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CE: Understanding the Complications of Sickle Cell Disease

Source:

AJN, American Journal of Nursing

June 2019, Volume :119 Number 6 , page 26 - 35 [Buy]

Keywords

sickle cell anemia, sickle cell disease, hemoglobin, hemoglobinopathy

 

Authors

  1. Tanabe, Paula PhD, RN
  2. Spratling, Regena PhD, RN
  3. Smith, Dana BSN
  4. Grissom, Peyton BSN
  5. Hulihan, Mary DrPH

Abstract

Sickle cell disease (SCD) is an autosomal recessive genetic condition that alters the shape and function of the hemoglobin molecule in red blood cells. While the overall survival rate among children with SCD has improved in recent years, pediatric rates of hospitalization, ED use, and mortality from complications of SCD remain high. Among patients ages 18 and older, hospital admission and ED usage are even greater-and the median age at death of people with SCD is considerably lower than that of the general population. Nurses who care for patients with SCD have an opportunity to improve health outcomes and quality of life for these patients by recognizing the major SCD-associated complications and providing patients and their caregivers with appropriate educational information. The authors discuss the genetic, hematologic, and clinical features of SCD and describe the major associated health complications. In addition, they review the nursing implications of each complication and provide online links to resources for clinicians, patients, and caregivers.

 

Article Content

Sickle cell disease (SCD) is an autosomal recessive genetic condition that alters the shape and function of the hemoglobin (Hb) molecule, causing red blood cells to take on the shape of a sickle (or crescent) (see Figure 1). The sickled blood cells break down prematurely, potentially producing anemia. Since they are rigid, they may become trapped in small blood vessels, triggering acute painful events, depriving tissues of oxygen-rich blood, and damaging organs, most notably, the spleen. Splenic injury greatly increases the risk of death from infection at a young age.

  
Figure 1 - Click to enlarge in new window Normal red blood cells are round and flexible and move easily through blood vessels. In sickle cell disease, abnormal hemoglobin causes red blood cells to become sickle (or crescent) shaped and rigid. The misshapen cells can easily become lodged in smaller blood vessels, depriving tissues of oxygen and triggering painful episodes. Illustration by Alila Medical Media.

Millions of people throughout the world have SCD, most frequently those of African, South or Central American, Caribbean, Mediterranean, Indian, or Saudi Arabian descent. In the United States, it is the most common inherited blood disorder, affecting more than 100,000 people, approximately 90% of whom are black and 10% of whom are Hispanic.1 (The number of non-black or non-Hispanic SCD patients is too low to estimate based on currently available data.) Of the four primary SCD genotypes, HbSS and HbS[beta]0-thalassemia tend to be the most clinically severe forms of the disease and are collectively termed sickle cell anemia (SCA). Generally, HbSC and HbS[beta]+ are the more clinically benign forms, though severity varies among patients, and even patients with these typically milder forms of SCD commonly experience acute painful events and such serious complications as acute chest syndrome (ACS), silent cerebral infarction (SCI), avascular necrosis (AVN), priapism, and kidney failure throughout life.2-6

 

In 1987, the National Institutes of Health (NIH) convened a Consensus Development Conference on Newborn Screening for Sickle Cell Disease and Other Hemoglobinopathies, which recommended that all newborns in the United States be screened for SCD.7 It was not until 2006, however, that all 50 states and the District of Columbia had fully adopted the recommendation.8 Now, the identification of SCD in newborns enables physicians to initiate prophylactic penicillin and early vaccination against Streptococcus pneumoniae in order to prevent related infection or death, and provides family members an opportunity to learn how to reduce the child's risk of potential SCD-related complications, to consider the implications of the child's condition for their own and the child's future family planning, and to seek evidence-based care for the child from health care professionals with an expertise in SCD. A 2010 study of the Dallas Newborn Cohort, which includes children who were diagnosed with SCD at birth (through newborn screening) and received ongoing care at a Dallas-based, tertiary SCD clinic from 1983 forward, found that the overall survival rate at age 18 was nearly 94% among children with SCA (up from 86% in 2004) and 99% among those with the less severe HbSC or HbS[beta]+-thalassemia (up from 97% in 2004). ACS and multisystem organ failure had replaced bacterial sepsis among these children as the leading causes of death.9

 

Despite increased survival among pediatric patients with SCD, hospitalization and ED usage rates are estimated to be seven to 30 and two to six times higher, respectively, than those of same-age cohorts without the disease.10 ED visits, hospital admissions, and hospital readmissions are even more frequent among 18-to-30-year-olds with SCD than among children or adults in middle or older age.11 The median age at death among patients with SCD is considerably lower than that of the general population: for men and women with SCA, 42 and 48 years, respectively; for men and women with HbSC, 60 and 68 years, respectively.12

