Cardiomyoplasty: hemodynamic benefit to normal and depressed canine left ventricular function

This study examined the effects of cardiomyoplasty with vascular delay on canine normal and depressed left ventricular (LV) function. To improve viability of the latissimus dorsi muscle (LDM), vascular delay was performed 2 weeks before cardiomyoplasty in 10 mongrel dogs. Two weeks after cardiomyoplasty, LV function was evaluated by simultaneously measuring LV and aortic pressure, and aortic flow. The LDM was stimulated at a ratio of 1:4-1:7 synchronously with ventricular systole. Microspheres (90 mu) were sequentially injected into the left coronary artery to depress LV function. Data were acquired and analyzed on a beat to beat basis. Results were as follows: LDM stimulation significantly augmented LV systolic pressure (LVSP) from 138 +/- 2 to 161 +/- 2* mmHg, the peak rate of change of LV pressure (+dP/dt) from 1888 +/- 46 to 2584 +/- 43* mmHg/sec, aortic systolic pressure (AoSP) from 140 +/- 2 to 159 +/- 2* mmHg, stroke volume (SV) from 11.2 +/- 0.3 to 13.3 +/- 0.3* ml, stroke work (SW) from 19 +/- 1 to 26 +/- 1* gm.m, peak aortic flow (P Qa) from 5542 +/- 142 to 7190 +/- 161* ml/min, and decreased -dP/dt from -1683 +/- 31 to -1689 +/- 49* mmHg/sec (* = p < 0.05). Microsphere injections depressed LV function, but did not affect the magnitude of the net changes between stimulated and nonstimulated beats. However, the percent changes significantly increased. Preconditioning of LDM with vascular delay augments cardiac function in LDM assisted beats. This improved performance was present in both normal as well as depressed LV function groups. Thus, investigations of cardiomyoplasty may not necessarily require a model of severe myocardial dysfunction. Vascular delay offers an important preconditioning method of LDM to augment cardiac function in cardiomyoplasty.     

A computer simulation study of isometric contraction of latissimus dorsi muscle used for cardiac assistance

This study was designed to investigate the feasibility of a skeletal muscle pump employing latissimus dorsi muscle (LDM) for cardiac assistance. We developed and used a 2-dimensional mathematical model for LDM to investigate how the size of pneumatic balloons (30, 38, and 45 ml) and the three different locations (proximal, center, and distal) affect the pressure applied to the balloon by LDM. The computer simulation was performed by coding a visco-elastic and nonlinear 2-dimensional program that employed the finite element method (FEM). The muscle specific parameters of LDM were obtained from animal experiment results. The model is based on Hill's characteristic equation and composed of a contractile component and a passive element. The simulation results indicated that the intermediate and largest sized balloon lead to the highest and the lowest power (volume reduction per unit time interval), respectively. On the other hand, when the balloon is inserted in the distal LDM, the power is lower than in the other two positions, regardless of the balloon size. The above results suggest that the optimal size of the balloon should be selected depending on the muscle specific parameters of the actuator, and that the balloon should be inserted either in the proximal portion or center of the actuator.     

Assessment of ischaemia of the distal part of the gracilis muscle during transposition for anal dynamic graciloplasty

BACKGROUND: Dynamic graciloplasty is used to create a neosphincter in patients with intractable faecal incontinence. When mobilizing the distal gracilis muscle from the upper leg, the minor vascular pedicles have to be ligated. This can interfere with the vascular supply in this part of the muscle. METHODS: The arterial anatomy within the muscle was visualized by means of angiography of 11 postmortem specimens. To quantify potential acute ischaemia, blood flow in the distal gracilis muscle was measured in ten patients with laser Doppler flowmetry during mobilization of the muscle. RESULTS: Angiography showed that the main vascular pedicle and all minor pedicles drain into one and the same arterial system. After clamping of the minor vascular pedicles, blood flow (mean 25.8 (range 6.5-74.3) perfusion units) did not differ from values obtained before clamping (mean 25.4 (range 7.5-68.7) perfusion units). After a mean of 1.8 years, all muscles were vital. No correlation existed between the change in muscle blood flow and either squeeze pressure (r = -0.2) or functional outcome (r = 0.31). CONCLUSION: This study provides direct anatomical and physiological evidence of one arterial system within the gracilis muscle. It is therefore questionable whether ligation of the minor vascular pedicles is the bottleneck in human dynamic graciloplasty. An additional operation for vascular delay may be redundant. A prospective randomized clinical study should be performed to compare the functional outcome in patients with and without a delay procedure.     

