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BACKGROUND: Enhanced recovery protocols (ERP) are a multimodal approach to standardize perioperative care. To substantiate the benefit of a pediatric-centered pathway, we compared outcomes of children treated with pediatric ERP (pERP) versus adult (aERP) pathways. We aimed to compare components of each pathway to create a new comprehensive pERP to reduce variation in care. METHODS: Retrospective study of children (≤18 y) undergoing elective colorectal surgery from August 2015 to April 2019 at a single institution managed with pERP versus aERP. Multivariable linear and logistic regression, adjusting for demographics and operation characteristics, were used to compare outcomes. RESULTS: Out of 100 hospitalizations (72 patients) were identified, including 37 treated with pERP. pERP patients were, on average, younger (13 versus 16 y), more likely to be ASA III (70% versus 30%), and more likely to receive regional (32% versus 3%) or neuraxial (35% versus 8%) anesthesia. Epidural use was an independent risk factor for longer length of stay (P = 0.000). After adjustment, pERP patients had similar LOS and time to oral intake, but shorter foley duration. pERP patients used significantly fewer opioids and were less likely to return to the operating room within 30 d. 30-d readmissions and ED visits were also lower, but this was not statistically significant. CONCLUSIONS: At our institution, data from both ERPs contributed formation of a synthesized pathway and reflected the pERP approach to opioid utilization and the aERP approach to earlier enteral nutrition.

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BACKGROUND: We hypothesized that an enhanced recovery after surgery (ERAS) pathway for pediatric patients undergoing surgery for inflammatory bowel disease (IBD) would be beneficial. METHODS: This is a single institution retrospective comparative study comparing patients treated with an ERAS pathway to consecutive patients in a Preimplementation Cohort (PIC) with similar open and laparoscopic surgeries for IBD. The pathway emphasized minimal preoperative fasting, multimodal and regional analgesia, and early enteral nutrition after surgery. Primary endpoints were time to 120 mL of PO intake (POI), length of stay (LOS), opioid utilization, and 30-day surgical outcomes. Continuous and categorical variables were compared (p < 0.05). RESULTS: There were 23 PIC and 28 ERAS patients with similar demographic data and surgical and anesthetic approaches. ERAS patients experienced a significant increase in the use of regional anesthesia, faster time to POI, and a nonsignificant decrease in mean LOS. ERAS patients had decreased total and daily opioid use with similar complication rates. CONCLUSION: This study demonstrates the effectiveness of a pediatric ERAS pathway for IBD patients requiring laparoscopic and (unique to this study) open surgery. The study demonstrates that opioid utilization and time to feeding can be positively impacted using ERAS pathways without negatively impacting outcomes. TYPE OF STUDY: Retrospective comparative study. LEVEL OF EVIDENCE: Level III.

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1. Loose-patch voltage-clamp recordings were made from rat and mouse skeletal muscle fibres denervated for up to 6 weeks. Innervated muscles possessed a Na+ current density of 107 +/- 3.3 mA cm-2 in endplate membrane, and 6.3 +/- 0.6 mA cm-2 in extrajunctional membrane. This high concentration of Na+ channels at the endplate was gradually reduced following denervation. After 6 weeks of denervation, the endplate Na+ channel concentration was reduced by 40-50%, and the density of Na+ channels in extrajunctional membrane was increased by about 30%. 2. The tetrodotoxin (TTX)-resistant form of the Na+ channel appeared after 3 days of denervation and comprised approximately 43% of the endplate Na+ channels 5-6 days after denervation. Subsequently, TTX-resistant Na+ channels were reduced in density to approximately 25% of the postjunctional Na+ channels and remained at this level up to 6 weeks after denervation. 3. RNase protection analysis showed that mRNA encoding the TTX-resistant Na+ channel was virtually absent in innervated muscle, rose > 50-fold after 3 days of denervation, then decreased by 95% 6 weeks after denervation. The density of TTX-resistant Na+ channels correlated qualitatively with changes in mRNA levels. 4. These results suggest that the density of Na+ channels at neuromuscular junctions is maintained by two mechanisms, one influenced by the nerve terminal and the other independent of innervation.