 

Two of the greatest challenges faced by clinicians caring for patients with SCD are the lack of evidence-based guidelines, owing to the paucity of data from large, randomized controlled trials involving SCD patients, and the underuse of the few recognized disease-modifying therapies.13 Since, in the United States, SCD affects primarily black and Hispanic patients, it's been suggested that "conscious or unconscious racial bias" has limited the availability of resources for research, as well as for the delivery and improvement of care.14 An evidence-based report on the management of SCD, supported by the NIH and published by the National Heart, Lung, and Blood Institute (NHLBI), identified only seven areas in which strong recommendations based on high-quality evidence could be made.13, 15 (See NHLBI Expert Panel Recommendations for Managing Sickle Cell Disease.13, 15) The other recommendations are based on observation or low-quality evidence. This article reviews the major health complications faced by patients with SCD, discusses the nursing actions relevant to each, and provides a summary of these for quick reference (see Table 1). It also lists online links to several resources for clinicians, patients, and patient caregivers (see Sickle Cell Disease Clinical Care Resources), as well as little-known facts about SCD (see Facts About Sickle Cell Disease5, 9, 10, 16-19).

  
Table 1 - Click to enlarge in new window Major Complications of Sickle Cell Disease and Nursing Implications
 
Box. NHLBI Expert Pa... - Click to enlarge in new window NHLBI Expert Panel Recommendations for Managing Sickle Cell Disease
 
Box. Facts About Sic... - Click to enlarge in new window Facts About Sickle Cell Disease

ACUTE PAIN

An acute vasoocclusive episode (VOE) is a new onset of severe pain that persists for at least four hours for which there is no explanation other than vasoocclusion. VOEs are the primary source of acute pain requiring medical attention in SCD, and they account for most acute pain episodes experienced by patients with this condition. VOEs can be treated with parenteral opioids, ketorolac, or other nonsteroidal antiinflammatory drugs. As patients grow older and learn strategies for alleviating the pain of VOEs, they often manage these episodes at home, but VOEs are the most common manifestation of SCD and the most common SCD-related ED diagnosis.16 In a 2013 follow-up analysis of 264 adult patients with SCA in the Bethesda Sickle Cell Cohort study, approximately 40% reported no hospitalizations or ED treatments for VOEs within the past year, whereas 22% reported five or more hospitalizations or ED visits within that period, underscoring the tremendous variability of VOE severity that occurs in SCA.20

 

The clinical management of VOEs focuses on rapid pain assessment and administration of appropriate analgesics. Infants and toddlers often present with dactylitis, or pain and swelling from infarctions in the hands and feet; these may be the first SCD-related complications they experience (see Figure 2).21 Other common locations for VOE pain in patients of all ages include the chest, abdomen, back, and long bones. SCD genotype, older age, higher hematocrit levels, and lower fetal Hb levels are risk factors for VOE.12 Patients may have specific triggers for pain, such as extremes in temperature, dehydration, menstrual cycle changes, alcohol, or stress, but the majority of painful episodes have no identifiable cause. The effects of VOEs extend beyond the episodes themselves. Acute multisystem organ failure and death have also been reported during VOEs.22, 23 And patients with more frequent VOEs are shown to have a younger age at death.20

  
Figure 2 - Click to enlarge in new window The hand of an infant with dactylitis-a painful swelling of the fingers or toes. Photo courtesy of Tom D. Thacher, MD.

Nursing implications. A nurse's comprehensive pain assessment, noting location, intensity, and duration of the pain episode, is invaluable. Nurses help patients identify what normally relieves the pain and whether the patient's current pain is a typical VOE or suggests a different complication, such as ACS. As primary advocate for the patient, nurses can work with the prescribing clinician to ensure the patient receives adequate analgesia. Nurses can also work with patients to determine which nonpharmacologic adjunct therapies best relieve the pain. Most patients find heat application comforting; the application of ice is contraindicated in VOEs because vasoconstriction increases the pain by reducing oxygen delivery. Other nonpharmacologic therapies frequently used in SCD include cognitive behavioral therapy, biofeedback, prayer, relaxation techniques, acupuncture, hypnosis, herbal therapies, and megavitamins.24

 

After the pain has been relieved, nurses can work with patients to understand potential VOE triggers and how to avoid them and to ensure patients understand how to take the pain medicines prescribed to manage their pain. Nurses may also help patients understand the importance of hydration in preventing VOEs by increasing plasma volume and reducing blood viscosity. Unless contraindicated by conditions such as heart failure or renal disease, fluid intake may be encouraged. Finally, nurses can persuade patients, who may be reluctant to move because of pain, to walk and use the incentive spirometer every hour to prevent blood clots and pulmonary complications.