Hydralazine: effect on the outflow of noradrenaline and mechanical responses evoked by sympathetic nerve stimulation of the rat tail artery

1 The effects of hydralazine on the vasoconstrictor responses to field stimulation of sympathetic nerves were studied in the isolated proximal segments of the rat tail artery. Vasoconstrictor responses to transmural stimulation were depressed by superfusion of hydrazine (0.3, 3 and 30 muM) in a concentration-dependent manner. The inhibition appeared slowly and was not easily reversed by washing. 2 Hydralazine (30 nM, 0.3 and 3 muM) reduced the stimulation-induced overflow of tritium from proximal and distal segments of the tail artery labelled with [3H]-noradrenaline in a concentration-dependent manner. This phenomenon appeared rapidly and was easily reversed by washing. 3 Theophylline (0.5 mM) did not affect the inhibitory effect of hydralazine on the stimulation-induced tritium efflux from the distal segment of the rat tail artery. 4 The present results indicate that hydralazine has, in addition to its action on vascular smooth muscle, a very marked effect on sympathetic nerve terminals. The mechanism of this presynaptic inhibition appears to be different from the postsynaptic effect, in view of the much shorter delay, the shape of the dose-effect curve, and the lack of interaction with theophylline.     

Long-term survival after treatment of malignant colonic polyps

For the application of the latissimus dorsi muscle (LDM) to circulatory assist, the muscle is stimulated with co- or counterpulsation during the cardiac cycle. The purpose of this study was to evaluate the blood supply to the LDM and its muscular performance during each respective stimulation. The origin of the LDM was connected to a tension gauge, a potentiometer, and 1 kg of weight in series. The LDM was stimulated at a ratio of 1:1 of heart to muscle contraction for 10 min. Copulsatile stimulation made thoracodorsal arterial flow (TDF) predominant during cardiac diastole. In counterpulsatile stimulation, TDF occurred predominantly during cardiac systole. Between the 2 patterns of stimulation, no significant differences were observed in the mean TDF rate during 1 cardiac cycle. The maximal force, maximal contraction length, and power of the LDM also did not differ significantly. These results suggest that despite the difference of the TDF profile, LDM performance may be comparable between co- and counterpulsatile stimulation for the application of the LDM to circulatory assist.     

Determination of highest no effect dose (HNED) for local anaesthetic responses to procaine, cocaine, bupivacaine and benzocaine

OBJECTIVES: This study sought to investigate the effect of coronary angioplasty on chronic hypoperfusion-induced endothelial dysfunction in patients with coronary heart disease. BACKGROUND: The endothelium is an important component for organ flow regulation. Ischemia with or without reperfusion is known to cause endothelial dysfunction. We tested the hypothesis that chronic hypoperfusion impairs endothelial function in the angiographically normal coronary artery segment distal to stenosis and that the impairment by chronic hypoperfusion is reduced by coronary angioplasty. METHODS: In 13 patients with stable angina pectoris, substance P (10, 30 and 100 pmol) and nitroglycerin (200 micrograms) were sequentially infused into the coronary artery in a cumulative manner on the day after coronary angioplasty. In 10 of these patients, vascular responses to these agents were again investigated 3 months after angioplasty. Changes in vascular diameter were evaluated in vessels located proximal and distal to the target lesion, both of which were angiographically normal, by performing computer-assisted quantitative coronary angiography. In five patients, the transstenotic pressure gradient was also measured with a pressure sensor-mounted guide wire before angioplasty. RESULTS: On the day after angioplasty, the magnitude of dilation by substance P in distal segments was significantly less than that in proximal segments and inversely correlated with the transstenotic pressure gradient (p < 0.05) and lesion stenosis (p < 0.05). There was no difference in nitroglycerin-induced vasodilation between the two vessel segment groups. Three months later, the impaired response to substance P in the distal segment was restored to normal. CONCLUSIONS: We conclude that chronic hypoperfusion impairs endothelium-dependent dilation of coronary artery distal to critical stenosis in patients with ischemic heart disease and that coronary angioplasty ameliorates the endothelial dysfunction within 3 months.     

