Shaken baby syndrome: a biomechanics analysis of injury mechanisms.

Bandak FA.

Department of Neurology, A1036 F. Edward Hébert School of Medicine, Uniformed Services, University of the Health Sciences, 4301 Jones Bridge Road, Bethesda, MD 20814, USA. f.bandak@usuhs.mil

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Biomechanics of shaken baby syndrome

Wolfson, David R. (2007) Biomechanics of shaken baby syndrome. PhD thesis, University of Nottingham.

In the first part of this work, an Anthropometric Test Dummy (ATD) was used to obtain torso acceleration data for Shaken Baby Syndrome (SBS). These data were used to drive computational simulations of SBS, in studies of the effect of neck stiffness and head-torso impact on injury risk. Finally, physical models were used to investigate the strain induced in brain tissue during shaking.

Clinical literature describes victims of Shaken Baby Syndrome (SBS) as young infants with life-threatening brain injuries, and poor long-term outcome. However, biomechanical studies using ATI)s to study head motion during shaking have been inconclusive about the capacity for shaking alone to cause these injuries 11,21. This work comprises a series of investigations into these conflicting findings.

Torso acceleration data for SBS, obtained using a specially constructed ATD, were found to be consistent with previous findings. The data were used to simulate shaking in computational studies of SBS, using Rigid Body Models (RBM) of the infant head and neck. Parametric studies were used to investigate the importance of neck stiffness in assessing the injury capacity of SBS, and showed that in order to exceed current injury criteria for SBS, impact was required. Head torso impact was then simulated, and although this resulted in higher injury risk than shaking alone, criteria for injuries associated with SBS were not reached.

Since these investigations did not predict brain injury in cases of SBS without impact, the origins of injury criteria were reviewed. It was found that they are derived from single high energy events, which is distinct from the type of motion in SBS. In order to establish if cyclic, low-energy motion contributes to brain injury in SBS, Physical Continuum Modelling was used to study strain in brain tissue during shaking.

A test rig was constructed to shake silicone gel models, and high-speed video used to capture the motion of optical markers with in the gel. Their movement was tracked using optical flow methods, and Green-Lagrangian strain derived by tensor algebra. No evidence was found to indicate a build up in strain between cycles, but published critical strains for damage to neural tissue were exceeded.

Although shaking alone was not found not induce head motion in excess of brain injury criteria, tissue damage criteria were exceeded. The application of current brain injury criteria to SBS maybe therefore be inappropriate.

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Story Back From: October 24, 2005 Government to settle ‘brittle bones’ case Would pay $950K to family of man accused of abuse By CYNTHIA DI PASQUALE Daily Record Legal Affairs Writer The U.S. government has agreed to pay a West Virginia couple $950,000 for failing to diagnose a baby with brittle bone disease and instead accusing her parents of abuse, an attorney for the family said. Alice and Miguel Velasquez reached the deal with the government after presenting their case at a bench trial in U.S. District Court in Baltimore. The agreement brings to an end an almost six-year battle between the couple and military doctors at Bethesda Naval Medical Center, whose reports resulted in charges of felony child abuse against Mr. Velasquez and kept Liliana in foster care for 18 months. “One of the most hideous things you could be accused of is abusing a baby,” said Dorothy M. Isaacs, an attorney for the parents. “Yes, you want to protect babies. But you don’t protect them by taking them from a loving home and accusing [their parents] of abuse without any evidence.” Marcia Murphy, a spokeswoman for the U.S. Attorney’s office in Baltimore, declined to comment on the case, saying the government cannot sign the settlement until the guardian ad litem for Liliana has had a chance to review it. Routine check-up Miguel and Alice Velasquez are shown in this family portrait with children Tahlia (left), Corbin and Liliana, who was taken from her parents as an infant because of rib fractures. Both Tahlia and Liliana have brittle bone disorder, the family says. The family was living in Alexandria, Va., when Alice Velasquez took four-month-old Liliana for a routine checkup at the Bethesda medical center in February 2000. During the checkup, Mrs. Velasquez, an enlisted Army medical lab technician, asked about some bumps she had noticed on the baby’s ribs. When an X-ray revealed multiple rib fractures, Mrs. Velasquez informed them that bone diseases ran in her family. However, hospital staff never tested the child for brittle bone disease and instead insisted the fractures could only be the result of child abuse, according to Isaacs. They concluded this even though Liliana was bruise-free and didn’t show signs of shaken-baby syndrome, the lawyer noted. The doctors contacted child protective services in Alexandria, Va., where the couple lived at the time, and their daughter was promptly placed in foster care. Miguel Velasquez, Liliana’s primary caregiver, was arrested and charged with felony child abuse. He was also placed on a state registry of child abusers. “These people went through absolute hell,” said Isaacs, who practices with Surovell Markle Isaacs & Levy in Alexandria. She represented the Velasquezes with Patricia Ann Smith, who also practices in Alexandria. Things started to turn for the couple when the public defender assigned to Miguel Velasquez’s criminal case obtained court funding for Liliana to be tested for osteogenesis imperfecta, a genetic disorder characterized by bones that break easily. The test came back positive and Alexandria nolle prossed the charges in January 2001. Despite the test results, Liliana remained in foster care until July of that year. Her doctors still wouldn’t concede that the girl’s injuries were caused by brittle bone disorder, and child protective services wanted to be certain she would be safe. The city preferred to err on the side of caution, Isaacs suspected, especially following the death of another toddler under its protective custody that year, who had been returned to her parents just weeks earlier. Virginia did not remove Velasquez from its registry of child abusers until ordered to do so by the state Court of Appeals in August 2004.” (Delete reference to his conviction; as stated a few paragraphs earlier, the charges were dropped. Meanwhile, in July 2003, the couple filed suit against the federal government for medical malpractice, intentional infliction of emotional distress and malicious prosecution in U.S. District Court in Greenbelt. The case was reassigned to Baltimore and was being heard in a bench trial earlier this month when the parties decided to settle. While Judge Richard D. Bennett has agreed to the settlement, a judge in West Virginia must still approve it on Liliana’s behalf before Bennett can sign the order, Isaacs explained. She hopes that will be done this week. Source: http://truthinjustice.org/velasquez.htm

