Keywords Lymphedema, bone fracture, bone break, Displaced Bone Fracture, Undisplaced Bone Fracture, Hairline Fracture, Pathological Bone Fracture, Compound Bone Fracture, Long Bone Fracture, Spiral Fracture, Comminuted Fracture
This is highly unusual and even many lymphedema experts are unaware this can occur.
If we start with the premise that some people are born with an already “at risk” lymph system and then understand the exact mechanisms of the lymphatic system response to trauma and the changes within the lymph nodes, then it becomes clear that this is in fact a possibility.
I need to remind readers that I am not a medical professional nor have I ever had formal medical training and/or education. What is presented is a combination of my fifty-five years of living with lymphedema and from the research that I have undertaken.
J Orthop Sci. 2007 Nov;
Arslan H, Uludağ A, Kapukaya A, Gezici A, Bekler HI, Ketani A. Department of Orthopedic and Trauma Surgery, University of Dicle, School of Medicine, Diyarbakir, Turkey.
BACKGROUND: Lymphedema delays the healing of any wound by negatively affecting its inflammatory period. Whether it affects bone healing in a similar negative manner is unknown. Therefore, we experimentally investigated the effect of lymphedema on fracture recovery.
METHODS: We used thirty 200- to 250-g Sprague-Dawley rats for the experiment. The rats were randomly divided into two groups of 15 rats each for the experimental lymphedema and control groups. Lymphedema development was confirmed by measuring the circumference and diameter of the extremities together with lymphoscintigraphy. Twenty days after the development of lymphedema, a fracture model was created in both groups in the right tibia with mid-diaphyseal osteotomy and fixing with an intramedullary Kirschner wire. After 6 weeks, all rats were sacrificed and the callus tissue that formed along the osteotomy was compared between groups with respect to radiographic, histological, and biomechanical characteristics.
RESULTS: The three-point bending test yielded an average stiffness value of 1227 N/mm (n = 6) in the control group and 284 N/mm (n = 7) in the experimental lymphedema group (P < 0.05). At the end of week 6, radiographic evaluation showed that solid knitting was obtained in the control group, whereas in the lymphedema group delayed or no knitting was observed. In the control group, histological investigation revealed normal callus morphology. Trabecular bone was normal and osteoblast and osteoclast activity was clearly evident. The bone was stained homogeneously with hematoxylin and eosin, and ossification was within normal limits. In the lymphedema group, however, the histological appearance was mostly that of scar tissue. In addition, osteoblast and osteoclast activity was much less visible or absent.
CONCLUSIONS: Lymphedema negatively affected bone healing in rats. However, the mechanism of this negative effect and its occurrence in humans are still unknown. Further experimental and clinical studies are needed to support and extend our findings.
Szczesny G, Olszewski WL, Gewartowska M, Zaleska M, Górecki A. Department of Surgical Research and Transplantology, Medical Research Centre, Polish Academy of Sciences, Warsaw, Poland. firstname.lastname@example.org
BACKGROUND: Damage of tissues by mechanical injury and inflammation is followed by reaction of the regional lymphoid tissue, lymphatics, and lymph nodes. In our previous lymphoscintigraphic studies, we showed that closed fractures of a lower limb cause reaction of the local lymphoid tissue. There was dilation of lymphatics draining the site of the fracture and enlargement of inguinal lymph nodes. These changes persisted even after clinical healing of the fracture. In the long-lasting nonhealing fractures, the lymphoscintigraphic pictures were different. The draining lymphatics became obliterated, and the lymph nodes disappeared.
METHODS: In this study, we tried to correlate the lymphoscintigraphic images, reflecting the immune events at the fracture site, with the immunohistochemical observations of the biopsy specimens obtained during corrective operations from the healing and nonhealing fracture gaps. Thirty-eight patients with closed fracture of the tibia without traumatic skin changes were studied.
RESULTS: We confirmed that closed tibial fracture evokes response of the regional lymphatic system. Normal fracture healing with immune cell infiltrates and foci of ossification was accompanied by dilated lymphatics and enlarged lymph nodes. Prolonged nonhealing fracture with lack of cellular reaction in the gap proceeded with decreased mass of lymph nodes.
CONCLUSION: This study provides evidence for existence of a functional axis between wound of bone and surrounding soft tissue and the local lymphatic (immune) system. We hypothesize that the fast healing is regulated by influx into the wound of lymph node regulatory cells, whereas prolonged healing causes gradual exhaustion of the regional lymph node functional elements, and reciprocally impairment in sending regulatory cells to the fracture gap.
