Sandbox: Dr.Reddy

Jump to navigation Jump to search

http://www.aafp.org/afp/2011/0615/p1403.html

[[image:xxx.jpg|thumb|500px|center|]


(({{#ev:youtube|}}))


Overview

Historical Perspective

[Disease name] was first discovered by [name of scientist], a [nationality + occupation], in [year]/during/following [event].

The association between [important risk factor/cause] and [disease name] was made in/during [year/event].

In [year], [scientist] was the first to discover the association between [risk factor] and the development of [disease name].

In [year], [gene] mutations were first implicated in the pathogenesis of [disease name].

There have been several outbreaks of [disease name], including -----.

In [year], [diagnostic test/therapy] was developed by [scientist] to treat/diagnose [disease name].

Classification

There is no established system for the classification of [disease name].

OR

[Disease name] may be classified according to [classification method] into [number] subtypes/groups: [group1], [group2], [group3], and [group4].

OR

[Disease name] may be classified into [large number > 6] subtypes based on [classification method 1], [classification method 2], and [classification method 3]. [Disease name] may be classified into several subtypes based on [classification method 1], [classification method 2], and [classification method 3].

OR

Based on the duration of symptoms, [disease name] may be classified as either acute or chronic.

OR

If the staging system involves specific and characteristic findings and features: According to the [staging system + reference], there are [number] stages of [malignancy name] based on the [finding1], [finding2], and [finding3]. Each stage is assigned a [letter/number1] and a [letter/number2] that designate the [feature1] and [feature2].

OR

The staging of [malignancy name] is based on the [staging system].

OR

There is no established system for the staging of [malignancy name].

Pathophysiology

The exact pathogenesis of [disease name] is not fully understood.

OR

It is thought that [disease name] is the result of / is mediated by / is produced by / is caused by either [hypothesis 1], [hypothesis 2], or [hypothesis 3].

OR

[Pathogen name] is usually transmitted via the [transmission route] route to the human host.

OR

Following transmission/ingestion, the [pathogen] uses the [entry site] to invade the [cell name] cell.

OR


[Disease or malignancy name] arises from [cell name]s, which are [cell type] cells that are normally involved in [function of cells].

OR

The progression to [disease name] usually involves the [molecular pathway].

OR

The pathophysiology of [disease/malignancy] depends on the histological subtype.

Causes

  • Fecal Incontinence may be caused due to the following: [1] [2] [3]
    • Anal sphincter dysfunction/damage
    • Rectal prolapse
    • Surgical procedures of the rectum and anus may lead to muscle or nerve injuries. Anorectal surgical procedures such as hemorrhoidectomy, fistula surgery and sphincterotomy. [2]
    • Impaired rectal sensation
    • Rectocele
    • Damage to the nerves
    • Diarrhea
    • Inflammatory bowel disease
    • Constipation
    • Hemorrhoids
    • Neurologic abnormalities such as multiple sclerosis and pudendal neuropathy
    • Decreased compliance of the rectum

Differentiating Fecal incontinence from Other Diseases

Epidemiology and Demographics

  • The prevalence of fecal Incontinence is approximately 2000-3000 per 100,000 individuals worldwide. [4]
  • In the US, the prevalence of fecal Incontinence is similar in women and men and increases with age, with the prevalence of 8900 per 100,000 individuals in women and 7700 per 100,00 individuals in men. [5]
  • In the US, fecal Incontinence affects 2600 per 100,000 individuals in the age group of 20 to 29 years and in elderly people up to 15,300 per 100,000 individuals who are over the age of 70 years. [5]
  • There is no racial predilection to fecal Incontinence.[5]

Risk Factors

  • Common risk factors in the development of Fecal incontinence include: [5] [6] [7] [8] [9]
    • Age factor: Mostly seen in middle-age and older adult population.
    • Gender: Females are more likely to have fecal incontinence when compared to men. The major risk factor being the complications during childbirth that damage the anal sphincter and injure the pelvic floor muscles and nerves such as:
      • Episiotomy
      • Forceps delivery
      • Prolonged second stage of labor
      • Occipitoposterior presentation of the fetus
      • Pelvic floor injury resulting in significant tears and higher birth-weight of the infant
    • Nerve injury/neuropathy: Damage to the pudendal nerve/pudendal neuropathy
    • Alzheimer's disease and Dementia: Fecal incontinence is usually seen in individuals with Alzheimer's disease(advanced stage) and Dementia.
    • Multiple sclerosis
    • Anorectal congenital abnormalities
    • Radiation therapy of the pelvis
    • Rectal prolapse
    • Hormone therapy: In post-menopausal women, fecal incontinence may be due to hormonal therapy.

