate by the enzymes d-and l-hydroxyisocaproate dehydrogenase. In a second step phenylpyruvate is reductively aminated to l-phenylalanine by l-phenylalanine dehydrogenase. Both steps are dependent on coenzyme, the first one requires NAD, the second one NADH in stoichiometric amounts; in this way the coenzyme is regenerated and only required catalytically. The coenzyme is covalently bound to polyethylene glyco-20 000 and can thus be retained in the reactor analogously to the three enzymes. In order to optimize the continuous production of l-phenylalanine from d,l-phenyllactate, models of the reaction kinetics and of the reactor system have been set up. By means of the reactor model, we can calculate the optimum ratio of the three enzymes, the optimum coenzyme concentration and the optimum phenylpyruvate concentration in the feed.In this process, at a substrate concentration of 50 mM d,l-phenyllactate we reached a spacetime-yield of 28 g l-Phe/(l*d).Abbreviations PEG polyethylene glycol - d-HicDH d-hydroxyisocaproate dehydrogenase - l-HicDH l-hydroxyisocaproate dehydrogenase - PheDH l-phenylalanine dehydrogenase - V _max maximum velocity - K _M Michaelis-Menten constant - K _l inhibition constant - R₁ reaction rate of the d-HicDH forward reaction - R₂ reaction rate of the d-HicDH reverse reaction - R₃ reaction rate of the l-HicDH forward reaction - R₄ reaction rate of the l-HicDH reverse reaction - R₅ reaction rate of the PheDH forward reaction - R₆ reaction rate of the PheDH reverse reaction - d-PLac d-phenyllactate - l-PLac l-phenyllactate - PPy phenylpyruvate - l-Phe l-phenylalanine - NH₄ ammonium - residence time     

Compositae Plants Differed in Leaf Cuticular Waxes between High and Low Altitudes

We sampled eight Compositae species at high altitude (3482 m) and seven species at low altitude (220 m), analyzed the chemical compositions and contents of leaf cuticular wax, and calculated the values of average chain length (ACL), carbon preference index (CPI), dispersion (d), dispersion/weighted mean chain length (d/N), and C₃₁/(C₃₁ + C₂₉) (Norm31). The amounts of total wax and compositions were significantly higher at high altitude than at low altitude, except for primary alcohol, secondary alcohol, and ketone. The main n‐alkanes in most samples were C₃₁, C₂₉, and C₃₃. Low altitude had more C₃₁ and C₃₃, whereas more C₂₉ occurred at high altitude. The ACL, CPI, d, d/N, and Norma 31 were higher at low altitude than at high altitude. The fatty acid and primary alcohol at low altitude contained more C₂₆ homologous than at high altitude. More short‐chain primary alcohols were observed at high altitude. At low altitude, the primary alcohol gave on average the largest amount, while it was n‐alkane at high altitude. These results indicated that the variations of leaf cuticular waxes benefited Compositae plants to adapt to various environmental stresses and enlarge their distribution.     

Molecular modelling as a tool for studying the disassembly of potentially leishmanicide-targeted dendrimer

Molecular modelling studies were carried out to analyse which carbonyl group is the most vulnerable to the disassembly of potentially leishmanicide-targeted dendrimer. The dendrimers were designed using myo-inositol (core and directing group), d-mannose (directing group), l-malic acid (spacer and dendron) and hydroxymethylnitrofurazone (NFOH) as a bioactive agent. The molecular models were built containing one, two and three branches. For this preliminary analysis, physicochemical properties, such as electronic density distribution and steric hindrance regarding the carbonyl groups were evaluated, and the carbon atoms in the following carbonyl groups were considered: near the core (C₁), close to the directing group (C₂), in l-malic acid (C₃) and near the bioactive agent (C₄). The most probable targeted dendrimers showed the carbonyl close to the core as the most susceptible to a nucleophilic attack, except those molecular systems containing two branches with d-mannose as the directing group, which displayed the carbonyl group near NFOH as the most likely ester breaking point.     

Antitumor activity of titanocene amino acid complexes

Seven ionic titanocene -amino acid (aa) complexes [(C₅H₅)₂Ti(aa)₂]²⁺[X]₂ ^– with aa = glycine,l-alanine, 2-methylalanine,d-l-phenylalanine,d,l-4-fluorophenylalanine and X = Cl or AsF₆, were investigated for antitumor activity against fluid Ehrlich ascites tumor growing in CF1 mice. These complexes are the first stable model compounds of titanocene units with protein components, synthesized from a water-like, methanolic medium. All titanocene amino acid complexes induced antitumor activity which was manifested by maximum cure rates ranging from 30 to 70% and increases in life span from 78 to 276% in comparison with untreated control animals. The complexes containing chloride as anion X were more effective than the hexafluoroarsenate derivatives, which surprisingly showed a low substance toxicity. In all cases, the antitumor activity of the ionic titanocene amino acid complexes tested was less pronounced than that of the neutral parent compound [(C₅H₅)₂TiCl₂].