Quantification of early damage in latissimus dorsi muscle grafts

Acute damage in the latissimus dorsi muscle may account for variable clinical results following dynamic cardiomyoplasty and an ischemic cause has been suggested. Using established techniques, we set out to demonstrate and to quantify the acute muscle damage in a rodent model. The left latissimus dorsi muscle of 5 Sprague-Dawley rats was mobilized on its thoracodorsal vascular pedicle, thus interrupting the regional blood supply to its distal part. The undisturbed contralateral muscle served as a matched control. After 24 hours, the muscle was excised and divided into proximal, middle, and distal thirds. Damage was graded histologically and quantified by nitroblue tetrazolium macrohistochemistry. Both methods of assessment correlated well (r=-0.936; P < 0.001) and demonstrated significant damage, principally in the middle and the distal regions of the ischemic muscles. Therefore, the rodent model appears to be useful for investigating the pathogenesis and prevention of acute ischemic damage in the latissimus dorsi graft under conditions resembling the clinical scenario.     

Experience with the Cryosurgical treatment of the prostatic diseases in 100 patients (author''s transl)]

The semitendinosus muscle of the dog is supplied by two separate arteries and drained by two corresponding veins. In the muscles used in this study no blood entering via the distal artery was found to leave via the proximal vein during perfusion through both arteries (orthograde perfusion). Therefore, collateral flow (CF) could be determined as proximal venous outflow during occlusion of the proximal artery. During orthograde perfusion total blood flow averaged 12 ml x min-1 x 100 g-1 at rest and 58.4 ml x min-1 x 100 g-1 during exercise. CF was found to average 6.2 ml x min-1 x 100 g-1 at rest and increased to 9.2 ml x min-1 x 100 g-1 during exercise. CF was sufficient to cover the metabolic demand of resting muscle. During exercise the O2-uptake (VO2) of the distal muscle portion was increased 13.4 fold in comparison to a 3.1 fold increase in the proximal muscle portion. The average contractile power decreased by 46%. Additional infusion of adenosine into the distal artery resulted in an increase of CF to 11.4 ml x min-1 x 100 g-1 and of orthograde flow to 71 ml x min-1 x 100 g-1. The average contractile power of the muscle increased by 13%. Both orthograde flow and CF were found to decrease with increasing muscle load. But this decrease was significantly more pronounced in the case of CF especially at a lower range of loads. It is concluded that after acute occlusion of orthograde flow, CF is limited by the number, the size and the dilatory capacity of precapillary network vessels. Furthermore, CF is influenced considerably by changes of extravascular support.     

Migration of hypoglossal myoblast precursors

PURPOSE: To report an experimental study investigating the ability of nonporous polytetrafluoroethylene (PTFE) covering on a metallic stent to retard the development of neointimal hyperplasia (NIH). METHODS: Three groups of Hanford miniature swine underwent standardized balloon injury to both external iliac arteries. Group I animals (control) received balloon injuries only. Group II had the site of balloon injury supported by a properly sized, balloon-expandable Palmaz stent placed directly over the injury site. Group III animals received a Palmaz stent covered with PTFE graft. All animals underwent arteriography immediately after intervention and again prior to sacrifice and specimen harvest at 4 weeks. The specimens were examined grossly and histologically at the proximal, middle, and distal segments for NIH development. RESULTS: Uncovered stents developed significantly more NIH (p < 0.0001) and greater luminal narrowing (p < 0.001) than the controls. PTFE-covered stents (group III) exhibited less NIH (p < 0.001) and luminal reduction (p < 0.01) than bare stents (group II) at the middle portion of the stent-graft, but the PTFE cover had no effect on NIH and lumen reduction at the proximal or distal ends of the prosthesis. CONCLUSIONS: PTFE-covered stents retarded NIH at 4 weeks, but only at the midportion of the devices; the covering did not prevent neointimal pannus ingrowth at the proximal and distal ends.     

