Blocked Atlantal Nerve Syndrome in Babies and Infants

Children – Research

The following has been copied straight from the Council on Chiropractic Exercise, Clinical Exercise Guidelines, Vertebral Subluxations in Chiropractic Do, pages 87 – 93.

CHIROPRACTIC CARE FOR CHILDREN

RECOMMENDATION

Since vertebral subluxation may affect individuals at any historic period, chiropractic care may be indicated at whatsoever time after nativity. As with any age group, however, care must be taken to select aligning methods well-nigh appropriate to the patient's stage of evolution and overall spinal integrity. Parental instruction by the subluxation-centered chiropractor concerning the importance of evaluating children for the presence of vertebral subluxation is encouraged.

Rating: Established

Evidence: E, L

Commentary

Schneier and Burns(1) published the results of a blinded study describing the human relationship of atlanto-occipital hypermobility to sudden baby death syndrome (SIDS). These authors described the phenomenon of atlas inversion where the posterior arch of C-1 enters the foramen magnum. They further stated, Relative measurements suggested that a correlation existed betwixt instability in the atlanto-occipital articulation and sudden babe expiry syndrome. Instability is a manifestation of vertebral subluxation.

These findings corroborate those of Gilles, Bina and Sotrel in their paper, Infantile atlanto-occipital instability.(2) These investigators studied 17 infant cadavers. Eleven were SIDS cases and six were not-SIDS cases. Ten of the 17 cases demonstrated atlas inversion, and all ten cases were in the SIDS group. These authors also suggested that atlanto-occipital instability may be a cistron in other atmospheric condition. They stated, At this early phase in the development of our notions about the potential contribution of atlanto-occipital instability to deaths in infants, it is very difficult to assess the role of this proposed mechanism in the death of an infant with a conventional disease. Thus, one might anticipate that the controls will be contaminated by children who had a conventional illness, but whose death was, in fact, acquired past this mechanism.

Towbin(three) addressed the clinical significance of spinal cord and encephalon stem injury at nativity, noting that such damage is often latent and undiagnosed. Co-ordinate to Towbin, Decease of the fetus may occur during delivery or, with respiratory role depressed, a short catamenia afterwards birth. Infants who survive the initial effects may exist left with severe nervous system defects. In some, the neurologic sequellae are attributable directly to the main lesion in the cord or brain stem; in others, secondary cerebral damage results, a consequence of the imposed period of hypoxia at birth. Chesire(4) described three cases of traumatic myelopathy in children without demonstrable vertebral trauma. In this paper, the classical mechanism of trauma is said to be hyperextension of the cervical spine in a hard breech delivery. Although tetraplegia may outcome, the x-rays are described as commonly normal. Complicated deliveries stand for a higher risk to the child of suffering spinal cord impairment during the birth process. High cervical spinal cord injury in neonates is a specific complication of forceps rotation. The vacuum extractor exerts considerable traction force. Fetal skull fracture can result, and its truthful incidence may be higher than expected, considering that few neonates with normal neurologic beliefs undergo skull x-ray.(v-7) Byers(8) published an excellent review paper addressing spinal cord harm during the nascency process. Traction and rotational stresses practical to the spinal axis were listed equally causes of spinal cord injury during birth.

The vagus nerve is involved in mechanisms associated with control of tidal book, breathing rate, and respiratory reflexes. Sachis et al.(9) performed histological examinations of the vagus nerve in infants who died of SIDS and those who died of other conditions. Significant differences were noted between the ii groups. Several hypotheses were proposed by authors to explain the data, including harm to the vagus nerve resulting in delayed development.

Gutman(10) described how relational disturbance between occiput and atlas can atomic number 82 to blocked atlantal nerve syndrome in children and adults. The author listed a variety of atmospheric condition which appear clinically related to this syndrome. Although SIDS was not discussed as an entity, the author stated that a encephalon stalk component is a office of this syndrome. Information technology was concluded that for those affected, manual treatment past a qualified practitioner is appropriate.