 

CHRONIC PAIN

Three subtypes of chronic pain have been identified in SCD25:

 

* chronic pain without contributing SCD complications, such as leg ulcers or AVN

 

* chronic pain with contributing SCD complications

 

* mixed presentation, when there is evidence of chronic pain from SCD complications but also apparently unrelated persistent pain

 

 

As with other types of chronic pain, SCD pain can cause patients to experience central sensitization, hyperalgesia, and altered opioid metabolism. Chronic pain not only causes discomfort but may also precipitate mood changes, emotional disturbance, and behavioral dysfunction, thereby affecting numerous facets of the patient's life as well as the lives of family members, friends, and colleagues.26 In a six-month, prospective cohort study of 232 patients with SCD who were age 16 or older, 29% experienced pain almost daily while 14% experienced pain on 5% or fewer days.27 This chronic pain was more frequent than VOEs and was often managed outside of a health care setting.

 

Nursing implications. In addition to conducting a comprehensive pain assessment for acute VOEs, nurses can try to determine the type of chronic pain patients are experiencing. For example, a patient experiencing hip pain may require an orthopedic evaluation for AVN and possibly surgery. Nurses can also obtain a thorough medication history, including all opioid and nonopioid pain medications. Many patients with SCD require both short- and long-acting opioids and may use these medications for sleep or anxiety in addition to pain. Nurses can help patients understand how to use long-term opioids most effectively and to encourage the use of nonpharmacologic interventions as adjunctive therapy.

 

AVASCULAR NECROSIS

When the bone's blood supply is interrupted, bone tissue may die, a condition referred to as AVN. In people with SCD, AVN may result from VOEs in the bone's microcirculation that cause thrombosis, infarction, and ultimately, necrosis.28 SCD severity and history of ACS may be risk factors for AVN,2 which can occur in people of all ages and has been seen in children as young as five years.29

 

Although the VOEs of SCD can occur in any organ, they are especially common in the bone marrow, particularly in the femoral or humeral head, where they can cause unilateral or bilateral AVN.28 In one study, the overall cumulative incidence of femoral head AVN was 15% by age 30; the median age at diagnosis was 27, and nearly a quarter of the patients underwent hip replacement surgery at a median age of 36.2 Often, however, patients do not report the pain of AVN or are unable to obtain orthopedic follow-up. If undetected or untreated, AVN can cause permanent gait abnormalities and limb-length discrepancies, significantly impairing mobility.

 

Nursing implications. The comprehensive pain assessment conducted by the nurse may provide the first clues that the patient has AVN. If AVN is suspected and an orthopedic consultation has not yet been recommended, the nurse should discuss assessment findings with the primary care provider. If the patient is diagnosed with AVN, the nurse can help the patient and family understand the condition and the various procedures that may be considered to alleviate related pain and disability.

 

PRIAPISM

Priapism is an undesired, persistent, and often painful erection that can lead to erectile dysfunction, substantially impairing quality of life. In boys and men with SCD, priapism is a common complication. Researchers have calculated that the actuarial probability of male patients with SCA experiencing priapism was nearly 13% by age 10, more than 50% by age 15, and more than 89% by age 20.30

 

In a survey of 130 male patients with SCD being treated at one of five UK or Nigerian hospitals, a history of priapism was reported by 46 (35%) of respondents.3 Within this group, 24 (52%) reported a history of severe, prolonged priapism (lasting more than 24 hours), which requires emergency treatment, and 33 (72%) reported a history of "stuttering" priapism-recurrent self-limited episodes, which are of much shorter duration. Stuttering episodes frequently heralded subsequent prolonged events, as only six of those reporting a history of severe priapism had no history of the stuttering type. In the group of 46 respondents, the mean age of priapism onset was 15, with 75% reporting their first episode before the age of 20 and 25% reporting a first episode before the age of 10. Sleep, sexual activity, and fever were frequent precipitating factors.3

 

Nursing implications. Prevention is key but is hindered by a lack of knowledge and awareness of the complication. In a survey of patients with SCA ages five to 20, only 7% of the men who had not experienced priapism were aware of what it was and knew it was a potential complication of SCA.30 Patient teaching can include the use of analgesia, hydration, exercise, voiding, and warm baths to help prevent episodes.

 

Priapism can be an embarrassing problem for men with SCD, which may make it a difficult topic to discuss. Nurses may approach the discussion with an educational focus, providing answers to questions the patient may be afraid to ask. It's important for patients with SCD to be knowledgeable about the condition, since it has potentially devastating sequelae. Nurses can emphasize the importance of reporting recurrent events and seeking medical attention for prolonged episodes within four hours of onset.

