Model for prompt and effective classification of motion recovery after stroke considering muscle strength and coordination factors.

BACKGROUND: Muscle synergies are now widely discussed as a method for evaluating the existence of redundant neural networks that can be activated to enhance stroke rehabilitation. However, this approach was initially conceived to study muscle coordination during learned motions in healthy individuals. After brain damage, there are several neural adaptations that contribute to the recovery of motor strength, with muscle coordination being one of them. In this study, a model is proposed that assesses motion based on surface electromyography (sEMG) according to two main factors closely related to the neural adaptations underlying motor recovery: (1) the correct coordination of the muscles involved in a particular motion and (2) the ability to tune the effective strength of each muscle through muscle fiber contractions. These two factors are hypothesized to be affected differently by brain damage. Therefore, their independent evaluation will play an important role in understanding the origin of stroke-related motor impairments. RESULTS: The model proposed was validated by analyzing sEMG data from 18 stroke patients with different paralysis levels and 30 healthy subjects. While the factors necessary to describe motion were stable across heathy subjects, there was an increasing disassociation for stroke patients with severe motor impairment. CONCLUSIONS: The clear dissociation between the coordination of muscles and the tuning of their strength demonstrates the importance of evaluating these factors in order to choose appropriate rehabilitation therapies. The model described in this research provides an efficient approach to promptly evaluate these factors through the use of two intuitive indexes.

Motor Control System for Adaptation of Healthy Individuals and Recovery of Poststroke Patients: A Case Study on Muscle Synergies.

Understanding the complex neuromuscular strategies underlying behavioral adaptation in healthy individuals and motor recovery after brain damage is essential for gaining fundamental knowledge on the motor control system. Relying on the concept of muscle synergy, which indicates the number of coordinated muscles needed to accomplish specific movements, we investigated behavioral adaptation in nine healthy participants who were introduced to a familiar environment and unfamiliar environment. We then compared the resulting computed muscle synergies with those observed in 10 moderate-stroke survivors throughout an 11-week motor recovery period. Our results revealed that computed muscle synergy characteristics changed after healthy participants were introduced to the unfamiliar environment, compared with those initially observed in the familiar environment, and exhibited an increased neural response to unpredictable inputs. The altered neural activities dramatically adjusted through behavior training to suit the unfamiliar environment requirements. Interestingly, we observed similar neuromuscular behaviors in patients with moderate stroke during the follow-up period of their motor recovery. This similarity suggests that the underlying neuromuscular strategies for adapting to an unfamiliar environment are comparable to those used for the recovery of motor function after stroke. Both mechanisms can be considered as a recall of neural pathways derived from preexisting muscle synergies, already encoded by the brain's internal model. Our results provide further insight on the fundamental principles of motor control and thus can guide the future development of poststroke therapies.

Anxiolytic actions of motilin in the basolateral amygdala.

Motilin is a 22-amino-acid gastrointestinal polypeptide that was first isolated from the porcine intestine. We identified that motilin receptor is highly expressed in GABAergic interneurons in the basolateral nucleus (BLA) of the amygdala, the structure of which is closely involved in assigning stress disorder and anxiety. However, little is known about the role of motilin in BLA neuronal circuits and the molecular mechanisms of stress-related anxiety. Whole-cell recordings from amygdala slices showed that motilin depolarized the interneurons and facilitated GABAergic transmission in the BLA, which is mimicked by the motilin receptor agonist, erythromycin. BLA local injection of erythromycin or motilin can reduce the anxiety-like behavior in mice after acute stress. Therefore, motilin is essential in regulating interneuron excitability and GABAergic transmission in BLA. Moreover, the anxiolytic actions of motilin can partly be explained by modulating the BLA neuronal circuits. The present data demonstrate the importance of motilin in anxiety and the development of motilin receptor non-peptide agonist as a clear target for the potential treatment of anxiety disorders.

Discovery of novel motilin antagonists: Conversion of tetrapeptide leads to orally available peptidomimetics.

We successfully discovered peptidomimetic motilin antagonists (17c and 17d) through the improvement of physicochemical properties of a tetrapeptide antagonist (2). Furthermore, with oral administration and based on motilin antagonistic activity, both compounds suppressed motilin-induced colonic and gastric motility in conscious dogs.

An orally active motilin receptor antagonist, MA-2029, inhibits motilin-induced gastrointestinal motility, increase in fundic tone, and diarrhea in conscious dogs without affecting gastric emptying.