Multiple Fractures from Metabolic Bone Disease, being Falsely Attributed to Inflicted Child Abuse

One of the defining differences between traumatic fractures and those of metabolic origin is a prevalence of shearing, severance, and/or major dislocations in fractures of traumatic origin as compared with their absence or rarity on those of metabolic origin.(1) A second defining difference is the absence of pain and discomfort in metabolic fractures. Traumatic fractures, in contrast, are almost always extremely painful. This is easily explained. It is well known that bone has no pain fibers, while surrounding connective tissues are abundantly supplied with pain fibers. In metabolic fractures, which can take place with ordinary infant handling, surrounding connective tissue is not involved. In traumatic fractures, surrounding connective tissues are torn resulting in significant pain, as anyone who has experienced a sprained ankle or traumatic rib fractures can testify.

Current Standards of Medical Practice Concerning Multiple Fractures, and the Requirement for Differential Diagnosis

As reported by Jenny C, Committee on Child Abuse and Neglect, in “Evaluating infants and young children with multiple fractures,” Pediatrics,(2)(2006), a differential diagnosis of child abuse should include the following list, with appropriate evaluation for each, according to currently recognized medical standards. Anything less should be
considered as substandard medical practice.

‘ Osteogenesis imperfecta
‘ Preterm birth (osteopenia of prematurity)
‘ Rickets
‘ Osteomyelitis
‘ Copper deficiency
‘ Disuse demineralization from paralysis
‘ Other rare conditions (e.g. Menkes Syndrome)

Two additions might legitimately be added to this; First, classical scurvy from vitamin C was characterized by multiple fractures. Vitamin C deficiency is still quite prevalent and may be a contributory factor in many cases of brittle bone disease. This is due to the essential role of vitamin C as an enzymatic cofactor for the conversion of the amino acid, proline, into procollagen and collagen tissue, the latter making up 90 % of bone mass. (3) Second, based largely on the pioneering work of Marvin Miller (reviewed below), disuse demineralization of bone will take place in any situation involving prolonged immobilization of bone. This is well documented in children with club feet subjected to prolonged immobilization in corrective casts, as well as in animals sent into the weightlessness of space in early experiments by the Soviet Union. As a matter of common observation, it may be a complication of prolonged bed rest. Finally, the immobilization of the fetus from any cause during the last trimester of pregnancy may result in “temporary brittle bone disease,” according to the work of Marvin Miller. (Emphasis added) Flawed Medical Consensus that Multiple Fractures in Infants, in the Absence of Known Accidental Trauma, are Diagnostic of Child Abuse

In 1990 Garcia reported in Journal of Trauma on a series of 33 children brought into a trauma center with rib fractures, all brought about by blunt trauma. Nearly 70 percent were from auto accidents, 21.2 percent from child abuse, and 9.1 percent from falls. Mortality was 42 percent. 72 percent of the children with three rib fractures had internal chest injuries, such as lung punctures or tears and/or injuries to other internal chest organs. With four or more rib fractures there were 100 percent internal chest injuries. (1) By way of explanation, when rib fractures are brought about by severe blunt force, such as in auto accidents or falls, a significant portion of ribs will be severed and sheared, the severed pieces acting like spears that are plunged into the deeper chest organs. In the present series of 30 infants, there was only one report of internal chest injury (pleural effusions). From a statistical standpoint, this small incidence would have been a virtual impossibility, had these fractures resulted from violent, inflicted force.

Atrophy of Disuse as Applied to Fetal Bone Development: Spontaneous Fractures Taking Place during Childbirth or the Neonatal Period, Commonly Attributed to Child Abuse

Atrophy-of-Disuse is a universal principle as applied to human organs, tissues, and physiology. Bone is no exception. Common examples include bone weakening and rapid decalcification known to take place during prolonged bed confinement, thereby predisposing to spontaneous fractures or fractures with minimal trauma. As reported by Grayev et al, eight children with clubfeet experienced metaphyseal fractures during physical therapy when their legs were passively manipulated, their legs having been immobilized for prolonged periods in corrective casts. (4) In studies by Rodriguez et al of the long bones in newborn infants with congenital muscular dystrophy (with marked muscle weakening/paralysis), the bones were found to be thin, hypomineralized, and elongated. In most of the bones there were multiple diaphyseal (shaft area of bone) or metaphyseal (at ends of bones) fractures or both. (5, 6) A study of rat fetuses that were curarized (paralyzed) during the later phases of pregnancy revealed marked thinning and delay in ossification of bone.(7) Conversely, as a matter of common observation, exercise such as weight lifting strengthens bone as well as muscle, or else stress fractures would be near universal in more advanced weight training.(8,9)