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The role of innervation in the establishment and regulation of the synaptic density of voltage-activated Na channels (NaChs) was investigated at regenerating neuromuscular junctions. Rat muscles were induced to degenerate after injection of the Australian tiger snake toxin, notexin. The loose-patch voltage clamp technique was used to measure the density and distribution of NaChs on muscle fibers regenerating with or without innervation. In either case, new myofibers formed within the original basal lamina sheaths, and, NaChs became concentrated at regenerating endplates nearly as soon as they formed. The subsequent increase in synaptic NaCh density followed a time course similar to postnatal muscles. Neuromuscular endplates regenerating after denervation, with no nerve terminals present, had NaCh densities not significantly different from endplates regenerating in the presence of nerve terminals. The results show that the nerve terminal is not required for the development of an enriched NaCh density at regenerating neuromuscular synapses and implicate Schwann cells or basal lamina as the origin of the signal for NaCh aggregation. In contrast, the change in expression from the immature to the mature form of the NaCh isoform that normally accompanies development occurred only partially on muscles regenerating in the absence of innervation. This aspect of NaCh regulation is thus dependent upon innervation.

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The clinical manifestation of myotonic dystrophy (DM) is correlated to the extent of expansion of an unstable [CTG]n DNA motif. Recent studies have demonstrated that this trinucleotide motif forms part of the last, 3' untranslated exon of a gene which potentially encodes multiple protein isoforms of a serine/threonine protein kinase (myotonic dystrophy protein kinase, DM-PK). We report here on the development of antisera against synthetic DM-PK peptide antigens and their use in biochemical and histochemical studies. Immunoreactive DM-kinase protein of 53 kD is present at low levels in skeletal and cardiac muscle extracts of DM patients and normal controls. Immunohistochemical staining revealed that DM-PK is localised prominently at sites of neuromuscular and myotendinous junctions (NMJs and MTJs) of human and rodent skeletal muscles. Furthermore, very low levels of immunoreactive DM-PK protein are present in the sarcoplasm of predominantly type I fibres in various muscles. Strikingly, presence of the protein can also be demonstrated for NMJs of muscular tissues of adult and congenital cases of DM, with no gross changes in structural organisation. Our findings provide a basis for further characterisation of the role of the kinase in protein assembly processes or signal mediation at synaptic sites and ultimately for the understanding of the complex pathophysiology of DM.

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The voltage-activated Na channel (NaCh) is an integral membrane protein that is enriched at the neuromuscular end plate. Using loose-patch voltage-clamp and immunofluorescence, we have found that the aggregation of NaChs occurs late, during maturation of the neuromuscular junction. A decline in expression of embryonic NaCh mRNA and increase in adult NaCh mRNA precedes the onset of aggregation, and the appearance of functional adult NaChs coincides with NaCh aggregation. We tested the possibility that only the adult NaCh subtype could aggregate during development and found that both the embryonic and adult isoforms become concentrated at the synapse. The NaCh is the first postsynaptic membrane protein shown to become clustered postnatally, and the mechanism producing this aggregation appears to be different from the process producing aggregation of other synaptic proteins.

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Myotubes of the C2 mouse muscle cell line form clusters of ACh receptors (AChRs) at apparently random sites along their length when cultured alone, and near sites of nerve-muscle contact when cocultured with neurons. We find in aneural cultures that myotubes of a C2 variant, S27, which is defective in glycosaminoglycan synthesis, express the AChR on their surface, but do not form clusters. S27 cells in aneural cultures also express the 43 kDa protein but do not cluster it. The altered distribution of laminin and collagen IV on the surface of S27 myotubes suggests that the basal lamina is abnormal. Neither the addition of exogenous proteoglycans or conditioned medium from wild-type C2 cells, nor the growth of S27 cells on substrates rich in basal lamina elements caused clusters to appear on S27 myotubes in aneural cultures. When cultured with primary neurons, however, S27 myotubes formed large clusters of the AChR near sites of neurite contact. The clusters were coincident with patches of the 43 kDa protein. Prelabeling experiments indicate that at least some AChRs in the clusters arise through aggregation. Although Torpedo agrin induces AChR clusters on C2 myotubes, it does not do so on S27 cells. Our experiments suggest that the spontaneous formation of clusters of AChRs and the 43 kDa protein in aneural cultures of myotubes depends upon the normal synthesis of muscle proteoglycans, and that nerve-induced clustering does not. Thus, there appear to be multiple mechanisms for the formation of AChR clusters.

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Sodium channel distributions were measured in fast and slow twitch rodent skeletal muscle fibres using the loose patch voltage clamp technique. Large differences were found between these fibre types with respect to Na channel density in the perijunctional region. Fast twitch fibres exhibited a large increase in Na channel density near the endplate, while slow twitch fibres did not.

