Meta-hologram-based authentication scheme employing a speckle pattern fingerprint.

A concept for an optical holographic security tag is proposed and demonstrated. When illuminated with a laser beam, the image scattered from the tag projects a Quick Response code which encodes identifying information. The image also carries pseudorandom speckle noise, from which a unique speckle pattern "fingerprint" is derived. We show numerically that the tag is unclonable without access to a secret key - the starting conditions of the design algorithm. However, given the key, it is straightforward to reproduce a tag exhibiting the expected fingerprint. Several tags have been realized, implemented as plasmonic meta-holograms, and characterized experimentally. The robustness of the tag to fabrication error and its resilience to counterfeiting are studied in detail and demonstrated experimentally.

Toward Hyperpolarization of Oil Molecules via Single Nitrogen Vacancy Centers in Diamond.

Efficient polarization of organic molecules is of extraordinary relevance when performing nuclear magnetic resonance (NMR) and imaging. Commercially available routes to dynamical nuclear polarization (DNP) work at extremely low temperatures, relying on the solidification of organic samples and thus bringing the molecules out of their ambient thermal conditions. In this work, we investigate polarization transfer from optically pumped nitrogen vacancy centers in diamond to external molecules at room temperature. This polarization transfer is described by both an extensive analytical analysis and numerical simulations based on spin bath bosonization and is supported by experimental data in excellent agreement. These results set the route to hyperpolarization of diffusive molecules in different scenarios and consequently, due to an increased signal, to high-resolution NMR.

Detecting and polarizing nuclear spins with double resonance on a single electron spin.

We report the detection and polarization of nuclear spins in diamond at room temperature by using a single nitrogen-vacancy (NV) center. We use Hartmann-Hahn double resonance to coherently enhance the signal from a single nuclear spin while decoupling from the noisy spin bath, which otherwise limits the detection sensitivity. As a proof of principle, we (i) observe coherent oscillations between the NV center and a weakly coupled nuclear spin and (ii) demonstrate nuclear-bath cooling, which prolongs the coherence time of the NV sensor by more than a factor of 5. Our results provide a route to nanometer scale magnetic resonance imaging and novel quantum information processing protocols.

Band splitting and modal dispersion induced by symmetry braking in coupled-resonator slowlight waveguide structures.

We study the dispersion relations in slow-light waveguide structures consisting of coupled microdisk resonators. A group theoretical analysis of the symmetry properties of the propagating modes reveals a fundamental phenomenon: The degeneracy of the CW and CCW rotating modes is removed, giving rise to two distinct transmission bands. This effect induces symmetry-based dispersion which may limit the usable bandwidth of such structures. The properties of this band splitting and its impact on CROW performance for optical communications are studied in detail.

Troponin-tropomyosin abnormalities in hamster cardiomyopathy.

Cardiac myofibrils from cardiomyopathic hamsters exhibit elevated Mg2+ ATPase activity and a parallel upward shift of the calcium ATPase dose response curve. To explore the mechanism, myofibrils from control and cardiomyopathic hamster hearts were incubated with isolated troponin-tropomyosin complex (Tn.Tm) from cardiomyopathic and control hamster or from dog hearts. Tn.Tm from control hamster or dog hearts restored normal Mg2+ ATPase activities to myofibrils from myopathic hearts. However, the maximum ATPase response to calcium stimulation was less in cardiomyopathic myofibrils compared to controls, even when control Tn.Tm was included. Electrophoretic patterns of Tn.Tm from myopathic and control hearts were similar. Electrophoresis of the hamster myofibrils mixed with dog cardiac Tn.Tm and then washed demonstrated binding of this complex to myopathic myofibrils. To further confirm that the incubation experiments resulted in binding, 125I troponin-tropomyosin was cross-hybridized with myofibrils, extensively washed, and then analyzed enzymatically and autoradiographically. Autoradiograms demonstrated similar percent binding of 125I Tn.Tm to all myofibrillar preparations and enzymatic effects like those found using cold Tn.Tm. These studies suggest that Tn.Tm from cardiomyopathic hearts inhibits Mg2+ myofibrillar ATPase activity to a lesser degree than Tn.Tm from control hearts. Decreased stimulation by calcium in myopathic preparations may be due to abnormalities in troponin-tropomyosin and/or to the decreased myosin ATPase activity observed previously.