Screening

  • There is insufficient evidence to recommend routine screening for fecal incontinence.
  • However, a physician should rule out the symptoms in conditions which may pose as risk factors for developing fecal incontinence.

Natural History, Complications, and Prognosis

  • If left untreated, patients with Fecal incontinence may progress to develop complications such as:
    • Pain and itching in the anal region leading to rashes and ulcers
    • Social withdrawal
    • Emotional distress
    • Depression
    • Insomnia
  • Prognosis: Prognosis is generally excellent/good/poor, and the 1/5/10-year mortality/survival rate of patients with [disease name] is approximately [#]%.

Diagnosis

Diagnostic Study of Choice

  • Reliable scoring systems for the assessment of fecal incontinence based on symptoms and the response received as a result of interventions are:[10] [11]
    • The American Medical System Score
    • The Vaizey Score
    • The Wexner Score

History and Symptoms

  • A thorough and detailed history is crucial while obtaining a history from a patient experiencing fecal incontinence. [2]
  • The history taking should be focused mainly on obstetrical and surgical history apart from medication history and other associated medical conditions if any. [2]
  • Symptoms should be categorized based on the onset, duration, severity and the type of incontinence. [2]
  • Soiling of undergarments is a common symptom observed in individuals with fecal incontinence wherein stains of stool are observed on the undergarments.
  • Symptoms of fecal incontinence vary acoording to the type of incontinence such as the urge fecal incontinence and passive fecal incontinence.
  • Symptoms in individuals with urge fecal incontinence, the patient realizes the need to defecate but lacks control over it and may pass the stool even before reaching the restoom. [12] [13]
  • Symptoms in individuals with passive fecal incontinence, the patient doesn't realize nor does have control over the passage of stools and hence it happens without their knowledge.[13]

Physical Examination

  • Physical examination includes:
    • Inspection of the perianal area: To check for anocutaneous reflex (anal wink sign). Absence of this reflex indicates nerve damage.
    • Digital rectal examination: It is done to evaluate for anal pathology and assess anal resting tone.
  • Procedures that may help in determining the underlying cause of fecal incontinence such as:
    • Colonoscopy
    • Sigmoidoscopy
    • Anoscopy

Laboratory Findings

Stool testing may be helpful in determining the underlying cause of diarrhea.

Electrocardiogram

There are no ECG findings associated with fecal incontinence.

X-ray

There are no x-ray findings associated with fecal incontinence.

Ultrasound/MRI

  • Ultrasound or magnetic resonance imaging may be helpful in the diagnosis of fecal incontinence. An ultrasound or magnetic resonance imaging may be helpful in determining the underlying abnormalities of the pelvic floor muscles, structural abnormalities of the anal sphincter and abnormalities of the wall of the rectum.

Other Diagnostic Studies

  • Anorectal manometry may be helpful in the diagnosis of fecal incontinence. This procedure helps in determining the anal sphincter tone and also the sensation and reflexes of the rectum.
  • Balloon expulsion test may be more helpful in determining defecation disorders in the elderly patients who sufffer from fecal incontinence secondary to fecal impaction.