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We used the loose patch voltage clamp technique and rhodamine-conjugated alpha-bungarotoxin to study the regulation of Na channel (NaCh) and acetylcholine receptor (AChR) distribution on dissociated adult skeletal muscle fibers in culture. The aggregate of AChRs and NaChs normally found in the postsynaptic membrane of these cells gradually fragmented and dispersed from the synaptic region after several days in culture. This dispersal was the result of the collagenase treatment used to dissociate the cells, suggesting that a factor associated with the extracellular matrix was responsible for maintaining the high concentration of AchRs and NaChs at the neuromuscular junction. We tested whether the basal lamina protein agrin, which has been shown to induce the aggregation of AChRs on embryonic myotubes, could similarly influence the distribution of NaChs. By following identified fibers, we found that agrin accelerated both the fragmentation of the endplate AChR cluster into smaller patches as well as the appearance of new AChR clusters away from the endplate. AChR patches which were fragments of the original endplate retained a high density of NaChs, but no new NaCh hotspots were found elsewhere on the fiber, including sites of newly formed AChR clusters. The results are consistent with the hypothesis that extracellular signals regulate the distribution of AChRs and NaChs on skeletal muscle fibers. While agrin probably serves this function for the AChR, it does not appear to play a role in the regulation of the NaCh distribution.

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The distribution of neurofilament (NF) and synaptic vesicle (SV) proteins in neurites cultured in vitro was visualized with immunocytochemical methods. NF and SV proteins were detected in neurites from both embryonic mouse spinal cord and chick ciliary ganglion neurons. NF proteins generally occupied more proximal, unbranched neurite segments while SV proteins were most often found in highly branched terminal segments. Neurites from mouse spinal cord cells showed a striking segregation of the NF and SV proteins into distinct domains; neurites from chick ciliary ganglion cells exhibited a similar, though less pronounced segregation. In cocultures of neurons and muscle cells, the neurite segments in contact with myotubes more often stained for SV than for NF while the opposite was true for neurites not in contact with myotubes. The preferential association of SV neurites with myotubes was also observed when the myotubes were previously fixed with paraformaldehyde. This association was absent in neurites growing over Chinese hamster ovary cells, suggesting that the effect is specific for muscle cells. Coculture of neurons with variant strains of C2 myotubes that are deficient in AChR (1R-) or proteoglycans (S27) revealed a preferential association of SV neurites with 1R- myotubes but not with S27 myotubes. Thus, proteoglycans on the surface of C2 myotubes may influence the growth and/or differentiation of presynaptic neurons.

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Antibodies to synaptic vesicle (SV) proteins and to neurofilament (NF) proteins were used to investigate presynaptic differentiation and its relation to the formation of acetylcholine receptor (AChR) clusters at developing mouse neuromuscular junctions. At all times during development, SV proteins and NF proteins were segregated into neighboring, but separate regions of the presynaptic neurite. At embryonic day (ED) 14 SV proteins were present throughout preterminal neurites but at later ages became progressively restricted to the distal parts of the neurites. NF proteins occupied a more proximal region that extended distally during development until NF proteins occupied the entire axon up to the terminal. The restriction of SV proteins exclusively to the terminal did not occur until the second postnatal week. At the time of their first appearance (ED 14), up to 50% of AChR clusters were not associated with neurites; precise colocalization required 12-36 hr to develop. These findings demonstrate a progressive restriction of both pre- and postsynaptic components to the synapse during development.

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The drug 2-(4-phenylpiperidino)cyclohexanol (AH5183), which potently inhibits the active transport of acetylcholine (ACh) into synaptic vesicles, was used as a pharmacological tool to study the functional role of synaptic vesicles in quantal transmitter release. Using microelectrode recording techniques, miniature endplate potentials (mepps) and nerve-evoked endplate potentials (epps) were recorded from frog cutaneous pectoris neuromuscular junctions in low Ca2+/high Mg2+ Ringer solution, and in normal Ringer with added D-tubocurarine (D-TC). Stimulation in the presence of AH5183 caused a 40% reduction in quantal size (mepp amplitude), depressed tetanic potentiation, and decreased the number of quanta released with each nerve impulse in the presence of D-TC. All of these effects appeared gradually and only after extended stimulation of the nerve, during which several hundred thousand quanta were released. Consequently, these findings suggest a serial one-time usage of vesicles, with little or no re-entry of recycled vesicles until after a large fraction of the original vesicles has been exhausted. The results primarily show that filling of synaptic vesicles with ACh is crucial for sustaining synaptic transmission, and gives further evidence that the ACh released by nerve impulses originates from these organelles.