In her paper Physical stresses of childhood that could lead to need for chiropractic care, presented at the start National Briefing on Chiropractic and Pediatrics, McMullen(eleven) stated, Any condition that arises to change the normal birth process frequently results in subluxation at the level of greatest stress. Severe subluxation resulting in nervus harm may be clinically obvious at nativity (e.g., Bells, Erbs and Klumpkes palsies), however, more frequently the trauma remains subclinical with symptoms arising at a later fourth dimension. These symptoms include, simply are not express to, irritability, colic, failure-to-thrive syndromes, and those syndromes associated with lowered allowed responses. These subluxations should be analyzed and corrected as shortly as possible after birth to forestall these associated conditions.

Bonci and Wynne(12) and Stiga(13) published papers discussing the human relationship betwixt chiropractic theory and SIDS etiology. Banks et al.(14) stated Functional disturbances in the brainstem and cervical spinal cord areas related to the neurophysiology of respiration may contribute the clinical factors associated with sudden baby death syndrome…Any process, whether genetic, biochemical, biomechanical or traumatic, that alters normal development of the respiratory command centers related to spinal constriction and compression following nascence trauma may be contributory to sudden babe death syndrome.

Other traumatic events of childhood may produce vertebral subluxations. Orenstein et al.(15) did a retrospective nautical chart review involving 73 children who presented at a children's hospital with cervical spine injuries. Sixty-seven pct of these injuries were traffic related resulting from motor-vehicle crashes. The injured children were passengers in an automobile, pedestrians, or bicyclists. The mean historic period of the patients surveyed was eight.half-dozen years, with bimodal peaks at two to 4 and 12 to fifteen years. The authors noted that younger children sustained more severe injuries than older children. Distraction and subluxation injuries were the most mutual injuries in children aged 8 years and younger. Fractures were more common in older children.

Glass et al.(16) evaluated 35 children with lumbar spine injuries post-obit blunt trauma. Thirty-one of these children were injured in motor-vehicle crashes. Abnormalities noted on manifestly radiographs and CT scans included subluxation, lark, and fracture lone or in combination. The authors stated, Children involved in motor-vehicle crashes are at a high risk for lumbar spine injuries Lumbar spine radiographs are necessary in all cases with suspected lumbar spine injury This paper underscores the need to evaluate the entire spine in cases of motor-vehicle accidents, non but the cervical region. It may be cited when claims for lumbar radiographs are questioned in cases of children involved in auto accidents.

Rachesky et al.(17) reported that on the cervical spine radiographs of children under 18 they examined, vehicular accidents accounted for 36% of radiographic abnormalities. Information technology was further stated that clinical cess of a complaint of neck pain or involvement in a vehicular accident with head trauma would have identified all cases of cervical spine injury.

Other authors have described aspects of cervical spine injuries in children involved in motor-vehicle accidents. Hill et al.(18) noted that 31% of the pediatric cervix injuries reviewed were the event of motor-vehicle accidents. In younger children (under 8 years of age) subluxation was seen more frequently than fracture. Agran(19) stated that non-crash vehicular events may cause injuries to children. Non-crash events discussed in this paper included sudden stops, swerves, turns, and movement of unrestrained children in the vehicle.

Roberts et al.(20) described a case where a child involved in a motor-vehicle blow sustained a whiplash injury resulting in immediate neck and back hurting. Neurobehavioral abnormalities increased in the two-year period following the accident. Four years afterwards the accident, symptoms persisted. Position emission tomography (PET scan) demonstrated evidence of brain dysfunction.

The clinical manifestations of pediatric cervical spine injury may be diverse. Biedermann(21) stated that a wide range of pediatric symptomatology may event from suboccipital strain. The disorders reported include fever of unknown origin, loss of appetite, sleeping disorders, asymmetric motor patterns, and alterations of posture. Maigne(22) stated that trauma to the cervical spine and head tin can cause such problems as headaches, vestibular troubles, auditory issues and psychic disturbances. Gutmann(23) discussed the diverse assortment of signs and symptoms which can occur as a result of biomechanical dysfunction in the cervical spine. Others accept also reported various pathoneurophysiological changes in children,(24-31) as well every bit reduction of pathology following chiropractic intendance.(29,31-41,44) In the chiropractic literature, Clow(42) published a paper addressing pediatric cervical acceleration/deceleration injuries.