The following paragraph from the text, Skeletal Tissue Mechanics, by R Martin et al,(1998) vividly describes the “atrophy of disuse” process as applied to bone: “It is commonly observed clinically that the intact portions of the fractured bone become osteoporotic as healing occurs. This generalized osteopenia of the intact regions, called posttraumatic osteoporosis or posttraumatic bone atrophy, is caused by two factors. First, in addition to the healing response, the fracture causes a remodeling….so that osteonal BMUs riddle the entire cortex with resorption cavities.

The second factor is the removal of mechanical loading from the fractured bone…If the fracture is well fixed and sufficient loadbearing is resumed, the resorption spaces will refill and the osteopenia will be transient.”(10) In other words, without movement or weight bearing, such as takes place when a fractured limb is immobilized in a cast, there may be significant decalcification of the bone; but there will be rapid recalcification once movement, weight bearing, and other mechanical stresses of daily living are resumed. With the above material as background, one of the frequent causes of osteopenia with spontaneous fractures during the perinatal period (shortly before and shortly after birth)  is prematurity. (11-13) As reviewed by Marvin Miller, (12)(2003), premature infants are at increased risk to develop temporary brittle bone state. It has traditionally been thought that the primary cause was insufficient calcium and phosphate in the diet of the premature infant. However, there is emerging evidence that the bone disease of prematurity may be more of a mechanical issue than one of nutritional mineral deficiency. Miller suggested that this increased bone resorption in the premature infant compared to the term infant is secondary to inadequate “bone loading” in the form of fetal muscular movement. During the last trimester of a full-term pregnancy the fetus is actively kicking and bouncing against the mother’s uterus. This fetal activity with associated muscle development is the
primary determinant of fetal bone formation, without which the bone remains poorly ossified, weak, and brittle.
It has been shown that preterm infants who receive 5-10 minutes of daily physical activity, with passive movements of extremities by nurse attendants, realize a 76% greater gain in bone density by one month of life compared to control premature infants who receive no physical activity. (8) M. Miller and T Hangartner have observed a comparable clinical situation referred to as “temporary brittle bone disease” associated with lack of fetal movement during the last
trimester of pregnancy, in which the baby remains susceptible to spontaneous fractures with minimal trauma for 6 or more months following birth.(14- 15)(Emphasis added) Risk factors that may lead to reduced fetal movement from limited uterine confinement include twin or triplet pregnancies, cephalopelvic disproportion, oligohydramnios (reduced amniotic fluid), large maternal uterine fibroids, or other maternal structural uterine abnormalities. Fetal structural defects such as clubfoot and dislocated hips may also result in decreased fetal movement; also short umbilical cords (16) and depressive-type drugs taken by the mother during pregnancy. (17)

Radiology Interpretations:

It is likely that many cases of metabolic bone disease are being missed in hospitals for the following reason: In the earlier phases of metabolic bone diseases, x-ray studies are of limited value since there must be at least a 30 to 40 percent loss of bone density (calcification) before there is any detectable reduction of whiteness on the films,(18-21) a level at which fractures may take place with minimal trauma or ordinary infant handling, (a physiology unknown to many prosecutors.)

Congenital Rickets from Vitamin D Deficiency

It is well established that there is a re-emergence of vitamin D-deficient rickets with “an alarming prevalence of low circulating levels of vitamin D in the United States population, leading to an increased incidence of infant fractures, especially when premature.” These conclusions were announced by the National Institute of Health (NIH) following a conference on vitamin D, October 9-10, 2003.(22) In a study conducted at the Pittsburgh Graduate School of Public Health, (23)(2007) serum 25-hydroxy vitamin D was measured at 4-21 week gestation and predelivery in 200 white and 200 black pregnant women and in cord blood of their neonates. Over 90 percent of women used prenatal vitamins. Women and neonates were classified as vitamin D deficient at less than 37.5 nmol/LI, insufficient between 37.5 and 80, and sufficient at over 80. At delivery, Vitamin D deficiency and insufficiency occurred in 29.2% and 54.1% of black women and 45.6% and 46.8 of black neonates, respectively; 5 % and 42.1% of white women and 9.7% and 56.4% of white neonates were vitamin D deficient and insufficient respectively. In other words, over 92% of black neonates and 66% of white neonates were born with grossly deficient or suboptimal vitamin D levels. It was concluded that black and white pregnant women and neonates residing in the northern USA are at high risk of vitamin D insufficiency, even when mothers are compliant with prenatal vitamins. Causes of the reemergence include reduction in milk intake (milk allergies, lactose intolerance, reduction in vitamin Dcontaining fats, and increased use of sun screens (sun acts on skin oils to generate vitamin D precursors).
An article entitled, “Rickets vs. Abuse: A National and International Epidemic,” by Kathy Keller and Patrick Barnes,(24)(2008) provided a review of the literature and four case reports of infants with multiple fractures demonstrating classical x-ray findings of rickets. Also, in each case vitamin D deficiencies were documented in the mothers. Classical x-ray findings of congenital rickets include the following:

Washed-out appearance of skull from side view.
Skull sutures widened and irregular.
Pseudo fractures occur in weakened bone with normal infant handling.
Rachitic rosaries: (Bulging irregularities in the growth centers at the anterior ends
of the ribs.)
Irregularities of the paired forearm bones at their endings in the wrists.
Curved diaphyses of leg bones (“bowed legs”) even before walking.
Absence of dense white lines in growth centers of epiphyses, such as at the wrists.
Maternal and infant diet histories are of highest importance in these cases.

Nutritional rickets has also been described with normal circulating 25-hydroxy vitamin D attributed to calcium deficiency in infants.(20) Elevated parathormone (PTH) levels are generally found in these cases.

Infantile Scurvy (Barlow’s Disease)

Infantile scurvy is another possible cause of spontaneous fractures, which may be more common than generally appreciated. The probability of Barlow’s Disease can be increased by maternal malnutrition, by hyperemesis gravidarum (excessive vomiting in pregnancy), by viral or bacterial infections in the mother or the infant. (26) The bones of infants may be vulnerable to fracture and defective formation before radiological signs appear. (18-21) Scurvy or subclinical scurvy would contribute to the deficiencies of proline and lysine hydroxylase (amino acid enzymes) that affect connective tissue components of bone formation. The hydroxylation (oxidation) of proline and lysine into procollagen is carried out by the enzyme prolyl hydroxylase, which requires vitamin C as a cofactor. (27,28) Collagen provides the bone’s tensile strength, comprising 90 percent of bone matrix. Deficiencies in vitamin C would compromise the prolyl hydroxylase enzyme system, resulting in imperfect bone formation. Far from being uncommon, vitamin C deficiency does still commonly occur in the Western World. When people attending a Health Maintenance Organization (HMO) in Tempe Arizona were tested for plasma vitamin C, it was found to be depleted (between 0.2 and 0.5 mgs/100 ml) in 30 percent and deficient (below 0.2 mgs/100 ml) in 6 percent. (29) As reviewed by Clemetson, when the human plasma ascorbic acid level falls below 0.2 mg/100 ml, whole blood histamine level is doubled or quadrupled. (30) It has been shown that bleeding from scurvy results from increased blood histamine, or histaminemia, which causes separation of endothelial cells from one another in capillaries and small venules, leading to spontaneous bruising. (31) When these are seen by a physician, almost always inflicted abuse is erroneously suspected. It follows then that the diagnosis of non-accidental trauma based on multiple bruises cannot be ethically or professionally justified without first ruling out scurvy by a plasma vitamin C blood test.

Metabolic Bone Disease and Vitamin K Deficiency

Maternal vitamin K deficiency during pregnancy is a risk factor for hemorrhagic disease of the newborn (HDN), usually a self-limited disorder taking place within 24 to 72 hours following birth. The primary dietary source of vitamin K is from green, leafy vegetables. It is for this reason that a maternal dietary history is of highest importance in adequate evaluation of infant fractures. Although calcium absorption from the gut into the blood stream is dependent on vitamin D, it is less well known that vitamin K delivers calcium from the blood into the bone.(32) Consequently deficiencies of vitamin K in early infancy may be a contributory cause of metabolic bone disease. Also, bone matrix proteins necessary for normal bone metabolism are vitamin K-dependent,(33-35) so that vitamin K deficiency in infants can lead to fractures as well as hemorrhagic disease..

Osteopenia of Prematurity

As reviewed above under “Atrophy of disuse,” prematurity poses one of the most common sources of infant fractures. (11-13) This is due to the fact that the fetal kicking and other vigorous body movements, which are essential for promotion of bone strength and integrity, are only in their beginning phases when preterm births occur. These
movements are intrinsically necessary for bony maturation, just as they are necessary to maintain bone strength at all ages following birth.

In Nelson’s Textbook of Pediatrics, 16th Edition, the following quotation is found:
“Osteopenia of prematurity. Very small premature infants with chronic illnesses often develop a rickets-like syndrome with pathologic fractures and demineralized bone. There may be associated cholestasis and vitamin D or calcium malabsorption; urine calcium loss due to diuretics; and poor calcium, phosphorus, or vitamin D intake, or aluminum toxicity. The treatment of fractures requires immobilization and administration of calcium and, if needed, phosphorus (for hypophosphatemia) and vitamin D (not more than 1,000 IU/day unless severe cholestasis or vitamin D resistance). Appropriate formulas for premature infants should provide a more optimal intake of calcium, phosphorus, and Vit. D.”(36)

As reviewed by FR Greer:

“Osteopenia of prematurity refers to the hypomineralized skeleton of the premature infant compared with that of the normal fetal skeleton…..In growing, low birth-weight infants with birth weight less than 1500 grams (3.3 lbs) and less than 32 weeks gestational age, it occurs almost without exception. This high incidence (of hypomineralization) is not surprising considering that 80% if fetal skeletal mineralization takes place during the last trimester of pregnancy. Thus one would expect an increasing degree of osteopenia in premature infants with decreasing gestational age. …Even term infants may have decreased stores owing to maternal complications such as severe preeclampsia.”(37)

Three reviews of fractures occurring during the first year of life in premature infants (38-40) found that rib fractures often remain undetected and are only discovered on x-rays taken for other reasons. In one series, clinical suspicion of fractures was documented prior to ordering the radiographs in only 3 of the 19 (16%) infants.(41) Hence the true incidence of fractures in infants born prematurely remains unknown, but it probably is much more common tan reported in the literature.