The effect of physical training upon the mechanical and metabolic performance of the rat heart.

The dynamic and metabolic performance of rats conditioned by a swimming program (CH) and hearts of sedentary rats (SH) was studied in an isolated working rat heart apparatus. Heart rate, filling pressure, and afterload were controlled or kept constant, and heart weights were comparable in both groups. When compared with SH, CH had increased cardiac output and cardiac work. Atrial pacing at more rapid rates caused greater differences in these functions, and left ventricular pressure and maximal rate of pressure rise (dp/dt) became higher in CH than in SH. Atrial pacing was associated in CH with increased oxygen consumption but in SH by increased lactate and pyruvate production. When atrial filling pressure was elevated in order to perform ventricular function curves, CH showed greater dynamic responses than SH. There were also greater increments in oxygen consumption, and the ratio of aerobic to anaerobic energy production was also higher in CH. The mechanism of increasing oxygen consumption during stress in CH was mainly by improved coronary flow. In SH coronary flow did not change, but extraction of oxygen from the perfusing fluid increased. The results indicate that in physically trained rats the function of the heart as a pump is improved. These hearts have greater aerobic and mechanical reserve than hearts of sedentary animals. These effects appear to be at least partially due to improved mechanisms of oxygen delivery.

Physiologic cardiac hypertrophy corrects contractile protein abnormalities associated with pathologic hypertrophy in rats.

To evaluate the combined effects of cardiac overload imposed by hypertension and by chronic exercise, male and female rats were made hypertensive by unilateral renal artery stenoses and made to exercise in an 8-10-wk swimming program. Sedentary normotensive animals, sedentary hypertensive animals and normotensive animals exposed to the swimming program were also studied. Hypertension was associated with the development of cardiac hypertrophy, and this was exaggerated in hypertensive swimmers. Actomyosin, Ca2+-myosin, and actin-activated Mg2+-myosin ATPase activities were enhanced in normotensive swimmers, depressed in hypertensives and were normal or increased in hypertensive swimmers. Myosin isoenzyme analysis showed a predominant V1 pattern in normals; an increase in percent V1 isoenzyme is swimmers; a predominant V3 pattern in hypertensives; and a return to the predominant V1 pattern in hypertensive swimmers. These findings suggest that the hypertrophy imposed by hypertension and hypertrophy imposed by physical training using a chronic swimming program are distinctly different biological phenomena. Physical training by swimming prevents the changes in cardiac myosin induced by hypertension despite the exaggeration of hypertrophy.

Cardiac conditioning ameliorates cardiac dysfunction associated with renal hypertension in rats.

To explore the effect of physiologic hypertrophy superimposed on pathologic hypertrophy, hearts from female control rats (C), renal hypertensive rats (H), rats conditioned with a 10-12 wk swimming program (Sw), and hypertensive rats trained by the swimming program (H-Sw) were perfused in an isolated working rat-heart apparatus. Systolic blood pressure was approximately 100 mmHg in C and Sw and was 160 mmHg in H and H-Sw. The swimming program had no effect on blood pressure. Compared with C, heart weight was increased by 30% in Sw, 47% in H, and 77% in H-Sw. At high preload and afterload, cardiac output (milliliters per gram dry LV weight) was decreased in H, increased in Sw, and partially restored towards normal in H-Sw. Ejection fraction, percent fractional shortening, and mean velocity of circumferential fiber shortening were enhanced in Sw, depressed in H, and normalized in H-Sw when compared with C. Coronary flow and myocardial oxygen consumption in this series of hearts were depressed in H, with no restoration in H-Sw, but coronary effluent lactate/pyruvate ratios were only elevated in the hearts of H-Sw. Coronary vascular responses were examined in a second series of experiments which used microspheres. In this series, the depressed coronary flow observed in H was partially restored towards normal in H-Sw and the inner/outer myocardial flow ratio was normal when hearts were perfused at 140 cm aortic pressure but was somewhat depressed in both H and H-Sw when the hearts were perfused at 80 cm aortic pressure. These studies demonstrate that hypertrophic hearts from renal hypertensive rats have diminished coronary flow and depressed cardiac function when they are studied in the isolated working heart apparatus, yet there is no evidence of myocardial ischemia. Superimposition of a chronic swimming program results in increased hypertrophy but restoration of cardiac function partially or completely to normal. Thus, pathologic and physiologic hypertrophy are biologically distinct entities. Physiologic hypertrophy may partially ameliorate the defects associated with pathologic hypertrophy.