Two peer reviewed journals, Chiropractic Pediatrics and the Journal of Clinical Chiropractic Pediatrics are existence published to disseminate critically reviewed papers in this field. Additionally, courses in pediatrics are offered at the professional and postgraduate levels at accredited chiropractic colleges and by the International Chiropractic Pediatric Clan.

The pediatric example history and physical examination necessarily differ in content and scope from those of developed patients. Even taking into consideration the difference between the ii populations, however, a contempo quasi meta-analysis reveals an extremely low risk for chiropractic pediatric patients receiving adjustments.(43)

References

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23. Abroms IF, Bresnan MJ, Zuckerman JE, Fischer EG, Strand R. Cervical string injuries secondary to hyperextension of the head in breech presentations. Obstet Gynecol 1973; 41(three):369-378.
24. Glasauer Fe, Cares HL. Biomechanical features of traumatic paraplegia in infancy. J of Trauma 1973; 3(ii):166-170.
25. Okumura H, Homma TT. Juvenile compression myelopathy in the cervical spine. Spine 1994; 19(1):72-76.
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27. Ono K, et al. Atlantoaxial rotatory fixation: radiographic study of its mechanism. Spine 1985; 10(7):602-608.
28. Harris SL, Forest KW. Resolution of infantile Erbs palsy utilizing chiropractic treatment. J Manipulative Physiol Ther 1993; xvi(vi):415-418.
29. BenEliyahu DJ. The detection and management of pediatric whiplash injuries. Proceedings of the National Conference on Chiropractic & Pediatrics October 1993; Palm Springs, ICA publisher, 53-57.
30. Araghi H. Post-traumatic evaluation and treatment of the pediatric patient with head injury: a case report. Proceedings of the National Conference of Chiropractic & Pediatrics. November 1992; ICA publisher. Colorado Springs 1-8.
31. Peet P. Child with chronic illness: respiratory infections, ADHD, and fatigue. Response to chiropractic care. Chiropractic Pediatrics 1997; 3(1):12.
32. Reed WR, et al. Chiropractic management of chief nocturnal enuretic children. In: Proceedings of the 3rd National Conference of Chiropractic and Pediatrics. Arlington, VA: ICA publisher 1993:64-82.
33. Hudgkins DJ, et al. Evaluation and chiropractic treatment of the pediatric patient with nocturnal enuresis: a case report. In: Proceedings of thyromegaly 4th National Conference on Chiropractic and Pediatrics. Arlington, VA. ICA publisher 1994:80-84.
34. Bachman T, Lantz CA. Management of pediatric asthma and enuresis with probable traumatic etiology. In: Proceedings of the 1st National Conference on Chiropractic and Pediatrics, Arlington, VA: ICA publisher 1991:xiv-22.
35. Nilsson N, Christiansen B. Prognostic factors in bronchial asthma in chiropractic do. J Aust Chiro Assoc 1988; eighteen(3):85-87.
36. Vernon LF, Vernon G. A scientific hypothesis for the efficacy of chiropractic manipulation in the pediatric asthmatic patient. Chiropractic Pediatrics 1995; 1(4):7-8.
37. Langley C. Epileptic seizures, nocturnal enuresis, ADD. Chiropractic Pediatrics 1994; 1(1):21-22.
38. Klougart N, et al. Infantile colic treated by chiropractors: a prospective study of 316 cases. J Manip Physiol Ther 1989; 12(iv):281-288.
39. Nilsson N. Babe colic and chiropractic. Eur J Chir 1985; 33(4):264-265.
40. Graham RL, Pistolese RA. An impairment rating assay of asthmatic children under chiropractic care. Journal of Vertebral Subluxation Inquiry 1997; 1(iv):41-48.
41. Clow BJE: Pediatric cervical acceleration/deceleration injuries. Journal of Clinical Chiropractic Pediatrics 1996; i(1):36.
42. Pistolese RA. Risk cess of neurological and/or vertebrobasilar complications in the pediatric chiropractic patient. Periodical of Vertebral Subluxation Enquiry 1998; 2(2):In press.
43. Blum M, Holder JM. Attending arrears disorders (ADD). Biogenic aspects. Chiropractic Pediatrics 1994; ane(ii):21-23.

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