Daisuke Sanjo

Arterial Blood Pressure Regulation of Pulpal Blood Flow as Determined by Laser Doppler

Dynamic changes of pulpal blood flow (PBF) and gingival blood flow (GBF) induced by intra-venous injection of two kinds of vasoactive drugs were observed in dogs by means of Laser Doppler Velocimetry. Intra-venous injection of norepinephrine caused PBF to increase, corresponding to the blood pressure (BP) increase, while GBF decreased. Orciprenaline sulfate caused PBF to decrease parallel to the BP decrease, as compared with a GBF increase. The effects of these vasoactive drugs lasted longer on GBF than on PBF and BP. These results indicate that the regulation of blood flow in the dental pulp is more dependent on systemic blood pressure than on local vasoconstriction or vasodilation.

The nervous control of gingival blood flow in cats

The purpose of the present study was to investigate the nervous control of gingival blood flow in cats. Gingival blood flow was measured by laser Doppler flowmeter in 75 cats during electrical stimulation and cutting or ligation of the inferior alveolar nerve and cervical sympathetic nerve without sympathectomy or pretreatment with adrenoceptor blocking agents. Three different patterns of responses in gingival blood flow were observed following electrical stimulation of the inferior alveolar nerve in cats. In 45 cats there was an increase in blood flow, in 4 cats a decrease in blood flow, and in 7 cats a biphasic change consisting of an initial decrease and a successive increase in blood flow. The vasodilator effect was significantly reduced by pretreatment with (D-Pro2, D-Trp7.9)-substance P. tripelennamine, and methysergide. Pretreatment with cimetidine, atropine, hexamethonium, phentolamine, or propranolol had no effect on vasodilatation. The vasoconstrictor response was completely inhibited by pretreatment with phentolamine; in this case the vasodilator response appeared after stimulation of the inferior alveolar nerve. Ligation or cutting of the inferior alveolar nerve always elicited an increase in gingival blood flow. Cutting the cervical sympathetic nerve had no effect on gingival blood flow in 8 of 10 cats and caused an increase in gingival blood flow in 2 cats; however, electrical stimulation of the cervical sympathetic nerve always caused a decrease in gingival blood flow in the cats investigated. The present results suggest that cat gingival blood flow is controlled by sympathetic alpha-adrenergic fibers for vasoconstriction and by sensory fibers and mast cells for vasodilatation.

Absence of Parasympathetic Vasodilatation in Cat Dental Pulp

The existence and nature of parasympathetic nerve fibers in the dental pulp have long been a subject for discussion; indeed, vasodilator responses mediated by such nerve fibers have yet to be conclusively demonstrated in the dental pulp. This study was designed to determine whether parasympathetic vasodilator mechanisms do or do not exist in the cat dental pulp. Dynamic changes in pulpal blood flow (PBF), with mandibular lip blood flow (LBF) recorded as a control, were investigated in cat mandibular canine teeth by means of laser Doppler velocimetry. Peripheral trigeminal afferents (see below) were stimulated electrically to confirm that somato-parasympathetic reflex vasodilatation could be induced. The peripheral cut ends of the facial and glossopharyngeal nerve roots, which have been reported to contain parasympathetic nerve fibers to the oral tissues, were then stimulated intracranially. Electrical stimulation of trigeminal afferents (in the infra-orbital nerve or the maxillary buccal gingiva) caused no change in PBF but did increase ipsilateral LBF. Neither facial nor glossopharyngeal nerve root stimulation caused a PBF increase, though both elicited increases in ipsilateral LBF. The vasodilator responses in the lip were sensitive to ganglion blockade (with hexamethonium), indicating vasodilatation via activation of parasympathetic vasodilator fibers. In contrast, intracranial stimulation of the trigeminal nerve root induced increases in both PBF and LBF which were reduced by pre-treatment with tripelennamine, indicating antidromic vasodilatation via the trigeminal sensory nerve. These results suggest that a parasympathetic vasodilator mechanism is not present in feline dental pulp.

Axon Reflex Vasodilatation in Cat Dental Pulp Elicited by Noxious Stimulation of the Gingiva

Antidromic stimulation of sensory nerves has been shown to increase blood flow in the tissue they innervate. This study was designed to determine if antidromic vasomotor responses occur in feline dental pulp and if they are mediated by branched axons supplying both tooth pulp and gingiva. Dynamic changes in pulpal blood flow (PBF) elicited by electrical stimulation, pinching, heating, and capsaicin application to the gingivae were investigated in cat mandibular canine teeth by means of Laser Doppler Velocimetry. All inferior alveolar nerve bundles and the cervical sympathetic trunk had been previously sectioned to avoid the occurrence of brainstem reflexes, e.g., somato-autonomic vasomotor reflexes. Increases in PBF were observed in seven out of 12 cats when a restricted gingival area adjacent to the canine teeth was stimulated as described, but the increases were abolished after the sensitive gingival area was painted with lidocaine jelly, a surface anesthetic. These vasodilator responses, remarkably reduced following repeated application of 30 mM of capsaicin, are considered to be induced via antidromic activation of capsaicin-sensitive nociceptive nerve fibers, presumably by axon reflex mechanisms, suggesting that nerve terminals supplying the gingiva originate from parent axons which have collaterals that innervate the canine tooth pulp.

Clinical Studies on a Cold-Curing Dental Resin with a Tri-n-Butylborane Catalyst

A cold-curing dental resin with a tri-n-butylborane catalyst, which has a chemical adhesiveness to dentin, was studied histologically in 15 human teeth and tested clinically in 184 teeth. The effect on the pulp was slight, and clinical adhesiveness to the teeth was excellent.

An Application of Laser Doppler Velocimetry to Mesurement of Pulpal and Periodontal Ligament Blood Flow

To measure blood flow in the dental pulp and the periodontal ligament (PL), a Laser Doppler Velocimetry that consists of helium and neon Laser was applied to the canine teeth of dogs and cats.The following results were obtained:1. The pulpal blood flow (PBF) could be monitored noninvasively and continuously whenthe distance from the probe to the dental pulp was within 1 mm.According as this distancebecame shoter, PBF showed higher value.2. Electrical stimulation of the ipsilateral cervical sympathetic nerve induced prompt decrease in PBF according to the frequency of stimulation.3. To monitor PL blood flow, the labial bone overlying the mandibular canine tooth rootwas pared away, and apical area of PL blood flow was continuously monitored. Whenforce was applied labio-lingually to the incisal edge of the tooth, PL blood flow showedpromptly decrease, and PL blood flow promptly increased when force was applied linguoladiplly. These results indicate that Laser Doppler Velocimetry considered to be availablefor monitoring the pulpal and the periodontal ligament blood flow. (J.Jpn. Soc. Laser Dent. 4: 21-25, 1993 Reprint requests to Dr. Sasano)