Effects of experimental diabetes on adrenergic and cholinergic receptors of rat myocardium.

To more fully characterize the alterations in myocardial adrenergic and cholinergic receptors induced by the diabetic state, we investigated the binding characteristics of (--) [3H] dihydroalprenolol to beta adrenergic receptors (bAR), [3H] prazosin to alpha adrenergic receptors (aAR), and [3H] quinuclidinyl-benzilate to muscarinic cholinergic receptors (MCR) in myocardial membranes derived from rats 8 wk after treatment with streptozotocin. We also studied an equal number of animals from three control groups: free-eating nondiabetics, pair-weighted nondiabetics, and streptozotocin-treated animals treated daily with insulin. Diabetic hearts demonstrated 27% fewer bAR (P less than 0.01) and 31% fewer aAR (P less than 0.01) than free-eating controls, without changes in MCR, and without changes in antagonist affinity, agonist affinity, or agonist slope factor (pseudo-Hill coefficient) for any class of receptors. Food restriction had no effect on receptor characteristics, and treatment of diabetic rats with insulin prevented any downregulation of cardiac bAR or aAR. The parallel decrease in both bAR and aAR suggests that streptozotocin-induced hypothyroidism is not the primary causative factor of bAR downregulation in this model, since hypothyroidism produces upregulation of aAR. Furthermore, the lack of change in cardiac MCR suggests that the adrenergic receptor alterations are not the result of nonspecific abnormalities of protein synthesis in the diabetic heart. Further studies are required to establish the physiologic significance of these receptor alterations, but these data support the hypothesis that altered adrenergic receptor properties may underlie, at least in part, the chronotropic and inotropic abnormalities of cardiac performance that are associated with the diabetic state.

Prevention of hereditary cardiomyopathy in the Syrian hamster with chronic verapamil therapy.

The cardiomyopathic Syrian hamster develops genetically determined cardiac necrosis that invariably leads to premature death from congestive heart failure or arrhythmia. This hamster is a valuable model of human disease because it has many features in common with clinical dilated, congestive cardiomyopathy. Previous studies have shown that therapy for several weeks with the calcium channel blocking drug verapamil or the alpha-1 adrenoceptor blocking drug prazosin can prevent myocardial necrosis due to microvascular spasm. Other investigations have demonstrated the positive effects of verapamil in the early stages of disease. It is not clear, however, whether continued treatment can prevent the long-term expression of the cardiomyopathy or whether the disease is genetically predetermined. To address this question, hamsters were treated with oral verapamil for 7 to 8 months during the necrotizing, compensatory hypertrophy and early failure stages of disease. Analysis of myocardial pathologic and biochemical variables demonstrated that continuously treated animals were generally similar to unaffected control hamsters; discontinuous therapy led to partial protection. These findings demonstrate that virtually complete prevention of this hereditary disease is feasible; these results may have important implications for the treatment of human cardiomyopathy.

Ventricular function and contractile proteins in the infarcted overloaded rat heart.