 

ACUTE CHEST SYNDROME

ACS was the leading cause of death in the Dallas Newborn Cohort of patients with SCD9 and one of the most frequent causes of hospitalization in SCD.5 ACS is characterized by pleuritic chest pain, fever, rales on auscultation, and pulmonary infiltrates on chest X-ray.5 It can resemble other acute respiratory illnesses, including pneumonia, asthma exacerbation, or bronchiolitis.

 

Patient age affects presentation, etiology, and severity of ACS. Incidence is highest in children ages two to four years,5 but severity tends to be higher in adults, in whom studies have found mortality rates to be up to four times higher than in children.31 Children are more likely to present with wheezing, fever, and cough, whereas adults more often present with dyspnea, pain (commonly in the chest, ribs, sternum, arms, or legs), productive cough, and hemoptysis. ACS frequently occurs during hospitalization for VOE and following surgery.31, 32 In many cases, a cause is not evident or easily discernible. However, the most common etiologies are infection, followed by fat emboli from infarcted bone marrow. Following onset of symptoms, ACS can rapidly progress to respiratory failure, acute respiratory distress syndrome, or multisystem organ failure.

 

All patients with ACS should be hospitalized.15 Analgesia should be sufficient to reduce respiratory splinting and hypoventilation without causing atelectasis.33 Guidelines on the clinical management of ACS were published in 2015.18 Among the recommendations in the guidelines are aggressive incentive spirometry (10 maximum inspirations) every two hours while the patient is awake to prevent atelectasis and the development of ACS during hospitalization for VOE.18, 19 Although iv fluid administration is frequently a component of VOE management, excessive fluids can cause pulmonary edema and precipitate ACS.18

 

Nursing implications. Nurses can reduce the incidence of ACS by encouraging use of the incentive spirometer. Nurses can teach patients and family members the importance of appropriate use of the incentive spirometer and remain alert for subtle changes in respiratory status, such as increased work of breathing, decreased oxygen saturation, and new symptoms of cough or shortness of breath. Any change in respiratory status should be reported promptly to the primary care provider.

 

STROKE

Children and adults with SCD are at risk for cerebrovascular accidents such as ischemic stroke, hemorrhagic stroke, and silent stroke, also known as SCI. Analysis of clinical data on 4,082 SCD patients in the Cooperative Study of Sickle Cell Disease (CSSCD) provided the following prevalence estimates for cerebrovascular accidents in patients whose SCD genotype could be confirmed34:

 

* HbSS, 4.01%

 

* HbS[beta]0-thalassemia, 2.43%

 

* HbS[beta]+-thalassemia, 1.29%

 

* HbSC, 0.84%

 

 

SCIs, the most common strokes in children with SCD, are small infarctions detectable only by magnetic resonance imaging (MRI). Children with SCI typically present with no acute neurologic signs or symptoms. However, any child with SCD who presents with progressive neurocognitive deficits should have MRI screening for SCI because, though SCI most commonly occurs in SCA (before age six in approximately 27% of these children and before age 14 in approximately 37%), it also occurs in 3% to 38% of patients with HbS[beta]+-thalassemia and in 5% to 31% of patients with HbSC.6, 35 Risk factors for SCI include low Hb levels, elevated systolic blood pressure, and male sex.6

 

Nursing implications. Nurses should maintain a high index of suspicion for SCI in patients with SCD who have neurologic signs or symptoms. Any acute changes in neurologic symptoms, including altered mental status during a hospitalization, should be immediately reported to the patient's primary care provider. Parents should be advised that poor academic performance is a red flag for potential neurocognitive deficits, possibly resulting from SCIs, and should be discussed with the child's health care team.

 

Ischemic stroke is common in both young children and adults with SCD. The CSSCD found that among patients with the HbSS genotype, in whom all types of cerebrovascular accidents are more prevalent, incidence of ischemic stroke is highest in children ages two to nine years.34 In addition to having the HbSS genotype, risk factors for ischemic stroke include recent or recurrent ACS, elevated systolic blood pressure, low Hb level, prior transient ischemic attacks, and history of meningitis.

 

Transcranial Doppler (TCD) ultrasound. Prior to a first stroke, cerebral blood flow velocity may be elevated in children secondary to intracranial arterial stenosis.36 Ischemia may also occur because the narrowing of the vessel reduces the amount of blood that can flow through to the tissues. Elevated blood flow velocity can be measured by noninvasive TCD ultrasound. Positive TCD screens may warrant blood transfusion or hydroxyurea to reduce blood flow velocity and prevent stroke.37, 38 The NHLBI recommends annual TCD screening of children with SCA, starting at age two and continuing through age 16, with referral to a specialist when results fall outside the normal range.15

 

Nursing implications. Nurses should reinforce with parents the need to seek care for any emerging neurologic symptoms in their children with SCD and teach them the importance of routine TCD screening of children with SCA.