Lymphat Res Biol. 2005
Szczesny G, Olszewski WL, Gorecki A. Department of Surgical Research, Medical Research Centre, Polish Academy of Sciences, Warsaw, Poland. email@example.com
Closed bone fractures, and torn muscles and tendons are “internal wounds”. What kind of reaction do they evoke in the local and systemic immune system? Cellular debris of damaged tissue and extravasated blood cells are removed by scavenger cells. They are transported via lymphatics to the lymph nodes. There elimination of self antigens takes place. Clinically, no enlargement of lymph nodes is observed after closed fractures and soft tissue damage. The question arises whether there is really no enlargement of regional lymph nodes, in other words, no reaction to damaged cell antigens. This question was studied by using lymphoscintigraphy to visualize lymphatics and lymph nodes draining the site of closed bone fracture. The lymphoscintigraphic pictures of two groups of patients, those with a rapid noncomplicated healing of leg fractures, and those with protracted healing and undergoing surgical reconstructions, were evaluated. The surface area of lymphatic pathways and inguinal lymph nodes on the injured and contralateral normal limb were measured. Enlarged superficial lymphatics and inguinal lymph nodes were found in limbs with healed bone fractures, and decreased inguinal lymph nodes and visualization of deep lymphatics and popliteal nodes in the majority of patients with nonhealing fractures. There was a lack of correlation between age of patients, duration of healing, and surgical interventions and the lymphoscintigraphic changes.
These findings suggest that the fracture gap tissue is a dominant source of signals to the lymph nodes, releasing cellular and humoral regulatory factors. Taken together, there is a strong immune reaction of lymph node to the fracture, although it cannot be recognized clinically.
Lymphat Res Biol. 2004;
Szczesny G, Olszewski WL, Zaleska M. Department of Surgical Research and Transplantology, Medical Research Centre, Polish Academy of Sciences, 02-106 Warsaw, Poland. firstname.lastname@example.org
In previous clinical studies, dilation of afferent lymphatics and enlargement of inguinal lymph nodes (LN) were observed in lymphoscintigrams from patients with persistent posttraumatic edema of lower extremities after fractures and trauma of soft tissues. In this study, changes in rat popliteal and iliac lymph nodes draining lymph from the site of tibial fracture and adjacent soft tissue injury were investigated. The observed parameters were lymph node weight, cell number, phenotype frequency, cell cytokine expression, and reactivity to mitogens. The key observations included: a) increase in the weight and total cell number of the lymph nodes; b) increased autotransformation rate and responsiveness of lymph node cells to mitogen; c) decreased frequency of ED1 macrophages and activated OX8 cytotoxic cells in flow cytometry analysis; d) high expression of OX6 class II-positive, OX7 (stem cells), OX62 (migrating dendritic cells), ED1 (macrophages), and OX12 (B cells) on immunohistochemical sections of LNs with some few HIS48 (granulocytes); e) high expression of NOS3 and TGF beta by lymph node lymphocytes and endothelial cells.
In summary, local lymph nodes reacted to internal wounds, such as bone fracture and injury to adjacent tissues, through mobilization of cells from the blood circulation, along with activation of cellular subsets. The molecular mechanism that provides the signal for this reaction remains unknown. The absence of major changes in the frequency of lymph node cell subpopulations indicates that lymph nodes are constitutively prepared for influx of antigens from damaged tissues and react only with increase in cell number and cell activation. The nature of the reaction, including lack of immunization against autoantigens, remains unclear. Further elucidation will require studies on the mechanism of cross-tolerance to self-antigens during wound healing.
By David A. Kasper, DO, MBA; Menachem M. Meller, MD, PhD ORTHOPEDICS 2008; 31:172 February 2008
Lymphedema of the hand following a fracture of the distal radius is a rare complication resulting from abnormal protein-rich fluid accumulation in the affected area. Although lymphedema affects approximately 2.5 million Americans and frequently is associated with breast cancer treatment, its occurrence in the context of a commonplace injury to the wrist is virtually nonexistent.1
The etiology of lymphedema development following fracture care is poorly understood and has been attributed to psychogenic causes. Only one case of lymphedema following a Colles fracture has been reported in the literature.2 In that report, the patient was a 42-year old man who presented with lymphedema after a fall while accidentally being pulled by a chain. After closed reduction of the fracture and immobilization, the patient reported intense pain without swelling. Immediately after removal of the patient’s final cast, his hand began to swell, and he underwent intense physiotherapy, numerous sympathetic nerve blocks, and hospitalization with no improvement. The authors suggested the pathogenesis of the patient’s lymphedema after his fracture was self-induced and psychogenic in nature.