The pharmacological properties of MA-2029, a selective and competitive motilin receptor antagonist, were investigated in conscious dogs after oral administration. Gastrointestinal contractile activity was recorded by chronically implanted force transducers. The proximal gastric volume was measured with a barostat under constant pressure. Gastric emptying was examined using the paracetamol absorption test. MA-2029 (0.3-10 mg/kg, p.o.) administered in the interdigestive state inhibited gastrointestinal contractions induced by motilin (3 microg/kg, i.v.) in a dose-dependent manner. MA-2029 (0.3-3 mg/kg, p.o.) also inhibited the occurrence of spontaneous phase III contractions, even though MA-2029 had no effect on basal gastrointestinal motility or basal gastric emptying even at 10 and 30 mg/kg p.o. The inhibitory effect of MA-2029 on motilin-induced gastrointestinal motility corresponded to its plasma concentration. Motilin (0.3 microg/kg/h, i.v. infusion) reduced the proximal gastric volume by about 50% of control during isobaric distension. This effect was also inhibited by MA-2029 (1-10 mg/kg, p.o.) in a dose-dependent manner. In the digestive state, injection of motilin (3 microg/kg, i.v.) induced diarrhea in 9 of 11 dogs. MA-2029 (1-30 mg/kg, p.o.) reduced the incidence of diarrhea induced by motilin in a dose-dependent manner. The results indicate that MA-2029 inhibits hypermotility induced by motilin in conscious dogs without having an effect on the basal gastrointestinal tone or gastric emptying rate. MA-2029 may be useful in treating gastrointestinal disorders in which the pathogenesis involves the elevation of circulating motilin.

Effects of mitemcinal (GM-611), an orally active erythromycin-derived prokinetic agent, on delayed gastric emptying and postprandial glucose in a new minipig model of diabetes.

AIMS: This study was conducted to evaluate the suitability of a new minipig model for investigating aspects of diabetes such as delayed gastric emptying and glucose metabolism abnormalities, and to test the effects of mitemcinal (GM-611), an orally active erythromycin-derived motilin receptor agonist, on gastric emptying and postprandial glucose in normal and diabetic minipigs. METHODS AND RESULTS: Intravenous injection of 300 mg/kg streptozotocin (STZ) to 5-week-old minipigs induced moderate hyperglycemia (about 200 mg/dl) for >80 weeks without insulin treatment. Decreased insulin production (P<.05), increased area under the glucose curve (P<.05), and slower glucose disappearance (P<.05) were demonstrated, and there was no severe inhibition of body weight gain, liver failure, or renal failure. Gastric emptying was significantly delayed in diabetic minipigs (P<.05) at 80 weeks, but not at 40 weeks, post-STZ. Oral administration of mitemcinal (5 mg/kg) at 80 weeks accelerated gastric emptying and induced a similar postprandial glucose profile in normal and diabetic minipigs with delayed gastric emptying. CONCLUSIONS: The new diabetic minipig model showed suitability for investigating diabetes, gastric emptying, and plasma glucose excursions. Since delayed gastric emptying and irregular plasma glucose excursions are characteristic of diabetic gastroparesis, the accelerating and regulating effects of mitemcinal on this model add to the existing evidence that mitemcinal is likely to be useful for treating diabetic gastroparesis.

Mitemcinal (GM-611), an orally active motilin receptor agonist, improves delayed gastric emptying in a canine model of diabetic gastroparesis.

1. The aim of the present study was to evaluate the effects of mitemcinal (GM-611), an orally active motilin receptor agonist, on delayed gastric emptying in a canine model of diabetic gastroparesis and to compare these effects with those of cisapride. 2. Moderate hyperglycaemia was induced by a single intravenous injection of a mixture of streptozotocin (30 mg/kg) and alloxan (50 mg/kg). Dogs that maintained moderate hyperglycaemia (fasting plasma glucose 200-300 mg/dL) without insulin treatment were selected and gastric emptying in these dogs was determined by the paracetamol method. 3. One year after the onset of diabetes, there was no difference in the gastric emptying of normal and diabetic dogs. However, after 5 years, the diabetic dogs showed delayed gastric emptying. The motor nerve conduction velocity of the tibial nerve was significantly lower in diabetic dogs compared with normal dogs at both time points. 4. Histopathological examination at the end of the study showed that there were fewer nerve fibres in both dorsal vagal and tibial nerves of diabetic dogs compared with normal dogs. The onset of delayed gastric emptying is thought to have occurred gradually, in parallel with abnormal autonomic nerve function induced by the long period of moderate hyperglycaemia. 5. Oral administration of mitemcinal (0.125, 0.25 or 0.5 mg/kg) dose-dependently accelerated delayed gastric emptying, significant at 0.5 mg/kg, in diabetic dogs, whereas cisapride (1, 3 or 10 mg/kg) had no significant effect. These results add to the existing evidence that mitemcinal is likely to be useful for treating diabetic gastroparesis.