Timing of Fractures

In court cases involving multiple fractures in which parent and/or caretaker have been accused of child abuse, the dating or timing of the fracture often plays a critical role.

As reviewed by Amir et al,(11) from 1977 to 1984, 973 premature infants were admitted to the neonatal intensive care unit of Beilinson Medical Center, Petah Tiquva (Isreal). Among those who survived over 6 months, 12 suffered from fractures that appeared during their hospitalization between ages 24 and 60 days. All of these were without clinical signs. All were diagnosed on routine chest x-rays. Callus was always present when first diagnosed. In six instances angulation was present, but there were no instances of separation or dislocation in the fractures. According to the authors, fractures usually occur a few weeks after birth, and are almost always pathologic, the most
common cause being metabolic bone disease.

According to N. Bishop, who observed a somewhat different timing, fractures due to osteopenia of prematurity and preterm rickets occur typically from 10 weeks age and usually stop before 6 months.(39) In one of the earliest prospective studies of the clinical course of fractures and rickets in very low birth weight infants (less than 1,500 grams) by WH Koo et al, (13) 78 infants were enrolled solely on the criteria of birth weight <1,500 grams. There was a distribution of 82 fractures in 19 infants in the study. 73 fractures (89%) originated during the course of hospitalizations ranging from 32 to 131 days. Clinical suspicion was documented prior to ordering the radiographs in only three of the 19 infants (16%). It was further determined that physical therapy was the source of some of the fractures. Fractures from congenital rickets, when followed serially on radiographs, showed complete resolution beyond six months after birth.

Conclusions and Recommendations:

The Jenny report in 2006, which established a standard for the differential diagnosis of multiple fractures in infants and children, might justifiably be considered a major landmark in medical history. Since the publication of this report, it has been incumbent on physicians to rule out various forms of metabolic bone disease before diagnosing inflicted child abuse directed against parent or caretaker. In my opinion, failure to do this must be considered substandard medical practice, bringing disrepute on the medical profession.
According to the time-honored principle of “considered innocent until proven guilty,” appropriate medical evaluation of multiple fractures would require a formal listing of a differential diagnosis and appropriate laboratory tests. In addition to routine chemistries and blood counts, blood tests should include 25-hydroxy vitamin D, alkaline
phosphatase, parathormone, calcium, phosphorus, serum histamine, plasma vitamin C, and tissue exams for osteogenesis imperfecta. These tests should be performed immediately on finding of fractures, as later tests might be irrelevant. A careful medical history of the mother’s diet and vitamin supplements during pregnancy and of the infant’s
diet and supplements following birth are of paramount importance. Lacking these criteria, diagnosis of inflicted child abuse cannot be justified.

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Source:

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A Parent’s Worst Nightmare

Doctors said we’d abused our baby. Who would believe us?

Accused

The pediatrics clinic at the hospital in Bethesda, Maryland, was jammed. Alice Velasquez, dressed in Army fatigues, passed four-month-old Liliana to her husband, Miguel, so she could stretch and check the clock. They had been in a waiting room at National Naval Medical Center for over an hour and a half. Now, Alice was late for duty at the Pentagon.

“Don’t worry, honey, it won’t be much longer,” Miguel told Alice. Then he kissed Liliana, and she began to coo.

A few days before, Alice had found two little bumps over Liliana’s left ribs. They felt bony, and bone problems ran in Alice’s family. The couple decided to ask the doctor to do x-rays during the “well baby” visit.

Husband and wife were a study in contrasts: Alice, blonde, outgoing, excitable; Miguel, olive-skinned, quiet, placid. He kept her calm until their turn finally came. Alice took Liliana. Miguel grabbed the baby’s diaper bag and toys, and they went into the exam room. It was the last moment of ordinary family routine they would have for the next five years.

“Healthy, four-month-old female, normal growth and development, gaining appropriately but on the smallish side,” say the notes of the intern who first examined Liliana on that day, February 3, 2000. The intern dismissed their fears about the bumps, but Alice persisted. A pediatrician, Dr. Paul Reed, agreed to order x-rays.

“I knew as soon as I saw Dr. Reed’s face that something was terribly wrong,” Alice says. The x-rays showed that several of Liliana’s ribs were broken. “These injuries are nonaccidental,” Dr. Reed told them. Someone has squeezed your baby, probably to make her stop crying, Alice recalls him saying. The doctors did more tests to check for other injuries. Alice began sobbing loudly.

People in white coats peppered Miguel with questions. What had happened? Did he drink a lot? Get angry? Shake the baby? Miguel was shocked speechless.