STUDY OBJECTIVE: The aim was to determine whether surviving myocardium in the infarcted rat heart retains the ability to respond to sustained increases in afterload. DESIGN: Cardiac mass, ventricular function, and actomyosin ATPase activity were compared in animals subjected to coronary artery ligation to produce infarction, superimposed renal artery constriction 4 weeks after infarction, and in sham operated animals. EXPERIMENTAL MATERIAL: Female Wistar rats obtained at 10 weeks of age (200-225 g) were used for the studies. MEASUREMENTS AND MAIN RESULTS: Four weeks after coronary artery ligation, infarcted hearts showed a 22% increase in heart weight and a significant reduction in peak systolic pressure and +/- dP/dt during acute volume infusion and aortic occlusion compared to sham operated hearts. Eight weeks after the initial surgical intervention, the infarct group showed significant impairment in ventricular performance compared to the sham operated group but no further decrement was observed between hearts with infarction and those with infarct and superimposed renal artery constriction for peak systolic pressure and +/- dP/dt during volume infusion and aortic occlusion. Actomyosin ATPase activity, however, was depressed and the shift to V3 myosin isoenzyme was greater in infarct and renal artery constriction compared to infarct alone. CONCLUSIONS: Left ventricular myocardium following infarction does not retain the ability to increase cardiac mass and shows depressed levels of actomyosin ATPase activity when exposed to a superimposed chronic afterload from renal artery constriction. However, cardiac function in situ is maintained.

Impaired coronary flow and ventricular function in hearts of hypertensive rats.

Hearts of rats made hypertensive (BP greater than 150 mmHg) by left renal artery clipping and sham operated controls were studied in two series of experiments. In series I, cardiac function was studied in an isolated working heart apparatus at weeks 4, 9 to 10 and 16 to 17 post-surgery. In series II, coronary flow was studied during normoxic and anoxic retrograde perfusions at days 6 to 9 and at weeks 4 and 10 post-surgery. In series I, when compared with controls, hypertensives had lower body weights at weeks 4 and 9 to 10, and higher left ventricular weights at each period. Heart function was depressed for hypertensives when compared with controls as measured by lower stroke volume, peak left ventricular systolic pressure, stroke work, ejection fraction, positive dP/dt, peak aortic flow, and maximal flow acceleration. Relaxation rate as measured by negative dP/dt was also depressed. Hearts from hypertensives had significantly lower coronary flows and MVO2, and increased percent oxygen extraction and effluent lactate/pyruvate ratios. LVEDP was significantly elevated for hypertensives, when LVEDV (ml) was similar for hypertensives and controls. Myocardial actomyosin ATPase activity was depressed for hypertensives at weeks 9 to 10 and 16 to 17 post-surgery. In series II, when hearts were perfused retrogradely, coronary flow was lower for hypertensives than for controls during normoxia at days 6 to 9 and at week 4, and during anoxia at all time periods. The findings demonstrate that impaired coronary vascular reserve develops within days of the development of hypertension in rats, and this can be associated with impaired ventricular function.

Catecholamines in cardiac hypertrophy.

There has been intense interest in the roles catecholamines may play in compensatory myocardial hypertrophy. This article reviews the following: (1) chronic infusions of catecholamines in experimental animals result in cardiac hypertrophy, but in many of the studies mechanical factors have played a role; (2) experiments using isolated papillary muscles and isolated hearts, stretched isolated myocytes, and denervated hearts in vivo demonstrate that mechanical activity is sufficient to cause increased protein synthesis and cell growth; (3) in neonatal myocyte cell cultures, alpha-adrenergic agonists are powerful stimulants for protein synthesis and cell growth. Beta-adrenergic stimulation of nonmyocyte myocardial cells causes release of a factor that promotes protein synthesis in neonatal myocytes. Either alpha or beta stimulation, probably through different mechanisms, appears to have growth-promoting effects on isolated adult myocytes in culture; (4) alpha stimulation is transduced through the Gq pathway and its activation of phospholipase C, cleavage of phosphatidylinositol (4,5)-bisphosphate, and then further through the ras/raf, mitogen-activated protein (MAP) kinase system; (5) transgenic mice with upregulation of catecholamine-related systems have not clarified the independent role of either the alpha- or beta-adrenergic pathway; and (6) observations in humans suggest that mechanical factors predominate in the development and regression of cardiac hypertrophy. Humoral mechanisms, including catecholamines, may play a role, but their quantitative importance has not been determined. It is hypothesized that catecholamines may play a role in transition from the adaptive to the maladaptive state.

Radionuclide ventriculographic study of adaptations to exercise in aortic regurgitation.