This article presents a case of Colles fracture complicated by nonpitting edema in a 62-year-old woman in whom psychogenic causes were not identified.
A 62-year-old right hand-dominant woman fell down a few steps at work onto her outstretched right hand. Evaluation in the emergency room indicated a fracture of the distal radius, and the patient underwent closed reduction (Figure 1) under general anesthesia without a tourniquet. This resulted in excellent restoration of the skeletal alignment. She was placed in a well-padded short arm cast.
At a routine follow-up visit 10 days later, the patient had complete loss of position, with the fracture reverting to the presurgical misalignment sustained immediately following the injury. She subsequently underwent open reduction and internal fixation using a dorsal plate. Both the surgery and postoperative course were uneventful.
The patient’s history included controlled hypertension, mitral valve prolapse, gastroesophageal reflux disease, rheumatic fever, scarlet fever, and a prior arthroscopic knee procedure. She reported no prior malignancies, and she was compliant with routine general medical care. Psychological profiling was normal
Following cast removal, the patient began occupational and physical therapy. Two months postoperatively, the swelling persisted, and she developed increasing asymmetry. She also had progressive nonpitting edema. The patient reported having no pain, hypersensitivity, or other symptoms. She also reported she did not develop any other illnesses or malignancies during this time.
The patient underwent an extensive workup that included electrodiagnostic studies and radiographs of the cervical spine, right shoulder, and right wrist (Figure 2). Computed tomography and magnetic resonance imaging revealed prominent edema adjacent to the capsule (Figure 3). An intravenous Doppler study ruled out deep vein thrombosis of the right upper extremity. A Duplex arterial scan and technetium bone scan revealed no pathological findings other than the fractured wrist.
Her fracture healed satisfactorily without additional loss of position. However, the function of her right hand was limited by the edema (Figure 4). Traditional treatments, such as a Jobst gauntlet (BSN-Jobst, Inc, Charlotte, North Carolina), Kinesio taping (Kinesio, Albuquerque, New Mexico), massage, elevation, and Isotoner gloves (Totes Isotoner Corp, Cincinnati, Ohio) supplemented by home exercises failed to relieve her symptoms.
Treatment subsequently was prescribed with the NormaTec PCD (pneumatic compression device; NormaTec, Newton Center, Massachusetts), and the patient initially used it at home for 4 hours daily. Within 2 weeks, her massive forearm edema dramatically diminished, and her wrist and hand motion normalized. She was able to bring her fingertips down to the proximal palmar crease with good grip, pinch, and opposition.
To inhibit the recurrence of the edema and hand stiffness, the patient has continued to use the device at home approximately 1 hour per week. She requires no compression garments and has not had any episodes of cellulitis (Figure 5).
Although lymphedema is a common and severely disabling medical condition, it has not been described following orthopedic injuries such as a Colles fracture. The only previously published case report describing this injury combination attributed the lymphedema to psychogenic causes.2 In our patient, psychogenic causes were not identified.
Lymphedema results when the lymphatic volume in tissue exceeds the lymphatic transport system’s capabilities to clear the fluid. Increased hydrostatic pressure or decreased plasma oncotic pressure creates gradients across the capillary membranes, which causes the excess fluid to spill and accumulate in the interstitial space. Possible causes of this excess fluid production include local inflammation, surgery, infection, cancer, lymphatic obstruction (ie, due to scarring), and trauma.3 Although all body tissues are bathed in interstitial fluid, the lymph circulation still remains a complex, dynamic, and incompletely understood process.4
Lymphedema can be classified into two types: primary and secondary. Primary lymphedema is associated with hypoplastic, hyperplastic, missing, or impaired lymph vessels. Other presentations are classified further by age of onset. However, causes of primary lymphedema are generally unknown and cannot be linked to any specific traumatic event. The most common cause of primary lymphedema is lymphangiodysplasia.