Because fractures stemming from compression injuries are often an indicator of child abuse, and noting Miguel’s seeming lack of emotion, Dr. Reed considered this a typical case of paternal mistreatment. He gave his opinion to his supervisor, Dr. Barbara Craig, head of the Armed Forces Center for Child Protection.

“We were so young and naive,” Alice says now, ruefully. She was 20, Miguel, 28.

The radiologist reading the next round of x-rays said Liliana also had a broken wrist and possibly a broken leg. This report, later found to be inaccurate, further convinced doctors of abuse.

Liliana was admitted to the pediatric unit at Walter Reed Army Medical Center for her protection, and another doctor examined her there. A summary of Liliana’s exam relates the following: no swelling, no bruises, no cuts, no burns. No evidence of pain. Well-nourished. Growing well. Not withdrawn. Clean clothes, earrings, painted toenails, very clean and well kept. Smiling, feeding, alert. Both parents attended all OB visits before the birth. Both parents bring her to clinic appointments.

The record also notes Alice mentioned bone problems in her family. Yet, medical experts would later testify, none of the many doctors at the Naval Medical Center or at Walter Reed recorded a thorough medical history, nor did they do a “differential diagnosis” to rule out what, besides abuse, could have caused Liliana’s broken ribs. All other tests, including a brain scan, were normal.

Well into the night, a doctor, two social workers from the Alexandria, Virginia, Child Protective Services, two Alexandria police detectives, and a military police officer all questioned the Velasquezes. They asked open-ended questions like, “How do you think this might have happened?”

Arrested

The couple didn’t comprehend the jeopardy they were in. During that interview and subsequent ones, they speculated and wondered aloud if it was possible they’d been too rough with the baby. In one session, Miguel told a social worker that he had massaged the baby’s stomach when she was constipated. It was a folk treatment in his native San Salvador. His comment was heard in a very different way. What got written down was, “Father admitted to squeezing the baby.”

The next day, the couple say, a social worker told them that, in light of Liliana’s injuries and the interviews, the baby was going to be put in foster care. If either of them made a scene, it would hurt their chances of getting her back.

Alice began to cry but composed herself enough to write out the baby’s schedule. Miguel filled the diaper bag while Alice nursed the baby one last time, and then they carried her to a car waiting in the snowy street. She buckled Liliana into a car seat, and the social worker closed the door. And Alice lost it. She sprinted after the car, crying, “They took my baby!” Miguel ran after her to stop her, and they both crumpled onto the slush-covered sidewalk, weeping.

A series of emergency hearings took place over the next few days. Each time the Velasquezes appeared in court, friends, co-workers and members of their church came as character witnesses. Yet social workers did not interview any of them to ask what sort of parents the Velasquezes were.

A friend searched the Internet to find out what childhood diseases might result in broken bones. One condition jumped out: osteogenesis imperfecta (OI), “brittle bone disease.”

OI is caused by a defect in the production of collagen, the protein that holds bones together. A person with OI doesn’t have enough or has poor-quality collagen. In mild forms, a doctor looking at an x-ray can’t always tell if the bones are right or not. Broken bones are often the first sign of the disease. “I’ve had parents tell me about breaking a baby’s leg when they lifted them by the ankles to change a diaper,” says Heller An Shapiro, executive director of the Osteogenesis Imperfecta Foundation. “We get calls about false accusations of abuse all the time.”

On February 15, Alice told Dr. Barbara Craig why she suspected OI, listing her own history of broken bones. She would later ask that Liliana be tested — but the infant never was.

“Please test her!” Alice begged every doctor and social worker she encountered. “All I heard was, ‘You’re just making excuses for your husband. You’d better cooperate if you want your baby back,’” Alice says.

At their first emotional reunion with Liliana, in a visitors room at the Alexandria Social Services office, the Velasquezes noticed she was wearing the same clothes she’d worn when she was taken away the week before.

“Maybe the foster provider washed them,” Alice said hopefully to her husband. But when they changed Liliana, they knew it wasn’t so. Her undergarment was stained and smelled bad. Alice says the baby had a diaper rash so severe her bottom was bloody.

The Alexandria police knew where and when the Velasquezes were seeing their baby. That’s when they decided to arrest Miguel for felony child abuse.

Osteogenesis Imperfecta

Miguel was released on bond, but more problems began. He had been well into the process of becoming an American citizen. Now, because he had been charged with a felony, he faced possible deportation.

At her job at the Pentagon, Alice was reprimanded for crying on duty. Her weight plummeted. She fainted during physical training.

Every time the couple saw Liliana, they felt frantic. Their baby looked dirty, had diaper rash, or seemed feverish or weak. Once, they saw mold in her bottle. She didn’t seem to be growing. The Velasquezes say they reported all this to their social worker and their court-appointed lawyers. Little was done; nothing changed.

In the spring, the public defender in Miguel’s criminal case finally got a court order to test the child. The results didn’t come back until September. But when they did, they confirmed Liliana had osteogenesis imperfecta type I. The main symptom: fractures.

When he heard about the diagnosis, the prosecutor for the Commonwealth of Virginia, Roger Canaff, consulted Dr. Craig. She wrote later in a memo that the test was “experimental in nature,” and that doctors looking at the x-rays of a child with OI should see evidence of the faulty bones. Liliana’s bones, she said, looked “completely normal.” Other military doctors, then and later on the witness stand, said the same.