 

Hemorrhagic stroke. The CSSCD found that hemorrhagic strokes occur most commonly in young adults ages 20 to 29 and were associated with a mortality rate of 24% overall and 26% in patients with the HbSS genotype.34 Hemorrhagic strokes, which are associated with weakened cerebral blood vessels and aneurysms, usually occur suddenly, with symptoms of severe headache; vomiting; seizures; and changes in alertness, sensation, and language.39 Risk factors for hemorrhagic stroke include low Hb level, high leukocyte count, and history of ACS.34, 39

 

SPLENIC COMPLICATIONS

The spleen is one of the first organs affected by SCD. In children with SCA, hyposplenism, a physiological reduction in spleen function, is usually evident within the first year of life.40 Splenic dysfunction is believed to stem from vasoocclusion of the organ by sickled erythrocytes and subsequent ischemia, fibrosis, and progressive atrophy of the organ. The spleen is a major filter of the blood and plays an important role in immune defense as well as in vascular and blood homeostasis by removing senescent or altered red blood cells, microorganisms, and blood-borne antigens. Splenic damage puts patients at risk for immune dysfunction, vascular narrowing and occlusion, and severe bacterial infection. People with SCD remain at high risk for infection and sepsis throughout life.

 

Nursing implications. Patient and family teaching should emphasize the importance of receiving all recommended immunizations as well as annual influenza vaccines. Parents should be taught the importance of recognizing fever early and notifying their child's primary care provider. Elevated temperatures in hospitalized children should be immediately reported to the primary care provider because a sepsis evaluation may be necessary.

 

Acute splenic sequestration crisis. The splenic damage seen in patients with SCD is typically silent and progressive, but it becomes clinically apparent in acute splenic sequestration crisis (ASSC), a life-threatening complication involving rapid accumulation of sickled erythrocytes within the spleen.41 ASSC is defined as sudden splenomegaly, a reduction in Hb concentration of at least 2 g/dL, and a normal or elevated basal reticulocyte count. The spleen enlarges within a period of hours, trapping a large portion of circulating erythrocytes and acutely worsening the anemia and circulatory failure. Symptoms include abdominal pain and distension, pallor, tachycardia, hypotension, and lethargy. Hypovolemic shock and death from cardiovascular collapse can occur within hours if untreated. In children with SCD, ASSC is one of the earliest life-threatening complications and may be the first clinical manifestation of the disease, occurring at a median age of 1.4 years, and as early as several weeks of age.42 More than 12% of children with SCA experience ASSC, and 67% of those go on to have at least one more occurrence. In patients with HbSC, sequestration may occur in early and late adulthood.43

 

INFECTION AND SEPSIS

All SCD genotypes put patients at increased risk for severe infection-particularly invasive bacterial infection-throughout life. This increased susceptibility is largely due to splenic and immune dysfunction. Young children with SCA in particular are at elevated risk for pneumonia, septicemia, and meningitis.44, 45 Incidence of these infections is lower in patients with HbSC and HbS[beta]+-thalassemia genotypes because splenic function is typically normal or only minimally impaired in infancy. The risk, however, is present in later childhood and adulthood.46 Other infections are also common in SCD. VOE of the bone and subsequent necrosis predisposes patients to osteomyelitis.47 Parvovirus B19, which is often asymptomatic in those without SCD, can trigger aplastic crisis and life-threatening anemia in people with SCD.48 Risk of catheter-related infections is also higher in SCD. Infection is a common precipitant of VOE and the most common cause of ACS.32 Because of increased risks of infection, including infection with penicillin-resistant organisms, and incomplete vaccination in patients with SCD, any fever higher than 101.3[degrees]F (38.5[degrees]C) is considered a medical emergency requiring further evaluation.15

 

Nursing implications. Nurses should closely monitor vital sign trends, particularly temperature, in patients with SCD. Elevations in fever should be reported to the primary care provider immediately. Nurses should also teach patients and parents the importance of monitoring temperature and the need for age-appropriate immunizations.