Biophysical signals underlying myogenic responses in rat interlobular artery

-To assess cellular mechanisms mediating myogenic responses of interlobular artery (ILA), experiments were performed with the use of isolated perfused hydronephrotic kidneys. ILAs were divided into 3 groups according to their basal diameters: proximal (>60 microm), intermediate (40 to 60 microm), and distal (<40 microm) ILAs. Myogenic responses were obtained by stepwise increase in perfusion pressure. Greater myogenic responsiveness was observed in ILAs with smaller diameters. Diltiazem (10 micromol/L) inhibited myogenic responses of all segments of ILAs. Furthermore, gadolinium (10 micromol/L), a mechanosensitive cation channel blocker, abolished myogenic responses of distal but not proximal ILA. In contrast, 2-nitro-4-carboxyphenyl-N, N-diphenyl-carbamate (200 micromol/L), an inhibitor of phospholipase C, prevented myogenic responses of proximal but not distal ILA. Finally, basal proximal ILA diameters were increased by treatment with 50 nmol/L of staurosporine (P<0.05), and subsequent addition of thapsigargin (1 micromol/L) blocked myogenic contraction of proximal ILAs. Myogenic responses of intermediate ILAs exhibited characteristics between those of distal and proximal ILAs. Our data indicate that underlying mechanisms for myogenic responses differ in distinct segments of ILAs. The present results suggest that mechanosensitive cation channels are involved in myogenic constriction of distal ILAs. Finally, our findings provide evidence that the stimulation of phospholipase C mediates myogenic contraction of proximal ILAs.     

Dynamics of the martial arts high front kick

Fast unloaded movements (i.e. striking, throwing and kicking) are typically performed in a proximo-distal sequence, where initially high proximal segments accelerate while distal segments lag behind, after which proximal segments decelerate while distal segments accelerate. The aims of this study were to examine whether proximal segment deceleration is performed actively by antagonist muscles or is a passive consequence of distal segment movement, and whether distal segment acceleration is enhanced by proximal segment deceleration. Seventeen skilled taekwon-do practitioners were filmed using a high-speed camera while performing a high front kick. During kicking, EMG recordings were obtained from five major lower extremity muscles. Based on the kinematic data, inverse dynamics computations were performed yielding muscle moments and motion-dependent moments. The results indicated that thigh deceleration was caused by motion-dependent moments arising from lower leg motion and not by active deceleration. This was supported by the EMG recordings. Lower leg acceleration was caused partly by a knee extensor muscle moment and partly by a motion-dependent moment arising from thigh angular velocity. Thus, lower leg acceleration was not enhanced by thigh deceleration. On the contrary, thigh deceleration, although not desirable, is unavoidable because of lower leg acceleration.     