Secondary lymphedema can be attributed to trauma to the lymph nodes or the lymphatic vessels themselves. Secondary lymphedema frequently is seen in surgical patients and is attributed to lymphatic obstruction.3 Speculations suggest secondary lymphedema associated with trauma is a consequence of an infectious or inflammatory process.3
Mechanical injury of the soft tissues and bones of the extremities usually is followed by edema distal to the site and at the site itself but not proximal to it. Patients usually present with a sensation of fullness and pain in the affected area, induration, edema, hyperkeratosis, and xerosis. Functional limitations include decreased range of motion, joint inflexibility, decreased mobility (if the lower limb is affected), and decreased activities of daily living (eg, grooming and dressing).3
For several decades, treatments to relieve lymphedema and traumatic or postoperative edema included manual massage, gradient compression stockings and sleeves, bandaging, taping, and pneumatic compression devices previously referred to as lymphedema pumps. All of these treatments used external compression, but none produced consistently good clinical outcomes. Additionally, these treatments used static compression strategies, with compression applied and held constant for varying lengths of time. Most of the lymphedema pumps were poorly bioengineered, and their designs lacked understanding of the optimum parameters for noninvasive compression.
Recently, the concept of pneumatic medicine was developed to more clearly characterize and advance the science of external compression strategies. As defined by Avery et al,5 pneumatic medicine is the use of noninvasive, dynamic compression to treat the array of peripheral vascular disorders, including arterial insufficiency, chronic wounds, venous insufficiency, and lymphedema.
The NormaTec PCD uses a multi-cell sleeve or boot that is placed on the affected limb and pneumatically inflated and deflated via a unique Peristalic Pulse dynamic compression strategy. The patented Peristalic Pulse pneumatic waveform consists of a “pulse, gradient hold, release” compression cycle, simulating normal physiology. It incorporates three major physiological concepts: dynamic pulsing compression as seen in the muscle pump of a normal limb, directionality of flow similar to the venous and lymphatic one-way valves, and the effective movement of fluids created by peristalsis. The parameters of the NormaTec PCD are programmed by the physician, and the patient then uses the device independently at home.
A full functional outcome for our patient, who had chronic, clinically significant symptoms, was achieved in a brief period of time after numerous other treatments failed. The Peristalic Pulse compression strategy dynamically decongested the edematous tissues, and her hand and wrist range of motion improved markedly. Our patient has continued to use the device approximately 1 hour per week as maintenance therapy to prevent the return of edema and upper extremity stiffness. No compression garment is required, and compliance with the treatment program has been excellent.
A pathological anomaly that may have been a causative agent in our patient’s proximal edema following reduction of her Colles fracture is complex regional pain syndrome. According to the literature, the incidence of patients with Colles fractures who develop complex regional pain syndrome, albeit controversial, ranges between 2% and 37%.6 Although the pathogenesis is poorly understood, complex regional pain syndrome commonly is triggered by minor injuries such as fractures, crush injuries, peripheral nerve injuries, and other precipitating events that involve abnormal sympathetic nervous system activity.
Complex regional pain syndrome is characterized by pain and tenderness that is described as burning or aching in nature and usually occurring at a distal extremity. Patients with complex regional pain syndrome may develop rapid bony demineralization, trophic skin changes, and vasomotor instability that also are disproportionate to the underlying injury.
Complex regional pain syndrome progresses through three clinical phases. The first phase is characterized by an intense burning pain, edema, warmth, and tenderness of a distal extremity, especially noted around the joints. The joints become stiff, and pain is reproduced on passive and active motion of the joint. During the second phase (3 to 6 months), the patient’s skin becomes thin, cool, and shiny. In the third phase (another 3 to 6 months), the skin becomes atrophic and dry, with progression to flexion contractures and palmar fibromatosis.3
To aid in the diagnosis of complex regional pain syndrome, plain radiographs of patients with fractures may exhibit spotty rarefaction (Sudeck atrophy). Other tests used to substantiate this diagnosis include thermography, bone scan, and sympathetic blockade.
The key component to successful conservative treatment is early diagnosis within 6 to 8 weeks. Conservative treatment modalities include heat, elevation, and desensitization. Chronic disability occurs when the diagnosis and subsequent treatment is delayed. However, some authors have suggested there is no correlation among age, adequacy or number of reductions, or severity of fracture in patients who present with complex regional pain syndrome.3 In our patient, we ruled out complex regional pain syndrome because electromyography, nerve conduction study, radiographs, intravenous Doppler study, duplex arterial scan, and technetium bone scan revealed no pathologic findings other than the fractured wrist.