 

ORGAN FAILURE

Renal disease. It's estimated that 16% to 18% of overall mortality in SCD is related to renal complications.49 The most common renal complication in SCD is hyposthenuria (the inability to concentrate urine), which can lead to urinary frequency, enuresis, and increased risk of intravascular volume depletion.50 Compared with the general U.S. population, patients with SCD are two to three times as likely to develop acute renal failure or chronic kidney disease.51

 

Adults with serum creatinine elevations above 1 mg/dL and children with elevations above 0.7 mg/dL are classified as having renal impairment and should receive nephrology consultation.15 Microalbuminuria is the first manifestation of chronic kidney disease, and all patients with SCD should be screened for proteinuria annually beginning at age 10.15 Risk factors for both acute renal failure and chronic kidney disease include the following51:

 

* advanced age

 

* male sex

 

* proteinuria

 

* diabetes

 

* hypertension

 

* chronic heart disease

 

* history of blood transfusion

 

 

Additional risk factors for chronic kidney disease include hypertension and dyslipidemia.51

 

Nursing implications. Nurses should be aware of the renal status of all patients with SCD and pay careful attention to kidney disease risk factors throughout hospitalization. Nurses should also maintain a high index of suspicion for proteinuria and decreased urine output, bearing in mind the patient's dialysis schedule. When patients are hospitalized, all health care team members need to work together to minimize disruptions to this schedule.

 

Multisystem organ failure in SCD is usually characterized by dysfunction of at least two or three major organ systems and often develops after several days of hospital treatment for a VOE, when pain is improving.22 Deterioration is typically rapid and associated with fever, nonfocal encephalopathy, and decreased Hb and platelet levels. Significant overlap between severe ACS due to fat emboli and multisystem organ failure has been noted. Multisystem organ failure is thought to result in part from diffuse microvascular occlusion and tissue ischemia.4

 

Nursing implications. Multisystem organ failure may occur rapidly in any patient with SCD. It is often signaled by changes in respiratory status or renal function. Nurses should consider any elevation in respiratory rate or reduction in oxygen saturation to be a potential early sign of ACS and report such signs to the patient's primary care provider. Renal function and iv fluid administration should also be monitored, especially in patients with a history of renal failure.

 

PSYCHOSOCIAL COMPLICATIONS

People with SCD suffer from a high incidence of social and behavioral health complications. Anxiety and depression have been reported to be as high as 7% and 28%, respectively, in these patients.52 Social and behavioral health complications can occur throughout life.

 

Severe disease may cause young children to miss school, limit college and job opportunities for young adults, and reduce career opportunities for older adults. Such losses present significant financial challenges, often limiting access to health care, insurance, and necessary medications. Interviews with 147 ED patients with SCD, conducted by social workers over a 14-month period, revealed that 27% and 17% of patients, respectively, experienced difficulties obtaining insurance coverage and meeting copay requirements for prescriptions.53 Other issues that may affect patients' ability to manage SCD effectively include navigating the time and transportation challenges involved in seeing numerous health care specialists while trying to work and take care of family responsibilities. It is not uncommon for patients to need to see an ophthalmologist, orthopedic surgeon, or nephrologist in addition to a sickle cell specialist and primary care provider.

 

Nursing implications. Nurses should assess patients, especially those with frequent ED visits and hospitalizations, for behavioral health complications to identify those who may benefit from social work, psychiatric, or case management referral. Patients should also be screened for depression, anxiety, and other social and behavioral determinants of health. When possible, nurses should refer patients with such complications to the social worker or case manager, who may be able to guide them in seeking extra support. A strong social support network is key to effective disease management and to a good quality of life in those with SCD.

 

Sickle Cell Disease Clinical Care Resources

American Society of Hematology

 

Pocket guides for clinicians can be downloaded or ordered, such as Management of Acute Complications of Sickle Cell Disease, Health Maintenance and Management of Chronic Complications of Sickle Cell Disease, and Hydroxyurea and Transfusion Therapy for the Treatment of Sickle Cell Disease.

 

http://www.hematology.org/Clinicians/Guidelines-Quality/Quick-Reference.aspx

 

Centers for Disease Control and Prevention

 

Materials and Multimedia on Sickle Cell Disease

 

https://www.cdc.gov/ncbddd/sicklecell/materials/index.html

 

National Heart, Lung, and Blood Institute

 

Evidence-Based Management of Sickle Cell Disease: Expert Panel Report, 2014

 

http://www.nhlbi.nih.gov/health-topics/evidence-based-management-sickle-cell-dis

 

National Institute for Children's Health Quality

 

On the Resources page, you can sign up for the Sickle Cell Disease Treatment Demonstration Program Compendium of Tools and Materials

 

http://www.nichq.org/resource/sickle-cell-disease-treatment-demonstration-progra

 

REFERENCES

 

1. Hassell KL Population estimates of sickle cell disease in the U.S Am J Prev Med 2010 38 4 Suppl S512-S521 [Context Link]

 

2. Adesina O, et al Osteonecrosis of the femoral head in sickle cell disease: prevalence, comorbidities, and surgical outcomes in California Blood Adv 2017 1 16 1287-95 [Context Link]