Oral administration of MA-2029, a novel selective and competitive motilin receptor antagonist, inhibits motilin-induced intestinal contractions and visceral pain in rabbits.

The pharmacological properties of MA-2029, a novel motilin receptor antagonist, were investigated. In vitro, MA-2029 (1 to 30 nM) competitively inhibited motilin-induced contractions in isolated rabbit duodenal longitudinal muscle strips, with a pA2 value of 9.17+/-0.01 (n=5). However, contractile responses to acetylcholine and substance P were unaffected even at 1 microM of MA-2029. MA-2029 concentration-dependently inhibited the binding of [125 I]motilin to motilin receptors in a homogenate of rabbit colon smooth muscle tissue and membranes of HEK 293 cells expressing human motilin receptors. The pKi of MA-2029 was 8.58+/-0.04 in the rabbit colon homogenate (n=4) and 8.39 in the HEK 293 cells (mean of duplicate experiments). In vivo, orally-administered MA-2029 (3 to 30 mg/kg) dose-dependently inhibited colonic contractions induced by motilin (3 microg/kg, i.v.) in conscious rabbits. Inhibition was caused by all doses at 30 min after administration and by 10 mg/kg or more at 4 h after administration. The plasma concentration of MA-2029 correlated with its inhibitory effect. Furthermore, the oral administration of MA-2029 (0.3 to 3 mg/kg) also inhibited abdominal muscle contractions (an index of the visceral pain) induced by intravenous infusion of motilin (3 microg/kg/h) during colorectal distension in conscious rabbits. These results indicate that MA-2029 is an orally active, selective and competitive motilin receptor antagonist. It is suggested that this compound may be useful for gastrointestinal disorders associated with disturbed gastrointestinal motility such as irritable bowel syndrome.

Effects of oral mitemcinal (GM-611), erythromycin, EM-574 and cisapride on gastric emptying in conscious rhesus monkeys.

We assessed and compared the effects of oral mitemcinal (an orally active, erythromycin-derived motilin-receptor agonist; Code name: GM-611), erythromycin, EM-574 and cisapride on gastric emptying in conscious Rhesus monkeys using the acetaminophen method. Mitemcinal and erythromycin induced significant, dose-dependent increases in indices of gastric emptying, but mitemcinal required a much lower dose for the same effect. Cisapride induced a bell-shaped dose response, and EM-574, a potent erythromycin derivative and originally developed as an enteric coated formulation, had little effect when it was given orally uncoated. Since our previous study showed that response to motilin is similar in Rhesus monkeys and humans, these results suggest that oral mitemcinal may be effective for the treatment of symptoms in human disorders related to delayed gastric emptying (e.g., functional dyspepsia and gastroparesis). Combined with the results of other studies, these results suggest that mitemcinal may be able to replace the withdrawn drug, cisapride, as the drug of choice for treating delayed gastric emptying.

Oral mitemcinal (GM-611), an erythromycin-derived prokinetic, accelerates normal and experimentally delayed gastric emptying in conscious dogs.

1. We examined effects of orally administered mitemcinal, an erythromycin-derived motilin agonist, on gastric emptying and antroduodenal motility in conscious normal dogs and conscious dogs with experimentally delayed gastric emptying. For comparison, we also examined the effects of orally administered cisapride. 2. Gastric emptying was assessed by adding paracetamol to the test meal and determining three of its pharmacokinetic parameters as indices of gastric emptying. Antroduodenal motility was assessed from the output of force transducers chronically implanted in the gastric antrum and duodenum. 3. In normal dogs, mitemcinal (0.25, 0.5 and 1 mg/kg) dose-dependently accelerated gastric emptying, significantly increasing all three indices at doses of 0.5 and 1 mg/kg; cisapride (1, 3 and 10 mg/kg) had no significant effect. Mitemcinal also dose-dependently stimulated antroduodenal motility in the interdigestive and digestive states. Cisapride, at 100-fold the dose, produced similar effects in the interdigestive state, but mixed results in the digestive state. 4. In dogs with delayed gastric emptying induced by subcutaneous clonidine (0.03 mg/kg), mitemcinal (0.25, 0.5 and 1 mg/kg) dose-dependently improved delayed gastric emptying, significantly increasing two of three indices at a dose of 1 mg/kg. Cisapride (1, 3 and 10 mg/kg) caused non-significant increases in the indices of gastric emptying, with roughly bell-shaped dose-response curves. The highest dose of mitemcinal (1 mg/kg) also stimulated antroduodenal motility. 5. In dogs with delayed gastric emptying induced by vagotomy, mitemcinal (0.125, 0.25 and 0.5 mg/kg) dose-dependently improved delayed gastric emptying, significantly increasing all three indices at doses of 0.25 and 0.5 mg/kg. Cisapride (3 mg/kg) restored the indices to roughly prevagotomy levels, but none of the increases was significant. Mitemcinal, at a dose of 0.25 mg/kg, also stimulated antroduodenal motility. 6. Because delayed gastric emptying is the basic characteristic of gastroparesis, the fact that mitemcinal accelerated gastric emptying in dogs with normal and delayed gastric emptying much more robustly than cisapride adds to the evidence that mitemcinal is likely to be useful for the treatment of patients with gastroparesis.