Exercise-gated radionuclide ventriculography has been proposed as a method to evaluate cardiac reserve in patients with aortic regurgitation (AR). Characterization of ventricular function, however, in AR is complicated by the dynamic nature of the leak in individual patients and by variations in severity among patients. Twenty patients with isolated AR were studied to assess the effects of exercise on the regurgitant index. The regurgitant index (left ventricular divided by right ventricular stroke counts) estimates the severity of the leak. The regurgitant index at rest was significantly higher in patients with AR than in patients without AR (3.46 +/- 1.25 versus 1.08 +/- 0.16, p less than 0.001). In patients with AR, the regurgitant index decreased during exercise to 2.6 +/- 0.8 (p less than 0.001), whereas it did not change in the control group (1.16 +/- 0.21, difference not significant). Further, in patients with AR, the greater the regurgitant index at rest, the greater the decrease during exercise (y = 0.56x -- 1.08, r = 0.78, p less than 0.001). End-diastolic counts and stroke count responses from rest to exercise were highly variable, but were explained in part by the decreasing regurgitant index. These data support previous catheterization studies and confirm gated radionuclide ventriculography as a useful tool for monitoring adaptations to exercise in AR.

Radionuclide ventriculographic responses to graded supine and upright exercise: critical role of the Frank-Starling mechanism at submaximal exercise.

To assess the influence of work load and posture on the response to exercise, 25 patients with coronary artery disease (CAD) and 17 normal subjects underwent graded supine and upright exercise radionuclide ventriculography. In both groups, end-diastolic counts increased with supine exercise (p less than 0.001). The ejection fraction and peak systolic pressure-end-systolic volume relation increased in normal subjects (p less than 0.02), but not in patients with CAD. At upright rest, end-diastolic counts decreased in both groups (p less than 0.001) and then increased with exercise (p less than 0.001). The increase in end-diastolic counts was most pronounced on the transition from upright rest to the 150-kpm work load and resulted in a significant increase in stroke counts (p less than 0.05) for both patients with CAD and normal subjects, without a measurable change in the ejection fraction or the peak systolic pressure-end-systolic volume relation. Later in exercise, end-diastolic counts plateaued, and the ejection fraction and the peak systolic pressure, end-systolic volume relation increased only among normal subjects. Thus, low-level upright exercise is highly dependent on the Starling mechanism in both normal subjects and patients with CAD, with enhanced contractility apparent only during more vigorous exercise in normal subjects.

The evaluation of ischemic heart disease thallium-210 with comments on radionuclide angiography.

Coronary artery disease causing myocardial ischemia and infarction is the leading cause of death in America. Methods that can be used to diagnose and follow the response to therapy of coronary artery disease or its effect on myocardial ischemia should help control the morbidity and mortality of ischemic heart disease. The use of ECG monitoring is less sensitive and specific for ischemia than thallium (TI) imaging or the use of radionuclide angiography (RNA). In large patient populations, the findings of a positive ECG and TI or RNA study will be highly predictive for the presence of coronary artery disease, while negative test results make the disease unlikely. A combined approach to the patient with possible ischemic heart disease is presented.

Cardiovascular and hormonal responses to swimming and running in the rat.

Hemodynamic and hormonal responses were studied during swimming (SW) and running (R) and in cage-confined (C) female Wistar rats at base line and 4 and 8 wk of training. Myocardial tissue levels of norepinephrine (NE) and epinephrine (EPI) were also measured at the end of 8 wk of training. Mean arterial blood pressure (BP), heart rate (HR), and blood samples for arterial lactate, plasma NE and EPI, and blood gases were obtained at rest and at 20, 40, and 60 min of exercise. After 4 wk of SW, a resting bradycardia was observed, and HR response for the remaining 4 wk was attenuated with SW compared with HR during R. BP and blood gases remained unchanged between the two groups. R resulted in increased arterial lactate concentrations compared with C and SW at base line but was not different from SW at 4 wk. SW elicited higher plasma levels of NE and EPI compared with C at base line and C and R at 4 wk. Myocardial tissue NE and EPI concentrations were markedly increased in both the left and right ventricle of the SW group compared with both R and C. These results indicate that BP and blood gases are not different between chronic R and SW and suggest a possible sympathoadrenal role in the differences observed in cardiac adaptations between R and SW.