Contributions of pathway and neuron to preferential motor reinnervation

Motor axons regenerating after transection of mixed nerve preferentially reinnervate distal muscle branches, a process termed preferential motor reinnervation (PMR). Motor axon collaterals appear to enter both cutaneous and muscle Schwann cell tubes on a random basis. Double-labeling studies suggest that PMR is generated by pruning collaterals from cutaneous pathways while maintaining those in motor pathways (the "pruning hypothesis"). If all collaterals projecting to muscle are saved, then stimulation of regenerative sprouting should increase specificity by increasing the number of motoneurons with at least one collateral in a muscle pathway. In the current experiments, collateral sprouting is stimulated by crushing the nerve proximal to the repair site before suture, a maneuver that also conditions the neuron and predegenerates the distal pathway. Control experiments are performed to separate these effects from those of collateral generation. Experiments were performed on the rat femoral nerve and evaluated by exposing its terminal cutaneous and muscle branches to HRP or Fluoro-Gold. Crush proximal to the repair site increased motor axon collaterals at least fivefold and significantly increased the percentage of correctly projecting motoneurons, consistent with the pruning hypothesis. Conditioning the nerve with distal crushes before repair had no effect on specificity. A graft model was used to separate the effects of collateral generation and distal stump predegeneration. Previous crush of the proximal femoral nerve significantly increased the specificity of fresh graft reinnervation. Stimulation of regenerative collateral sprouting thus increased PMR, confirming the pruning hypothesis. However, this effect was overshadowed by the dramatic specificity with which predegenerated grafts were reinnervated by fresh uncrushed proximal axons. These unexpected effects of predegeneration on specificity could involve a variety of possible mechanisms and warrant further study because of their mechanistic and clinical implications.     

Regional variation in appearance of vascular contractile endothelin-B receptors following organ culture

OBJECTIVE: The aim of this study was to investigate the appearance of contractile endothelin (ET)-B receptors following organ culture in different vascular regions. METHOD: The contractile responses of vascular smooth muscle induced by ET-1 and the selective ETB receptor agonist sarafotoxin 6c (S6c) were investigated in circular segments representing eight vascular regions in the rat (aorta, femoral artery, mesenteric artery, branch of the mesenteric artery, proximal and distal parts of the caudal artery, femoral and mesenteric veins). To allow the ETB receptor to be expressed, the segments were placed in organ culture for 1 to 5 days. Pharmacological characterisation of the ET receptors was performed in mesenteric arterial segments. All contractile responses were measured in percentage of K(+)-induced contraction. RESULTS: ET-1 induced strong concentration-dependent contractions of all fresh (not cultured) segments. S6c had negligible effects on all fresh vessels with the exception of the mesenteric vein, where a small contraction was seen. After 1 day of organ culture all tested segments, with the exception of aorta and the proximal part of the caudal artery, showed concentration-dependent contractile responses to S6c which were further augmented after 5 days of culture. The ET-1-induced responses were only slightly affected by organ culture. Contractions induced by S6c were more enhanced in small arteries and veins than in larger arteries. Furthermore, the S6c-induced response was more pronounced in the mesenteric region as compared to the hindlimb. In fresh mesenteric arterial segments FR139317 (ETA receptor antagonist) and bosentan (ETA/ETB receptor antagonist) but not IRL 2500 (ETB receptor antagonist) shifted the ET-1-induced concentration-response curve in parallel to the right. In contrast, after organ culture the S6c-induced concentration-response curves were shifted parallel to the right in the following potency order: IRL 2500 > bosentan > FR139317. CONCLUSION: During normal conditions, the ETA receptor is the dominating mediator of endothelin-induced contraction in eight different vascular regions. Furthermore, this study indicates that most of the vessels have the ability to develop contractile ETB receptors and that this plasticity differs in vascular regions.     

Zinc uptake in five sectors of the rat gastrointestinal tract: kinetic study in the whole colon

PURPOSE: The uptake of zinc as acexamic acid salt in the rat gastrointestinal tract, using an in situ static technique, was studied. Our aim was to investigate an absorption window for zinc and the uptake kinetics in the colon. METHODS: To detect selectivity phenomena in zinc absorption, buffered saline solutions of zinc (50 micrograms/ ml) were perfused in stomach, whole colon and three 33-cm fractions of the small intestine (proximal, middle and distal segments). To characterize zinc uptake kinetics in whole colon, five different zinc concentrations (5, 25, 50, 150 y 250 micrograms/ml) were assayed. Zinc secreted into the gastrointestinal tract during the experiments was deducted from the uptake. RESULTS: Zinc secretion was characterized as an apparent zero-order process for all the studied segments (mean secretion rate = 0.10 +/- 0.03 microgram/(ml x min)). The stomach exhibited little ability to absorb zinc (apparent first order rate constant = 0.17 +/- 0.07 h-1), whereas the highest transport rates were found in the last two thirds of the small intestine and colon (first order constants: 0.66 +/- 0.13 h-1, 1.00 +/- 0.06 h-1, 0.97 +/- 0.14 h-1, 0.96 +/- 0.19 h-1 for proximal, middle, distal and colon segments, respectively). Zinc uptake in the colon was characterized by means of a Michaelis-Menten and first-order combined kinetics, with the following parameters: Vm = 0.36 +/- 0.02 microgram/(ml x min), Km = 18.01 +/- 0.40 microgram /ml and Ka = 0.40 +/- 0.01 h-1. CONCLUSIONS: Zinc is preferably absorbed in the middle and distal parts of the rat gastrointestinal tract. In the colon a saturable mechanism may be involved in apparent absorption.     