Effects of mitemcinal (GM-611), an acid-resistant nonpeptide motilin receptor agonist, on the gastrointestinal contractile activity in conscious dogs.

The effects of mitemcinal (GM-611) on the gastrointestinal contractile activity were investigated using chronically implanted force transducers in conscious dogs and were compared with the effects of porcine motilin (pMTL), EM-523 and EM-574. In the interdigestive state, intravenous and oral administration of mitemcinal, EM-523 and EM-574 induced the gastrointestinal contractile activity in a manner similar to pMTL. The contractile activity caused by mitemcinal was suppressed by continuous intravenous infusion of a motilin receptor antagonist. In the digestive state, intravenous and oral administration of mitemcinal, EM-523 and EM-574 also stimulated the gastrointestinal contractile activity. Mitemcinal, EM-523 and EM-574 given intravenously increased the gastric contractile activity in a similar dose range; however, mitemcinal was approximately 10 times more potent than EM-523 and EM-574 when administered orally in the digestive state. These results indicate that the mitemcinal-induced gastrointestinal contractile activity operates via motilin receptors and possesses a higher activity than EM-523 and EM-574 when administered orally in conscious dogs in the digestive state. Mitemcinal may therefore be useful in the treatment of several gastrointestinal disorders involving dysmotility, such as gastroparesis and functional dyspepsia, even when administered orally.

Effects of motilin and mitemcinal (GM-611) on gastrointestinal contractile activity in rhesus monkeys in vivo and in vitro.

Neither the presence of motilin receptors nor their action has been investigated in monkeys. The object of this study was to determine the effects of motilin and mitemcinal (GM-611), an erythromycin derivative, on the gastrointestinal tract in rhesus monkeys in vivo and in vitro. In in vivo investigations in conscious monkeys, both motilin and mitemcinal induced migrating motor complex-like contractions in the interdigestive state and also accelerated gastric emptying. In in vitro investigations, the presence of motilin receptors in the gastrointestinal tract was demonstrated by receptor binding assays. Motilin and mitemcinal contracted isolated duodenum strips in a concentration-dependent manner. In conclusion, rhesus monkeys may be useful for studying the physiological and pharmacological roles of the motilin agonistic mechanism because they show reactivity to motilin both in vivo and in vitro.

In vitro pharmacological characterization of mitemcinal (GM-611), the first acid-resistant non-peptide motilin receptor agonist, in smooth muscle of rabbit small intestine.

The pharmacological properties of mitemcinal (GM-611), the first acid-resistant non-peptide motilin agonist, were investigated in the smooth muscle of the rabbit small intestine and compared with porcine motilin (pMTL), erythromycin A (EMA) and its derivatives (EM-523, EM-574 and ABT-229). Mitemcinal, pMTL, EMA, EM-523, EM-574 and ABT-229 produced concentration-dependent contractions with approximately the same maximum contractions in the isolated rabbit duodenum longitudinal strips. The contractile response to mitemcinal or pMTL was competitively inhibited by a selective motilin antagonist, GM-109. The pA(2) values for GM-109 as an antagonist of mitemcinal and pMTL showed approximately the same values. However, the concentration-dependent contractile responses to mitemcinal or pMTL were not affected by pretreatment with atropine, tetrodotoxin, hexamethonium, naloxone or tropisetron. The removal of calcium ions from the medium and pretreatment with verapamil greatly suppressed the contractions induced by mitemcinal and pMTL. The contractile response to mitemcinal was not affected by preincubation in acidic solutions, while those of EM-523, EM-574 and ABT-229 were strongly diminished in the same condition. Mitemcinal as well as other motilin agonists displaced (125)I-pMTL bound to a homogenate of the rabbit duodenum muscle tissue. The displacement curves of all these compounds were parallel. These results indicate that mitemcinal is a selective and full motilin receptor agonist in the smooth muscle of the rabbit small intestine and that this agent has an excellent acid-resistant property.