Treatment

Medical Therapy

  • Medical management of fecal incontinence involves medical therapy along with supportive measures that are focused at symptom control and also resolving the underlying conditions such as the stool consistency, rectal prolapse and other underlying associated medical conditions, if any.[2]
  • The first-line of management inn case of the affected patients would be the streamlining of conservative measures. Symptom control approach that includes dietary modification along with behavioral modification, usage of pads, skin care and pharmacotherapy. The patients in whom behavioral changes are suggested, should be made aware of the gastrocolic reflex.[2]
  • Dietary habits have to be assessed inorder to minimize the negative impacts of the food on stool consistency and volume.[2]
  • Inclusion of fiber rich foods or supplements may help in minimizing loose stools but, such foods should be used cautiously in patients with baseline formed stools, because the softer consistency and increased volume of the stools may result in the symptoms getting deteriorated.[2]
  • Medical therapy includes the use of drugs such as diphenoxylate/atropine, loperamide, cholestyramine, ondansetron, and/or amitriptyline. In order to reduce diarrhea and slightly increase the internal sphincter tone, diphenoxylate/atropine or loperamide are frequently used.[14] Amitriptyline may also be used as an alternative for treating diarrhea, and it may also be used to reduce rectal urgency.[15]
  • In order to reduce episodes of incontinence in patients with fecal impaction and overflow incontinence, enema is suggested to facilitate stool elimination and reduce the stool load. [16]
  • Supportive measures such as perianal skin care with barrier creams and restraining from over-the-counter topical creams without prescription.
  • Physical therapy and biofeedback may help strengthen pelvic floor and sphincter muscles as they serve as exercises thereby helping the muscles to recordinate. [17]

Surgery

Surgical intervention is not recommended for the management of [disease name].

OR

Surgery is not the first-line treatment option for patients with [disease name]. Surgery is usually reserved for patients with either [indication 1], [indication 2], and [indication 3]

OR

The mainstay of treatment for [disease name] is medical therapy. Surgery is usually reserved for patients with either [indication 1], [indication 2], and/or [indication 3].

OR

The feasibility of surgery depends on the stage of [malignancy] at diagnosis.

OR

Surgery is the mainstay of treatment for [disease or malignancy].

Primary Prevention

  • Effective measures for the primary prevention of Fecal incontinence include:
    • Avoid constipation by exercising regularly and maintaining healthy food habits by drinking plenty water and including foods rich in fiber in the diet
    • Avoiding straining or forceful defecation which may effect the anal sphincter and damage the related muscles and nerves which may lead to fecal incontinence.
    • Treating Diarrhea by managing the underlying cause such as the gastrointestinal infection.
    • In cases of fecal incontinence related to pregnancy, pelvic floor muscle training may help in prevention and reversal of the condition following the first year of delivery. [18] [19]
    • Elimination of interventions such as episiotomy, lateral sphincterotomy, and anal sphincter stretch in women may be helpful in preventing fecal incontinence. [20]


abcd

  • American Association for the Surgery of Trauma (AAST) Spleen Trauma Classification: [21]
American Association for the Surgery of Trauma (AAST) Spleen Trauma Classification
Grade Injury description
I Hematoma Subcapsular, < 10% surface area
Laceration Capsular tear, < 1 cm parenchymal depth
II Hematoma Subcapsular, 10–50% surface area
Intraparenchymal, < 5 cm diameter
Laceration 1–3 cm parenchymal depth not involving a perenchymal vessel
III Hematoma Subcapsular, > 50% surface area or expanding
Ruptured subcapsular or parenchymal hematoma
Intraparenchymal hematoma > 5 cm
Laceration > 3 cm parenchymal depth or involving trabecular vessels
IV Laceration Laceration of segmental or hilar vessels producing major devascularization (> 25% of spleen)
V Laceration Completely shatters spleen
Vascular Hilar vascular injury which devascularized spleen
  • WSES Spleen Trauma Classification for adult and pediatric patients:[21]

WSES Class Mechanism of injury AAST Hemodynamix Status (a), (b) CT scan First-line treatment in adults First-line treatment in pediatric
Minor WSES I Blunt/penetrating I - II Stable Yes + local exploration in SW (d) NOM (c) + serial clinical/laboratory/radiological evaluation

Consider angiography/angioembolization

NOM (c) + serial clinical/laboratory/radiological evaluation
Moderate WSES II Blunt/penetrating III Stable Consider angiography/angioembolization
WSES III Blunt/penetrating IV - V Stable NOM (c) All angiography/angioembolization + serial clinical/laboratory/radiological evaluation
Severe WSES IV Blunt/penetrating I - V Unstable No OM OM
SW - Stab wound; GSW - Gunshot wound; OM - Operative management; NOM - Non-Operative management