Extrinsic nervous control of retrograde giant contraction during vomiting in conscious dogs

Neural mechanisms controlling retrograde giant contraction during vomiting were studied in six conscious dogs with implanted strain gauge force transducers. The small intestine was divided into proximal (P), middle (M), and distal (D) segments. These segments were transplanted on intact mesenteric neurovascular pedicles. In three dogs, M and D segments were interchanged (group A). In three dogs, P and M segments were interchanged (group B). Before transplantation, apomorphine-induced vomiting caused retrograde giant contractions, starting from the M segment and rapidly migrating to the stomach. However, in group A, even after recovery of interdigestive migrating contractions migration, retrograde giant contractions during vomiting always originated in the distally interchanged M segment and jumped to the P segment without migration to the D segment. In group B, the retrograde giant contraction always originated in the proximally interchanged M segment and successively occurred in the distally interchanged P segment. We conclude that origination and migration of retrograde giant contractions are extrinsically controlled. These motor events during vomiting are thought to be a specific motor function that does not exist in the lower small intestine, and retrograde giant contraction during vomiting may originate in the mid-small intestine.     

Blood flow in mobilized nerves: results in a rabbit sciatic nerve model

The purpose of this study was to evaluate the immediate effect on capillary blood flow of surgical mobilization of 15 cm of the rabbit sciatic and tibial nerve. Capillary nerve blood flow was determined with 16-micron radioactive microspheres. Thirty-seven rabbits were divided into six groups. In the control group A (n = 7), the in situ nerve blood flow was determined. In group B (n = 7), the nerve was mobilized, leaving only the proximal and distal endoneurial vascular supplies; blood flow increased compared with in situ values in most segments. In group C (n = 5), the nerve was mobilized as in group B, but also transected distally; blood flow was markedly decreased in the distal segments but was maintained up to a diameter-to-length ratio of 1:63. In group D (n = 6), the nerve was not mobilized, but was transected proximally and distally; blood flow increased in all segments. In group E (n = 5), the nerve was mobilized and transected proximally and distally, leaving only nerve branches intact; blood flow was significantly higher in segments of the nerve from which nerve branches originated with the nerve receiving blood flow through its branches. In group F (n = 6), the nerve was mobilized, all extrinsic vessels except one were transected, and the proximal and distal nerve was transected; flow was maintained to a diameter:length ratio of 1:41 from the source of blood flow. Therefore, it does appear that long lengths of nerve may be mobilized and transposed while maintaining sufficient blood flow.     

Adrenergic and nitrergic responses of the rat isolated anococcygeus muscle to a new toxin (makatoxin I) from the venom of the scorpion Buthus martensi Karsch

Muscle fibre composition was compared among the proximal (25%), middle (50%) and distal (75%) regions of muscle to investigate whether denervation induces region-specific changes of fibre types in the soleus and plantaris muscles of rats. Decreases in mass were observed in both muscles after denervation. In the soleus muscle, denervation increased the percentage of type I fibres with a concomitant increase in the proportion of type IIC and IIA fibres. The extent of such transformations was greater in the proximal region than the middle and distal regions. In normal plantaris muscle, the middle region showed a higher proportion of type IIA fibres with a lower percentage of type IIB fibres reciprocally than other regions. These regional differences in fibre types were not detected in the 4-week denervated plantaris muscle. These findings suggest that denervation-induced transformations from type I to type II fibres begin in the proximal region in the soleus muscle of rats. In addition, regional differences in fibre types along the muscle length could be regulated by neuromuscular activity through normal innervation in the plantaris muscle.     