In fact, the test of bone collagen had been the “gold standard” for OI since the late 1980s. Insurance companies routinely reimbursed for it. It was very reliable. If a test is negative for OI, there is a chance a child might still have the disease, but there are no false positives. The military doctors were simply wrong in their beliefs.

But then the doctors took the position that even if Liliana did have OI, she still had been physically abused. E-mails between prosecutor Canaff and Dr. Craig said that the Velasquezes “lie and exaggerate,” make “bizarre statements” and “cannot be trusted.”

Canaff offered to reduce the charge from a felony to a misdemeanor if Miguel would plead guilty. Miguel responded that he had not harmed his child and would never say he had.

In October 2000, about a month after the OI diagnosis, Alice and Miguel found a large, festering burn on the top of Liliana’s right foot. The child was still in foster care. They photographed the burn and went before a judge, showing the pictures and citing other failures they perceived in her care. They wanted Liliana back. Failing that, they wanted her in a different foster home.

They lost.

A few months later, the social workers refused to let the Velasquezes see Liliana at all unless they agreed not to take anything but family photos, and not to change her clothes.

By this time in the ordeal, Alice’s weight had dropped from 140 pounds to 82. She had to take a hardship discharge from the Army. That meant they had no income and no health insurance — and Alexandria Social Services was charging them almost $700 a month for Liliana’s child support. Miguel still had immigration issues, and his name had been put on Virginia’s “abuser” registry. It became nearly impossible for him to find work.

Alice and Miguel had not seen their daughter for two months when they learned just before Christmas that she was in the hospital. Liliana had been brought in by ambulance, unconscious. Her blood sugar count was low. Seemingly she hadn’t been fed.

A nurse privately told Alice, “Your baby has been hospitalized here many times before.” Then she explained how to get Liliana’s hospital records.

Alice discovered the baby had been hospitalized a total of seven times, often for dehydration. Neither the Velasquezes, Liliana’s court-appointed attorney, nor her pediatrician had been informed.

Last Hope

A few days later at the hospital, Alice says, a social worker told them that if they didn’t confess to causing Liliana’s injuries, they might never get her back. “Pretty soon, we’ll put Liliana up for adoption.”

Giving in to the will of the bureaucracies aligned against them might have been the easiest way out. Alice and Miguel were penniless. Their church was feeding them and paying their rent. A long list of attorneys had refused to help them with a case against the state. They did not give in.

Fortunately, about that time they were referred to Dorothy Isaacs, a partner at Surovell Markle Isaacs & Levy. She agreed to take their case.

After more than a decade in the law, a lot of it in divorce court, Isaacs is no bleeding heart. She listened to Alice and Miguel, then read their documents and checked their backgrounds. And she grew enraged. “I believe there are a few things I was put on the planet to do,” Isaacs says. “I came to feel getting Liliana back and clearing Miguel’s name were on the list.”

Isaacs first helped get Liliana moved to a different foster home. Then, in July of 2001, ten months after the OI diagnosis and 17 months after she had first been taken from them, Liliana came home. By spring of 2002, the Velasquezes had formal, legal custody.

Late in the summer of 2004, the Virginia Court of Appeals overturned the finding of abuse against Miguel, essentially declaring that the Department of Social Services had made an error. It was the first such ruling on an abuse case in the history of the state.

It took two more months to get Miguel’s name off the state’s central registry of abusers. “I owe Dorothy Isaacs everything,” Miguel says softly. “She gave me back my baby. Then she gave me back my name.”

Finally, Isaacs filed suit in federal district court against the government, accusing the doctors who had treated Liliana of medical negligence, intentional infliction of emotional distress and malicious prosecution.

On October 11, 2005, Isaacs and her co-counsel began laying out the details of how the family had been shattered. After reviewing a thousand pages of records, experts in both child abuse and OI concluded the military doctors “breached the standards of care” by too quickly assuming Liliana had been abused by her father, by not doing a differential diagnosis, by not testing her, and then by insisting she had been abused even after the OI diagnosis was made.

Even an expert witness hired by the military testified that the test used to determine Liliana’s OI was reliable.

A settlement was reached, but there was no assignment of wrongdoing. The Velasquezes were, however, awarded $950,000. About half went for legal fees and expenses. A trust fund of $150,000 was set aside for Liliana. As far as is publicly known, no one at the hospitals or in social services was fired or reprimanded. The foster-care giver was not found negligent.

After the Velasquezes paid off their spiraling bills, they used the remaining money to buy a house for their family, which now also includes Tahlia, 5, and Korbin, 2. Tahlia has OI; her brother does not. Liliana, now 7, still has bad dreams but does not show overt problems arising from her terrible ordeal. She is not in therapy. She’s at home with her parents, who are trying to give her a normal life.

After the papers had been signed, Judge Richard D. Bennett read a statement into the record outlining the “living nightmare” the Velasquezes had endured. He encouraged Miguel to become a citizen. Then the judge said something rarely heard in a courtroom, “I apologize on behalf of the United States government,” and he came down off the bench and shook their hands.