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Several different types of acetylcholine secretion have been shown to coexist at the neuromuscular junction along with the Ca2+-dependent quantal release producing miniature endplate potentials (mepps) and endplate potentials. One of these, the Ca2+-insensitive, slow-rising mepps (slow mepps), is present in normal untreated muscles but is most prominent in many conditions where the Ca2+-dependent quantal release mechanism is not functioning properly. Slow mepps occur at a frequency of less than 0.1 Hz in normal muscles, with large variability between fibres and muscles, and can reach frequencies of 1-2 Hz in several pathological conditions. The potentials are also highly variable in size and shape, being generally of high amplitude (0.1-15 mV) and prolonged time course (1-15 ms rise time). Most importantly, slow mepps are not affected by procedures which increase the intraterminal Ca2+ concentration, including nerve stimulation, thus being unable to contribute to the function of synaptic transmission. The cellular source of the Ca2+-insensitive mepps has been determined to be the nerve terminal and not the Schwann cells or nerve sprouts. The release process producing slow mepps is generally insensitive to many drugs, ions, and procedures, stimulation being observed with vinblastine, cytochalasin B, and caffeine. Depression of this secretion is effected by uncouplers of oxidative phosphorylation and by a drug (AH5183) which inhibits the vesicular active acetylcholine transport system. It is concluded that the slow mepps are due to an exocytic fusion of unique synaptic vesicles with the plasma membrane near the active zones, in a process insensitive to many intracellular ions and regulators. Since slow mepps are prominent in many pathological conditions of nerve and muscle, it is speculated that they play some role in the recovery or development of synaptic function.

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1. To study the nature and origin of slow-rising, Ca2+-insensitive miniature end-plate potentials (m.e.p.p.s) in mammalian muscle we used intracellular recording techniques and drugs which block acetylcholine (ACh) synthesis or the uptake of ACh into synaptic vesicles. Slow m.e.p.p.s were induced in vivo by paralysing the extensor digitorum longus muscle of the rat with botulinum toxin type A or in vitro by the application of 4-aminoquinoline to the mouse diaphragm nerve-muscle preparation. 2. Hemicholinium-3, which blocks ACh synthesis, reduced the amplitude of all synaptic potentials including slow m.e.p.p.s, but only if the nerve was stimulated. 3. 2(4-phenylpiperidino)cyclohexanol (AH-5183), which blocks the active uptake of ACh into synaptic vesicles, reduced both the frequency and the amplitude of slow m.e.p.p.s and did so without requiring nerve stimulation. 4. No correlation was observed between the molecular leakage of ACh from the motor nerve and the frequency and amplitude of slow m.e.p.p.s. 5. We conclude that slow m.e.p.p.s are caused by the release of ACh from the nerve terminal, possibly from a small pool of synaptic vesicle-like structures.

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A variety of pharmacologically active compounds was surveyed for effects on the Ca2+-insensitive miniature end-plate potentials (slow mepps) induced by botulinum toxin type A (Botx) poisoning in rat muscle. The purpose was to gain insight into the release process responsible for this type of acetylcholine secretion. It was found that caffeine and dibutyryl cyclic adenosine 3',5'-monophosphate increased significantly the frequency of slow mepps in Botx-poisoned muscles, but had no effect on slow mepps in control muscles. Vinblastine and cytochalasin B significantly increased the slow mepp frequency in Botx-poisoned as well as in normal control muscles. Inhibitors of oxidative metabolism reduced the frequency of slow mepps by 90%, indicating a high energy requirement for this type of release. No agent was found to augment the slow mepp frequency above 1-2 Hz, suggesting that an upper limit exists for this type of packaging and release of acetylcholine.

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The effects of denervation and long-term botulinum toxin type A (BoTx) poisoning on miniature end-plate potentials (m.e.p.p.s) in the frog were studied with intracellular microelectrode recording. BoTx reduced the frequency of m.e.p.p.s to less than 1% of the level seen in untreated frogs, leaving a large percentage of tiny m.e.p.p.s and slow-rising m.e.p.p.s (slow m.e.p.p.s). Unlike what is observed in the rat, the frequency of slow m.e.p.p.s never increased above the low rate measured in the untreated controls, and in fact slightly but significantly decreased after BoTx. A comparison of the m.e.p.p.s seen after BoTx poisoning (BoTx m.e.p.p.s) and m.e.p.p.s seen after denervation (Schwann m.e.p.p.s) revealed many similarities between the two including amplitude and time-to-peak distributions, temperature Q10 values and responses to several drugs and procedures. However, it was concluded that BoTx m.e.p.p.s do not originate from the Schwann cells because denervation of BoTx-paralysed frogs abolishes all m.e.p.p.s and the drug 4-aminoquinoline affects BoTx m.e.p.p.s and Schwann m.e.p.p.s in opposite ways, increasing the frequency of the former while almost eliminating the latter. BoTx m.e.p.p.s and Schwann m.e.p.p.s probably represent similar processes of secretion which are non-specific in nature, having a lower energy barrier than for normal release and not originating from specialized areas of transmitter release.

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