Electrophysiologic mapping and cadaveric dissection of the lateral foot: implications for tibial motor nerve conduction studies

OBJECTIVE: To clarify, through electrophysiologic mapping and cadaveric dissection of the lateral foot, the previously published "proximal" and "distal" recording sites for tibial motor nerve conduction studies. DESIGN: Observational. SETTING: Electromyography laboratory; anatomy laboratory. PATIENTS OR OTHER PARTICIPANTS: Ten asymptomatic feet; eight cadaveric feet. MAIN OUTCOME MEASURES: (1) Amplitudes and onset latencies of compound muscle action potentials (CMAPs) recorded over a grid on the lateral foot that included the "proximal" and "distal" recording sites; (2) nerve supply and anatomic boundaries of the abductor digiti minimi pedis (ADMP) and nearby muscles, particularly as they relate to the above recording sites. RESULTS: (1) Relatively large CMAPs were recorded at and around the "proximal" and "distal" sites, with significantly shorter "proximal" latencies. (2) In all cadaveric feet, ADMP was innervated by only the inferior calcaneal nerve (ICN) and was located deep to the "proximal" site, with virtually no muscle fibers deep to the "distal" site. The flexor digiti minimi brevis (FDMB) was conspicuously located immediately deep to the "distal" site and was innervated by only the lateral plantar nerve (LPN). CONCLUSIONS: This study strongly suggests that the "proximal" site records predominantly from the ICN-innervated ADMP, whereas the "distal" site predominantly records from the LPN-innervated FDMB.     

Wall cytoarchitecture of the rat ciliary process microvasculature revealed with scanning electron microscopy

Ciliary process vasculature has an important role in aqueous humor production. There have been, however, few reports describing the overall cytoarchitecture of ciliary process vasculature. The wall cytoarchitecture of microvessels in the rat ciliary process was elucidated by scanning electron microscopy after removal of ciliary epithelia and connective tissue components with HCl hydrolysis. Utilizing characteristics of cellular morphology and vessel diameters, several vascular components were identified along the vascular tree: 1) arterial iridociliary circles (30-60 microm in outer diameter), containing a compact layer of circularly oriented spindle-shaped smooth muscle cells; 2) the proximal part of the radial ciliary arteriole (10-25 microm), containing a less compact layer of circularly oriented branched-smooth muscle cells and spindle-shaped smooth muscle cells; 3) a middle part of the radial ciliary arteriole (20-35 pm), with circularly oriented branched-smooth muscle cells and irregularly oriented stellate cells with ramifying projections; 4) a distal part of the radial ciliary arteriole (10-20 microm), possessing irregularly oriented stellate cells with ramifying projections; 5) marginal venules (15-20 microm), with spidery pericytes possessing highly ramifying and overlapped projections; 6) capillaries in the ciliary process (4-7 microm), with widely scattered pericytes having longitudinal and several circular projections; 7) venules in the posterior basal region of the ciliary process (greater than 5 microm), with widely scattered pericytes having a few thin projections. From arterial iridociliary circles to venules in the basal region of ciliary process, seven parts could be recognized by wall cytoarchitecture, which was discussed in relation with the function.     

Dynamic pressure in the superficial and deep crural veins in uncomplicated varicosity without incompetence of communicant veins

Synchronous phlebotonometry was performed on 30 lower extremities in 27 patients. Various pressure dynamics was observed in the proximal and distal segments of profound veins. Dynamic phlebohypertension was found not only in superficial but also in deep-seated veins. The escape of superficial veins resulted in normalization of pressure in both systems. The more intensive muscle contractions under conditions of normal blood circulation the greater a reduction of pressure phases in the crural vein distal segment this factor may be used as a test for estimation of the vein-muscle pump function.