Spinal maturation affects vertebral compressive mechanics and vBMD with sex dependence

Comparison of bone density patterns of the subaxial spine between chimpanzees and gorillas - A case study

Case study on the bone density pattern of subaxial vertebral column in African apes.

INTRODUCTION

African apes have been noted to experience fewer back ailments than humans and to have higher vertebral bone density. Yet, research on the subject is quite limited and has usually included only one or few vertebrae. However, to understand vertebral column as whole and how posture and locomotion might have affected it, we need to know how bone density varies between adjacent vertebrae.

MATERIALS AND METHODS

Bone density in the vertebral body was measured for all subaxial vertebrae of five specimens including two Pan troglodytes (1 male and 1 female) and three Gorilla gorilla (2 males and 1 female) using peripheral quantitative computed tomography (pQCT).

RESULTS

The results tentatively indicated differences between species, especially in the trabecular density of the cervical segment and support the need for further studies on this subject.

Mesenchymal Stem Cell-Specific and Preosteoblast-Specific Ablation of TSC1 in Mice Lead to Severe and Slight Spinal Dysplasia, Respectively

Background

TSC1-related signaling plays a pivotal role in intramembranous and endochondral ossification processes during skeletogenesis. This study was aimed at determining the significance of the TSC1 gene at different stages of spinal development. Materials and Methods. TSC1-floxed mice (TSC1^flox/flox) were crossed with Prrx1-Cre or BGLAP-Cre transgenic mice or mesenchymal stem cell- and osteoblast-specific TSC1-deficient mice, respectively. Somatic and vertebral differences between WT and Prrx1-TSC1 null mice were examined at 4 weeks after birth.

Results

No apparent body size abnormalities were apparent in newborn and 4-week- to 2-month-old mice with BGLAP-Cre driver-depleted TSC1. Vertebral and intervertebral discs displayed strong dysplasia in Prrx1-TSC1 null mice. In contrast, vertebrae were only slightly affected, and intervertebral discs from skeletal preparations displayed no apparent changes in BGLAP-TSC1 null mice.

Conclusion

Our data suggest that the TSC1 gene is crucial for endochondral ossification during postnatal spine development but plays discriminative roles at different stages. Mesenchymal stem cell-specific ablation of TSC1 led to severe spinal dysplasia at early stages of endochondral ossification while osteoblast-specific deletion of TSC1 affected vertebrae slightly and had no detectable effects on intervertebral discs.

Spine trauma in very young children: a retrospective study of 206 patients presenting to a level 1 pediatric trauma center

BACKGROUND

The immature spine has anatomic and biomechanical properties that differ from the adult spine and result in unique characteristics of pediatric spinal trauma. Although distinct patterns of spinal injury have been identified in children younger than 10 years of age, little research has explored the differing characteristics of spinal trauma within this age group, particularly in the very young. The purpose of this study is to identify differences in the epidemiology and characteristics of spinal trauma between children under the age of 4 years and those between 4 and 9 years of age.

METHODS

A review of all patients treated for spinal injury at a single large level I pediatric trauma center between 2003 and 2011 was conducted. Demographic data, injury mechanism, neurologic status, and details of any associated injuries were compiled. Radiographic studies were used to determine injury location and fracture classification. The patient population was divided into 2 groups: the infantile/toddler (IT) group (ages 0 to 3 y) and the young (Y) group (ages 4 to 9 y). Data were compared between these groups using the χ2 test and the Student t test to identify differences in injury characteristics.

RESULTS

A total of 206 patients were identified. Fifty-seven patients were between 0 and 3 years of age and 149 were between 4 and 9 years old. Although motor vehicle collision was the most common cause of injury in both the groups, nonaccidental trauma was responsible for 19% of spine trauma among patients aged 0 to 3 years. Cervical spine injuries were much more common in the youngest patients (P<0.05) with injuries primarily in the upper cervical spine. Children in the IT group were more likely to sustain ligamentous injuries, whereas Y patients had more compression fractures (P<0.05). Neurologic injury was common in both the groups with IT patients more often presenting with complete loss of function or hemiplegia and Y patients sustaining more spinal cord injuries (P<0.05). IT patients had a 25% mortality rate, which was significantly higher than that of the Y group (P=0.005).