Jan 2007

Source:

http://www.rd.com/your-america-inspiring-people-and-stories/parents-wrongly-accused-of-child-abuse/article31773.html

Shaken Baby Syndrome And Oteogenesis Imperfecta

Authors:

Cabrerizo de Diago R, Ureña-Hornos T, Conde-Barreiro S, Labarta-Aizpun J, Peña-Segura JL, López-Pisón J.

Servicio de Pediatría, Hospital Infantil Universitario Miguel Servet, P.o Isabel la Católica 1-3, E-50009 Zaragoza, Spain.

Abstract

INTRODUCTION: Shaken baby syndrome (SBS) is a form of physical abuse that includes the presence of a subdural or subarachnoid haematoma or diffuse cerebral oedema, retinal haemorrhages and, in general, absence of other physical signs of traumatic injury. Osteogenesis imperfecta (OI) is a genetic disorder affecting the synthesis of type I collagen that leads to brittle bones with frequently occurring fractures, with presenting clinical symptoms taking a variety of forms. A differential diagnosis allowing it to be distinguished from physical abuse is known, due to the existence of bone fractures with no known traumatic injuries, but we do not understand the link between OI and SBS. CASE REPORT: We describe the case of an infant who, at the age of 3 months, suffered symptoms of acute encephalopathy with convulsions, subdural haematoma and retinal haemorrhages compatible with SBS, as well as bilateral rib fractures. The skeletal series of X-rays revealed alterations in bone structure and texture, which led to a diagnosis of OI that was confirmed by a study of the collagen in skin fibroblasts. CONCLUSIONS: The suspected existence of SBS is unpleasant both for the health care professional and for the patient’s relatives. The existence of rib fractures in an obvious case of shaken baby syndrome suggested malicious abuse; however, the parents’ attitude and the existence of OI made us think that no harm was intended. Shaking could have been secondary to bouts of crying due to microfissures related to the OI. The differential diagnosis of processes that can be mistaken for shaken baby or from favourable or predisposing medical factors must be taken into consideration.

Source:

http://www.ncbi.nlm.nih.gov/pubmed/15926132

Dysphagia as a risk factor for sudden unexplained death in infancy.

Talbert DG.

Institute of Reproductive and Developmental Biology, Imperial College School of Medicine, Queen Charlotte’s Hospital, Du Cane Road, London W 12 ONN,UK. d.talbert@imperial.ac.uk

Vitamin K deficiency mimicking child abuse

Tonia J. Brousseau, DO

Niranjan Kissoon, MD CPE

Bruce McIntosh, MD

Abstract:

Supplemental vitamin K is required for normal hemostasis in infancy. Infants born outside the hospital may not receive prophylactic vitamin K. They may suffer from bleeding into various tissues and are likely to present to the emergency department. This report describes an infant born at home who presented with intracranial bleeding and signs and symptoms consistent with child abuse. Further investigations confirmed the diagnosis of Vitamin K deficiency. Although it is important to consider child abuse when the history and examination are consistent with the diagnosis, it is equally important to consider other potential diagnoses including Vitamin K deficiency.

Source:

The Journal Of Emergency Medicine

http://www.jem-journal.com/article/S0736-4679%2805%2900156-3/abstract

Retinal hemorrhage and pediatric brain injury: etiology and review of the literature

Henry E. Aryan MD

Division of Neurosurgery, University of California, San Diego, California

Faris R. Ghosheh MD

Rahul Jandial MD

Department of Neurosurgery, Children’s Hospital, San Diego, California

Michael L. Levy MD, PhD

Department of Ophthalmology, University of Maryland, Baltimore, Maryland, USA

Retinal Haemorrhages In Premature Infants: A Pathogenetic Alternative Diagnosis To Child Abuse.

Author: Hans C. Fledelius

Purpose:

To present the occasional observation of retinal haemorrhages in premature babies, as a diagnostic alternative to those observed as part of shaken baby syndrome.

Methods:

We carried out an observational study on 11 infants in whom retinal and/or vitreous haemorrhages had been observed within their first months of life. Ten infants were under surveillance for retinopathy of prematurity (ROP), with gestational ages and birth weights in the ranges of 27–34 weeks and 790–1665 g, respectively. One infant was diagnosed with Zellweger’s syndrome and one received substitution therapy for coagulation factor II deficiency. The last child had been delivered at 38 weeks, weighing 2070 g; he died on day 5 from severe brain oedema with incarceration and extensive bilateral fundus bleeding.

Results:

Four of the 11 infants had some evidence of ROP, and two later received retinal ablation therapy. Contrary to the quick absorption (< 1–2 weeks only) usually seen in most newborn term infants, the ocular bleeding in preterms was generally longstanding. A quick increase in intracranial pressure probably played a role in the lethal case with delivery near term, and one infant received lung physiotherapy for pneumonia at the age of 6 months. Some bleeding appeared to be truly postnatal (i.e. it was observed as a new occurrence during the course of surveillance).

Conclusions:

In the series under study there was no suspicion of child abuse. In term infants, retinal haemorrhages are extremely rare except when due to shaking, but other diseases should be ruled out, coagulopathies in particular. We suggest that prematurity as such is added to the list of possibly underlying causes when retinal bleedings are evaluated in very small infants and shaken baby mechanisms are suspected.

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