 

3. Adeyoju AB, et al Priapism in sickle-cell disease; incidence, risk factors and complications-an international multicentre study BJU Int 2002 90 9 898-902 [Context Link]

 

4. Ataga KI, Orringer EP Renal abnormalities in sickle cell disease Am J Hematol 2000 63 4 205-11 [Context Link]

 

5. Castro O, et al The acute chest syndrome in sickle cell disease: incidence and risk factors. The Cooperative Study of Sickle Cell Disease Blood 1994 84 2 643-9 [Context Link]

 

6. DeBaun MR, et al Silent cerebral infarcts: a review on a prevalent and progressive cause of neurologic injury in sickle cell anemia Blood 2012 119 20 4587-96 [Context Link]

 

7. National Institutes of Health Consensus Development Conference. Newborn screening for sickle cell disease and other hemoglobinopathies JAMA 1987 258 9 1205-9 [Context Link]

 

8. Benson JM, Therrell BL Jr. History and current status of newborn screening for hemoglobinopathies Semin Perinatol 2010 34 2 134-44 [Context Link]

 

9. Quinn CT, et al Improved survival of children and adolescents with sickle cell disease Blood 2010 115 17 3447-52 [Context Link]

 

10. Shankar SM, et al Medical care utilization and mortality in sickle cell disease: a population-based study Am J Hematol 2005 80 4 262-70 [Context Link]

 

11. Brousseau DC, et al Acute care utilization and rehospitalizations for sickle cell disease JAMA 2010 303 13 1288-94 [Context Link]

 

12. Platt OS, et al Pain in sickle cell disease. Rates and risk factors N Engl J Med 1991 325 1 11-6 [Context Link]

 

13. Yawn BP, et al Management of sickle cell disease: summary of the 2014 evidence-based report by expert panel members JAMA 2014 312 10 1033-48 [Context Link]

 

14. Smith LA, et al Sickle cell disease: a question of equity and quality Pediatrics 2006 117 5 1763-70 [Context Link]

 

15. National Heart, Lung, and Blood Institute. Evidence-based management of sickle cell disease: expert panel report (EPR), 2014. Bethesda, MD; 2014 Sep. Evidence report; https://www.nhlbi.nih.gov/sites/default/files/media/docs/sickle-cell-disease-rep. [Context Link]

 

16. Lanzkron S, et al The burden of emergency department use for sickle-cell disease: an analysis of the national emergency department sample database Am J Hematol 2010 85 10 797-9 [Context Link]

 

17. Platt OS, et al Mortality in sickle cell disease. Life expectancy and risk factors for early death N Engl J Med 1994 330 23 1639-44 [Context Link]

 

18. Howard J, et al Guideline on the management of acute chest syndrome in sickle cell disease Br J Haematol 2015 169 4 492-505 [Context Link]

 

19. Bellet PS, et al Incentive spirometry to prevent acute pulmonary complications in sickle cell diseases N Engl J Med 1995 333 11 699-703 [Context Link]

 

20. Darbari DS, et al Severe painful vaso-occlusive crises and mortality in a contemporary adult sickle cell anemia cohort study PLoS One 2013 8 11 e79923 [Context Link]

 

21. Bainbridge R, et al Clinical presentation of homozygous sickle cell disease J Pediatr 1985 106 6 881-5 [Context Link]

 

22. Hassell KL, et al Acute multiorgan failure syndrome: a potentially catastrophic complication of severe sickle cell pain episodes Am J Med 1994 96 2 155-62 [Context Link]

 

23. Manci EA, et al Causes of death in sickle cell disease: an autopsy study Br J Haematol 2003 123 2 359-65 [Context Link]

 

24. Williams H, Tanabe P Sickle cell disease: a review of nonpharmacological approaches for pain J Pain Symptom Manage 2016 51 2 163-77 [Context Link]

 

25. Dampier C, et al AAPT diagnostic criteria for chronic sickle cell disease pain J Pain 2017 18 5 490-8 [Context Link]

 

26. Ballas SK Pain management of sickle cell disease Hematol Oncol Clin North Am 2005 19 5 785-802 [Context Link]

 

27. Smith WR, et al Daily assessment of pain in adults with sickle cell disease Ann Intern Med 2008 148 2 94-101 [Context Link]

 

28. Junior GB da Silva, et al Osteoarticular involvement in sickle cell disease Rev Bras Hematol Hemoter 2012 34 2 156-64 [Context Link]

 

29. Milner PF, et al Sickle cell disease as a cause of osteonecrosis of the femoral head N Engl J Med 1991 325 21 1476-81 [Context Link]

 