(a) Hemodynamic instability in adults is considered the condition in which the patient has an admission systolic blood pressure < 90 mmHg with evidence of skin vasoconstriction (cool, clammy, decreased capillary refill), altered level of consciousness and/or shortness of breath, or > 90 mmHg but requiring bolus infusions/transfusions and/or vasopressor drugs and/or admission base excess (BE) > − 5 mmol/l and/or shock index > 1 and/or transfusion requirement of at least 4–6 units of packed red blood cells within the first 24 h; moreover, transient responder patients (those showing an initial response to adequate fluid resuscitation, and then signs of ongoing loss and perfusion deficits) and more in general those responding to therapy but not amenable of sufficient stabilization to be undergone to interventional radiology treatments.

(b) Hemodynamic stability in pediatric patients is considered systolic blood pressure of 90 mmHg plus twice the child’s age in years (the lower limit is inferior to 70 mmHg plus twice the child’s age in years, or inferior to 50 mmHg in some studies). Stabilized or acceptable hemodynamic status is considered in children with a positive response to fluid resuscitation: 3 boluses of 20 mL/kg of crystalloid replacement should be administered before blood replacement; positive response can be indicated by the heart rate reduction, the sensorium clearing, the return of peripheral pulses and normal skin color, an increase in blood pressure and urinary output, and an increase in warmth of extremity. Clinical judgment is fundamental in evaluating children

(c) NOM should only be attempted in centers capable of a precise diagnosis of the severity of spleen injuries and capable of intensive management (close clinical observation and hemodynamic monitoring in a high dependency/intensive care environment, including serial clinical examination and laboratory assay, with immediate access to diagnostics, interventional radiology, and surgery and immediately available access to blood and blood products or alternatively in the presence of a rapid centralization system in those patients amenable to be transferred

(d) Wound exploration near the inferior costal margin should be avoided if not strictly necessary because of the high risk to damage the intercostal vessels.