CONCLUSIONS

This study shows many significant differences in characteristics of spinal injury in infants/toddlers when compared with older children. These differences can help guide diagnostic evaluation and initial management, as well as future prevention efforts.

LEVEL OF EVIDENCE

Level III.

Early Trabecular Development in Human Vertebrae: Overproduction, Constructive Regression, and Refinement

Early bone development may have a significant impact upon bone health in adulthood. Bone mineral density (BMD) and bone mass are important determinants of adult bone strength. However, several studies have shown that BMD and bone mass decrease after birth. If early development is important for strength, why does this reduction occur? To investigate this, more data characterizing gestational, infant, and childhood bone development are needed in order to compare with adults. The aim of this study is to document early vertebral trabecular bone development, a key fragility fracture site, and infer whether this period is important for adult bone mass and structure. A series of 120 vertebrae aged between 6 months gestation and 2.5 years were visualized using microcomputed tomography. Spherical volumes of interest were defined, thresholded, and measured using 3D bone analysis software (BoneJ, Quant3D). The findings showed that gestation was characterized by increasing bone volume fraction whilst infancy was defined by significant bone loss (≈2/3rds) and the appearance of a highly anisotropic trabecular structure with a predominantly inferior-superior direction. Childhood development progressed via selective thickening of some trabeculae and the loss of others; maintaining bone volume whilst creating a more anisotropic structure. Overall, the pattern of vertebral development is one of gestational overproduction followed by infant "sculpting" of bone tissue during the first year of life (perhaps in order to regulate mineral homeostasis or to adapt to loading environment) and then subsequent refinement during early childhood. Comparison of early bone developmental data in this study with adult bone volume values taken from the literature shows that the loss in bone mass that occurs during the first year of life is never fully recovered. Early development could therefore be important for developing bone strength, but through structural changes in trabecular microarchitecture rather than bone mass.

Developmental biomechanics of neck musculature

Neck mechanics is central to head injury prevention since it is the musculoskeletal neck, which dictates the position and movement of the head. In the US, traumatic injury is the leading cause of death for children; however prevention is hampered by the lack of data concerning the mechanics of the immature head-and-neck. Thus, the objective of this study was to quantify neck muscle strength and endurance across the maturation spectrum and correlate these with head-and-neck anthropometry. A factorial study was performed on 91 human subjects measuring head-and-neck anthropometry and neck strength and endurance in three bending directions (flexion, extension, and lateral) as a function of age (6-23 years). Using a custom device, neck maximum voluntary contraction (MVC) force was measured in triplicate. Next, neck muscle endurance (sustained effort) was measured as the subjects' ability to maintain 70% of peak force over 30s. Linear regression of peak force and endurance as a function of age revealed each direction to significantly (p<0.0001) increase with age. The MVC force, averaged across all directions and normalized to the adult values, exhibits the following maturation curve: %MVC Force=-0.0879(age)(2)+6.018(age)+8.120. Neck muscle strength, similar between young males and females, becomes disparate in adolescence and adulthood with males exhibiting greater strength. Bending direction differences were also found with extension strength being the greatest regardless of age and sex. Furthermore, neck circumference appears predictive of neck strength and endurance in children. Together, these relationships may facilitate improved design of injury prevention interventions.

Biomechanics of the toddler head during low-height falls: an anthropomorphic dummy analysis

OBJECT

Falls are the most common environmental setting for closed head injuries in children between 2 and 4 years of age. The authors previously found that toddlers had fewer skull fractures and scalp/facial soft-tissue injuries, and more frequent altered mental status than infants for the same low-height falls (<or=3 ft).