Some patients present with this syndrome after age 40 years, with the highest incidence in the sixth decade of life. Some patients also present with this anomaly after requiring repeated fracture reductions. Itzchaki et al2 suggested there may be a psychogenic component to this syndrome. Emotional instability was identified in one third of patients with this syndrome.2
Other causes of lymphedema were evaluated extensively in our patient. Local, regional, and metastatic causes such as breast cancer and Pancoast tumor were ruled out as were mechanical dysfunctions such as thoracic outlet syndrome and Milroy disease. Neurological involvement also was ruled out based on normal electroencephalographic readings and nonpathological clinical and physical findings.
The surgical procedure in our patient was uncomplicated and thus lymphedema secondary to any vascular injury was ruled out. Questions that need to be addressed are whether the lymphedema was locally or systemically mediated, or whether the onset of the fracture induced an avascular anastomosis that led to the lymphedema. Our conclusions led us to believe the development of lymphedema of the distal radius following Colles fracture was idiopathic in our patient.
References Norton S. Managing lymphedema. Advance. 2000; 11(10):1-6. Itzchaki M, Ben-Hur N, Ashur H. Lymphedema of the hand following a fracture of the distal radius. Int Surg. 1978; 63(1):29-30. Patel AT. Lymphedema. In: Frontera WR, Silver JK, eds. Essentials of Physical Medicine and Rehabilitation. 1st ed. Philadelphia, PA: Hanley and Belfus; 2002:575-577. St Louis JD, McCann RL. Lymphatic System. In: Townsend CM, ed. Sabiston Textbook of Surgery. 16th ed. Philadelphia, PA: WB Saunders Co; 2001:1446-1450. Avery KB, Solomon AD, Weber RB, Jacobs LF. Treatment of congenital lymphoedema with sequential intermittent pneumatic compression therapy. The Foot. 2000; 10(4):210-215. Stern PJ, Derr RG. Non-osseous complications following distal radius fractures. Iowa Orthop J. 1993; 13:63-69.
Authors Drs Kasper and Meller are from the Department of Orthopedic Surgery, Veterans Hospital, University of Pennsylvania, Philadelphia, Pennsylvania.
Drs Kasper and Meller have no relevant financial relationships to disclose.
Correspondence should be addressed to: Menachem M. Meller, MD, PhD, Department of Orthopedic Surgery, Veterans Hospital, University of Pennsylvania, 424 Stemmler Hall, Philadelphia, PA 19104-6081.
Understanding Bone Fractures – the Basics
The Facts About Broken Bones
Displaced Bone Fracture is when the broken ends of a fracture move away from each other and there is a significant gap between them, when seen on an x-ray. The significant gap is different for different types of bone fractures, for example, a gap of 3-4 mm may be insignificant in a humerus bone fracture, but can be significant in a finger phalanx fracture.
Undisplaced Bone Fracture or Hairline Fracture is when a bone develops a crack or breaks through and through, but the broken ends remain in place, without any displacement or gap. These bone fractures, are best treated with a simple fiberglass or plaster cast and generally do not require surgical treatment. Pathological Bone Fracture is when a bone has been weakened by a disease, like cancer, osteoporosis, etc., and develops a fracture. Such bone fractures do not require a lot of force and are possible after trivial falls or even without any traumatic incident.
Compound Bone Fracture is when the broken bones pierce the skin and create an external wound. These bone fractures are associated with higher rates of infection, due to exposure of the bone to the surrounding dirt and also cause profuse bleeding from the wound. Long Bone Fracture Types
Long bones, like femur (thigh bone), tibia & fibula (leg bones), humerus (arm bone), radius & ulna (forearm bones) or clavicle (collar bone), have particular types of bone fractures, where the edges of broken bones have a characteristic shape. This not only influences the outcome of the bone fracture, but also dictates the bone fracture repair method which can be used for treatment.
Spiral Facture is when a twisting force is applied to a bone, resulting in long curvy edges of the broken bones, like a spiral. Due to the zig-zag nature of the fractured ends of bone, it is slightly easier to treat a spiral fracture of long bones
Comminuted Fracture is when a bone breaks into several small pieces and is the result of high velocity injuries, like car accidents, or falls from a height. Such bone fractures generally are very difficult to treat, and result in a deformity of the injured part even after treatment.