30. Mantadakis E, et al Prevalence of priapism in children and adolescents with sickle cell anemia J Pediatr Hematol Oncol 1999 21 6 518-22 [Context Link]

 

31. Vichinsky EP, et al Acute chest syndrome in sickle cell disease: clinical presentation and course. Cooperative Study of Sickle Cell Disease Blood 1997 89 5 1787-92 [Context Link]

 

32. Vichinsky EP, et al Causes and outcomes of the acute chest syndrome in sickle cell disease. National Acute Chest Syndrome Study Group N Engl J Med 2000 342 25 1855-65 [Context Link]

 

33. Needleman JP, et al Breathing patterns during vaso-occlusive crisis of sickle cell disease Chest 2002 122 1 43-6 [Context Link]

 

34. Ohene-Frempong K, et al Cerebrovascular accidents in sickle cell disease: rates and risk factors Blood 1998 91 1 288-94 [Context Link]

 

35. DeBaun MR, et al Associated risk factors for silent cerebral infarcts in sickle cell anemia: low baseline hemoglobin, sex, and relative high systolic blood pressure Blood 2012 119 16 3684-90 [Context Link]

 

36. Adams R, et al The use of transcranial ultrasonography to predict stroke in sickle cell disease N Engl J Med 1992 326 9 605-10 [Context Link]

 

37. Adams RJ, et al Prevention of a first stroke by transfusions in children with sickle cell anemia and abnormal results on transcranial Doppler ultrasonography N Engl J Med 1998 339 1 5-11 [Context Link]

 

38. Ware RE, et al Hydroxycarbamide versus chronic transfusion for maintenance of transcranial doppler flow velocities in children with sickle cell anaemia-TCD With Transfusions Changing to Hydroxyurea (TWiTCH): a multicentre, open-label, phase 3, non-inferiority trial Lancet 2016 387 10019 661-70 [Context Link]

 

39. Redding-Lallinger R, Knoll C Sickle cell disease-pathophysiology and treatment Curr Probl Pediatr Adolesc Health Care 2006 36 10 346-76 [Context Link]

 

40. Rogers ZR, et al Biomarkers of splenic function in infants with sickle cell anemia: baseline data from the BABY HUG Trial Blood 2011 117 9 2614-7 [Context Link]

 

41. Topley JM, et al Acute splenic sequestration and hypersplenism in the first five years in homozygous sickle cell disease Arch Dis Child 1981 56 10 765-9 [Context Link]

 

42. Brousse V, et al Acute splenic sequestration crisis in sickle cell disease: cohort study of 190 paediatric patients Br J Haematol 2012 156 5 643-8 [Context Link]

 

43. Koduri PR, Kovarik P Acute splenic sequestration crisis in an adult with sickle beta-thalassemia Ann Hematol 2006 85 9 633-5 [Context Link]

 

44. Rogers DW, et al Early splenomegaly in homozygous sickle-cell disease: an indicator of susceptibility to infection Lancet 1978 2 8097 963-5 [Context Link]

 

45. Zarkowsky HS, et al Bacteremia in sickle hemoglobinopathies J Pediatr 1986 109 4 579-85 [Context Link]

 

46. Zarrouk V, et al Bloodstream infection in adults with sickle cell disease: association with venous catheters, Staphylococcus aureus, and bone-joint infections Medicine (Baltimore) 2006 85 1 43-8 [Context Link]

 

47. Neonato MG, et al Acute clinical events in 299 homozygous sickle cell patients living in France. French Study Group on Sickle Cell Disease Eur J Haematol 2000 65 3 155-64 [Context Link]

 

48. Serjeant GR, et al Outbreak of aplastic crises in sickle cell anaemia associated with parvovirus-like agent Lancet 1981 2 8247 595-7 [Context Link]

 

49. Nath KA, Hebbel RP Sickle cell disease: renal manifestations and mechanisms Nat Rev Nephrol 2015 11 3 161-71 [Context Link]

 

50. Francis YF, Worthen HG Hyposthenuria in sickle cell disease J Natl Med Assoc 1968 60 4 266-70 [Context Link]

 

51. Yeruva SL, et al Renal failure in sickle cell disease: prevalence, predictors of disease, mortality and effect on length of hospital stay Hemoglobin 2016 40 5 295-9 [Context Link]

 

52. Levenson JL, et al Depression and anxiety in adults with sickle cell disease: the PiSCES project Psychosom Med 2008 70 2 192-6 [Context Link]

 

53. Smith SK, et al Identifying social-behavioral health needs of adults with sickle cell disease in the emergency department J Emerg Nurs 2017 43 5 444-50 [Context Link]

 

For five additional continuing nursing education activities related to sickle cell disease, go to http://www.nursingcenter.com/ce.

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