METHODS

To identify potential age-dependent mechanical load factors that may be responsible for these clinical findings, the authors created an instrumented dummy representing an 18-month-old child using published toddler anthropometry and mechanical properties of the skull and neck, and they measured peak angular acceleration during low-height falls (1, 2, and 3 ft) onto carpet pad and concrete. They compared these results from occiput-first impacts to previously obtained values measured in a 6-week-old infant dummy.

RESULTS

Peak angular acceleration of the toddler dummy head was largest in the sagittal and horizontal directions and increased significantly (around 2-fold) with fall height between 1 and 2 ft. Impacts onto concrete produced larger peak angular accelerations and smaller impact durations than those onto carpet pad. When compared with previously measured infant drops, toddler head accelerations were more than double those of the infant from the same height onto the same surface, likely contributing to the higher incidence of loss of consciousness reported in toddlers. Furthermore, the toddler impact forces were larger than those in the infant, but because of the thicker toddler skull, the risk of skull fracture from low-height falls is likely lower in toddlers compared with infants.

CONCLUSIONS

If similar fracture limits and brain tissue injury thresholds between infants and toddlers are assumed, it is expected that for impact events, the toddler is likely less vulnerable to skull fracture but more vulnerable to neurological impairment compared with the infant.

Traumatic spinal cord injury: accidental versus nonaccidental injury

A 21-month-old boy with steroid-dependent asthma presented to the emergency room with Glascow Coma Score (GCS) 3 and retinal hemorrhages. He was found to have subdural and subarachnoid hemorrhage on computed tomography plus findings of hypoxic-ischemic encephalopathy (HIE). The caretaker history was thought to be inconsistent with the clinical and imaging features, and the patient was diagnosed with nonaccidental injury (NAI) and "shaken baby syndrome." The autopsy revealed a cranial impact site and fatal injury to the cervicomedullary junction. Biomechanical analysis provided further objective support that, although NAI could not be ruled out, the injuries could result from an accidental fall as consistently described by the caretaker.

Osteopenia and osteoporosis in adult baboons (Papio hamadryas)

BACKGROUND

Little is known about the degree to which baboons, an important animal model in skeletal research, spontaneously experience age-related osteopenia and osteoporosis.

METHODS

We measured bone mineral density (BMD) in 667 baboons, assigned T-scores to older animals based on sex-specific young adult reference groups, and compared reproductive history in older females with low BMD to those with normal BMD.

RESULTS

Approximately 25% of older baboon females were osteopenic. No females or males were osteoporotic. Neither parity nor interbirth interval spine clearly distinguished low vs. normal BMD groups. Intersite correspondence in low BMD was highest between sites in the same region rather than sites of the same bone type.

CONCLUSION

As with humans, osteopenia is common among older females. The absence of osteoporotic animals may be due to colony maintenance resulting in truncation of the aged population and selection for healthier animals in the oldest ranges.

Contrasting biomechanics and neuropathology of spinal cord injury in neonatal and adult rats following vertebral dislocation

Clinically, spinal cord injuries (SCI) in infants are different from SCIs in adults. SCI is rarer in infants, and the most common types of associated spinal column injury are different for adults and infants. Initially, infants tend to have higher injury severities and mortality; however, young survivors of SCI typically have greater and more rapid functional recovery. The objective of this study was to contrast the biomechanics and neuropathology of SCI in adult and neonatal rats to investigate these differences. Thoracolumbar vertebrae of anaesthetized rats were dislocated laterally (T12 held stationary and L1 displaced laterally, with T13 between these levels) by 10 mm at 250 mm/sec in adults and by 4 mm at 100 mm/sec in neonates (13-15 days), and rats were euthanized 6 h later. Spinal cord sections were stained to detect hemorrhage (with hematoxylin and eosin [H&E]), axonal injury (with beta-amyloid precursor protein [betaAPP]), and neuronal nuclei (with NeuN). Maximum load was significantly higher in adults (25.7 +/- 2.4N) than neonates (11.0 +/- 2.4N; p < 0.001). Adult and neonatal hemorrhage volumes were not significantly different for either the raw or normalized data sets (p = 0.064 for normalized dataset). Un-normalized axonal injury densities were similar for adults and neonates, but normalized axonal injury density was significantly higher in neonates (p < 0.001). Reduction of NeuN immunoreactivity was significantly lower in neonates, for both un-normalized (p < 0.004) and normalized (p < 0.001) data sets. The findings of this study may explain the different common types of spinal column injury associated with SCI, and the greater initial severity of SCI in infants.