Effects of systolic overload and swim training on cardiac mechanics and biochemistry in rats.

We have previously shown that swim conditioning corrects the depressed mechanical function and myosin adenosinetriphosphatase (ATPase) activities associated with renovascular hypertension (HTN) in the rat. The present study was designed to assess the effects of swim conditioning on another form of systolic overload, subdiaphragmatic suprarenal aortic stenosis. Cardiac mechanics in an isolated working heart apparatus and myosin enzymology were studied in four groups of rats: controls (C), animals with chronic systolic overload secondary to aortic constriction (St), swim-conditioning animals (Sw), and animals exposed to a combined load (St-Sw). Heart weight was increased by 23% in St, 27% in Sw, and 36% in St-Sw. In contrast to HTN, cardiac pump and muscle function were not depressed in St. Sw was associated with improved cardiac output, stroke work, and velocity of circumferential fiber shortening. St-Sw showed improved mechanical cardiac performance relative to both C and St. The percent of ventricular myosin of the V1 type and Ca2+-activated myosin ATPase activity relative to C was unchanged in Sw but was depressed in St and St-Sw. These data demonstrate that the salutory mechanical effects of Sw can be superimposed on the systolic overload of St. However, the dissociation between mechanics and myosin enzymology suggests that factors in excitation-contraction coupling other than myosin isoenzyme shifts are responsible for this finding.

Combined effects of hypertension and conditioning on coronary vascular reserve in rats.

To evaluate the combined effects of cardiac overload imposed by hypertension and chronic swim training on coronary vascularity, female rats were made hypertensive by unilateral renal artery stenoses and were exercised in an 8- to 10-wk swimming program. Maximal coronary flow was assessed in isolated retrograde buffer-perfused hearts under conditions of minimal coronary resistance (15 microM adenosine or anoxia). Sedentary normotensive animals, sedentary hypertensive animals, and normotensive animals exposed to a swimming program were also studied. Swimming was associated with an 18% increase in heart weight and with increases in both absolute (ml/min) and relative (ml X g-1 X min-1) maximal coronary flow. Hypertension was associated with a 32% increase in heart weight but with a decrease in absolute and relative coronary flow compared with controls. The combined stimuli resulted in a 63% myocardial hypertrophy and a 19% increase in absolute flow. Relative coronary flow (g tissue-1) was similar in hearts from hypertensive sedentary animals and hypertensive swimmers. These data indicate that the coronary vascular deficit that accompanies the cardiac hypertrophy of hypertension is not worsened by the superimposition of an exercise load that exaggerates the hypertrophy.

Chronic swimming reverses cardiac dysfunction and myosin abnormalities in hypertensive rats.

The purpose of this study was to determine whether a chronic swimming program could reverse the decreased cardiac function and altered myosin biochemistry found in hearts of rats with established renal hypertension. Ten wk after the onset of hypertension [midpoint (m)], hearts from normotensive controls (C) and hypertensives (H) were studied in an isolated working heart apparatus, and myosin biochemistry was analyzed. Half of the control and hypertensive animals were then subjected to a 10-wk swimming program (Sw) and their hearts were compared with those from age-matched sedentary rats. Body weight was no different at the midpoint of the study between Cm and Hm or at the end point (e) of the study among Ce, Swe, He, or H-Swe. Swimming had no effect on blood pressure in either normotensive or hypertensive rats. Dry heart weight was increased by 46% in Hm compared with Cm and by 36% in He, 21% in Swe, and 61% in H-Swe when compared with Ce. Hypertension was associated in both the mid- and end-point studies, with decreases in coronary flow, stroke work (both per gram left ventricle), ejection fraction, and midwall fractional shortening. In addition, actin-activated myosin adenosinetriphosphatase (ATPase) activity was decreased in Hm and He associated with an increase in the content of the V3 myosin isoenzyme. Although the coronary deficit was not corrected in H-Swe, stroke work, ejection fraction, and fractional midwall shortening were normalized compared with control hearts. Myosin ATPase activity and the myosin isoenzyme distribution were similarly restored in H-Swe.(ABSTRACT TRUNCATED AT 250 WORDS)