Immature sheep spines are more flexible than mature spines: an in vitro biomechanical study

STUDY DESIGN

Dynamic triaxial biomechanical testing of immature and mature ovine spine motion segments.

OBJECTIVE

To compare torque-deflection parameters of mature and immature spine motion segments and to investigate whether scaling relationships apply between mature and immature motion segment torque-deflection responses.

SUMMARY OF BACKGROUND DATA

While previous studies have examined the cervical region in a limited number of loading directions, a comprehensive multiaxial study of the response of the pediatric spine at all 3 spinal levels (cervical, thoracic, and lumbar) has not been performed.

METHODS

Motion segments from cervical, thoracic, and lumbar levels were tested under moment application about 3 axes for newborn and 2-year-old sheep. Range of motion, neutral zone, and stiffness were calculated for each motion segment and compared for immature and mature spine.

RESULTS

Immature spine motion segments exhibited a significantly larger range of motion (P < 0.001) and neutral zone (P < 0.001) and significantly lower stiffness (P < 0.001) in comparison to mature spine segments about the 3 moment axes, at the 3 spinal levels tested. There were statistically significant interactions between specimen age and the moment axis and/or spinal level for some torque-deflection parameters.

CONCLUSION

The significantly greater neutral zone of immature spine suggests greater ligament laxity. Significantly higher range of motion and lower stiffness of the immature spine may be implicated in spinal cord injury mechanisms and implies a change in relative tolerance of the spine to damage with spinal maturity. Significant statistical interactions between spinal maturity and moment axis or motion segment level suggest that scaling torque-deflection parameters from mature to immature spine may not be appropriate.

Neural space and biomechanical integrity of the developing cervical spine in compression

STUDY DESIGN

A factorial study design was used to examine the biomechanical and neuroprotective integrity of the cervical spine throughout maturation using a postmortem baboon model.

OBJECTIVE

To investigate changes with spinal development that affect the neuroprotective ability of the cervical spine in compressive loading.

SUMMARY OF BACKGROUND DATA

Child spinal cord injuries claim and debilitate thousands of children in the United States each year. Many of these injuries are diagnostically and mechanistically difficult to classify, treat, and prevent. Biomechanical studies on maturing spinal tissues have identified decreased stiffness and tolerance characteristics for children compared with adults. Unfortunately, while neurologic deficit typically dictates functional outcome, no previous studies have examined the neuroprotective role of the pediatric cervical spine.

METHODS

Twenty-two postmortem baboon cervical spines across the developmental age spectrum were tested. Two functional spinal unit segments (Oc-C2, C3-C5, and C6-T1) were instrumented with transducers to measure dynamic changes in the spinal canal. These tissues were compressed to 70% strain dynamically, and the resultant mechanics and spinal canal occlusions were recorded.

RESULTS

Classic injury patterns were observed in all of the specimens tested. The compressive mechanics exhibited a significant age relationship (P < 0.0001). Furthermore, while the peak-percent spinal canal occlusion was not age dependent, the percent occlusion just before failure did demonstrate a significant decrease with advancing age (P = 0.0001).

CONCLUSIONS

The neuroprotective ability of the cervical spine preceding failure appears to be age dependent, where the young spine can produce greater spinal canal occlusions without failure than its adult counterpart. The overall percent of the spinal canal occluded during a compression injury was not age dependent; however, these data reveal the neuroprotective ability of the child spine to be more sensitive as an injury predictor than the biomechanical fracture data.