  • Non-operative management: [21]
Non-operative management
Adults Pediatrics
General indications
  • NOM is recommended as first-line treatment for hemodynamically stable pediatric patients with blunt splenic trauma (GoR 2A).
  • Patients with moderate-severe blunt and all penetrating splenic injuries should be considered for transfer to dedicated pediatric trauma centers after hemodynamic stabilization (GoR2A).
  • NOM of spleen injuries in children should be considered only in an environment that provides capability for patient continuous monitoring, angiography, and trained surgeons, an immediately available OR and immediate access to blood and blood products or alternatively in the presence of a rapid centralization system in those patients amenable to be transferred (GoR 2A).
  • NOM should be attempted even in the setting of concomitant head trauma; unless the patient is unstable, this might be due to intra-abdominal bleeding (GoR 2B).
Blunt/penetrating trauma
  • Patients with hemodynamic stability and absence of other abdominal organ injuries requiring surgery should undergo an initial attempt of NOM irrespective of injury grade (GoR 2A).
 Blunt trauma
  • Blunt splenic injuries with hemodynamic stability and absence of other internal injuries requiring surgery, should undergo an initial attempt of NOM irrespective of injury grade (GoR 2A).
  • NOM of moderate or severe spleen injuries should be considered only in an environment that provides capability for patient intensive monitoring, AG/AE, an immediately available OR and immediate access to blood and blood product or alternatively in the presence of a rapid centralization system and only in patients with stable or stabilized hemodynamic and absence of other internal injuries requiring surgery (GoR 2A).
  • In hemodynamically stable children with isolated splenic injury splenectomy should be avoided (GoR 1A).
  • NOM in splenic injuries is contraindicated in the setting of unresponsive hemodynamic instability or other indicates for laparotomy (peritonitis, hollow organ injuries, bowel evisceration, impalement) (GoR 1A).
  • NOM is contraindicated in presence of peritonitis, bowel evisceration, impalement or other indications to laparotomy (GoR 2A).
  • In patients being considered for NOM, CT scan with intravenous contrast should be performed to define the anatomic spleen injury and identify associated injuries (GoR 2A).
  • The presence of contrast blush at CT scan is not an absolute indication for splenectomy or AG/AE in children (GoR 2B).
  • AG/AE may be considered the first-line intervention in patients with hemodynamic stability and arterial blush on CT scan irrespective from injury grade (GoR 2B).
  • Intensive care unit admission in isolated splenic injury may be required only for moderate and severe lesions (GoR 2B).
  • Strong evidence exists that age above 55 years old, high ISS, and moderate to severe splenic injuries are prognostic factors for NOM failure. These patients require more intensive monitoring and higher index of suspicion (GoR 2B).
  • Age above 55 years old alone, large hemoperitoneum alone, hypotension before resuscitation, GCS < 12 and low-hematocrit level at the admission, associated abdominal injuries, blush at CT scan, anticoagulation drugs, HIV disease, drug addiction, cirrhosis, and need for blood transfusions should be taken into account, but they are not absolute contraindications for NOM (GoR 2B).
  • In WSES class II–III spleen injuries with associated severe traumatic brain injury, NOM could be considered only if rescue therapy (OR and/or AG/AE) is rapidly available; otherwise, splenectomy should be performed (GoR 1C).
Penetrating trauma
  • No sufficient data validating NOM for penetrating spleen injury in children exist.
The role of angiography/angioembolization (AG/AE)
  • AG/AE may be performed in hemodynamically stable and rapid responder patients with moderate and severe lesions and in those with vascular injuries at CT scan (contrast blush, pseudo-aneurysms and arterio-venous fistula) (GoR 2A).
  • The vast majority of pediatric patients do not require AG/AE for CT blush or moderate to severe injuries (GoR 1C).
  • In patients with bleeding vascular injuries and in those with intraperitoneal blush, AG/AE should be performed as part of NOM only in centers where AG/AE is rapidly available. In other centers and in case of rapid hemodynamic deterioration, OM should be considered (GoR 2B).
  • AG/AE may be considered in patients undergone to NOM, hemodynamically stable with sings of persistent hemorrhage not amenable of NOM, regardless with the presence of CT blush once excluded extra-splenic source of bleeding (GoR 1C).
  • In case of absence of blush during angiography, if blush was previously seen at CT scan, proximal angioembolization could be considered (GoR 2C).
  • AG/AE may be considered for the treatment of post-traumatic splenic pseudo-aneurysms prior to patient discharge (GoR 2C).
  • AG/AE should be considered in all hemodynamically stable patients with WSES grade III lesions, regardless with the presence of CT blush (GoR 1B).
  • Patients with more than 15 years old should be managed according to adults AG/AE-protocols (GoR 1C).
  • AG/AE could be considered in patients undergone to NOM, hemodynamically stable with sings of persistent hemorrhage regardless with the presence of CT blush once excluded extra-splenic source of bleeding (GoR 1C).
  • Hemodynamically stable patients with WSES grade II lesions without blush should not underwent routine AG/AE but may be considered for prophylactic proximal embolization in presence of risk factors for NOM failure (GoR 2B).
  • In the presence of a single vascular abnormality (contrast blush, pseudo-aneurysms, and artero-venous fistula) in minor and moderate injuries, the currently available literature is inconclusive regarding whether proximal or distal embolization should be used. In the presence of multiple splenic vascular abnormalities or in the presence of a severe lesion, proximal or combined AG/AE should be used, after confirming the presence of a permissive pancreatic vascular anatomy (GoR 1C).
  • In performing, AG/AE coils should be preferred to temporary agents (GoR 1C).


  • Operative management: [21]
Operative management (OM)
Adults Pediatrics
  • OM should be performed in patients with hemodynamic instability and/or with associated lesions like peritonitis or bowel evisceration or impalement requiring surgical exploration (GoR 2A).
  • Patients should undergo to OM in case of hemodynamic instability, failure of conservative treatments, severe coexisting injuries necessitating intervention and peritonitis, bowel evisceration, impalement (GoR 2A).
  • OM should be performed in moderate and severe lesions even in stable patients in centers where intensive monitoring cannot be performed and/or when AG/AE is not rapidly available (GoR 2A).
  • Splenic preservation (at least partial) should be attempted whenever possible (GoR 2B).
  • Splenectomy should be performed when NOM with AG/AE failed, and patient remains hemodynamically unstable or shows a significant drop in hematocrit levels or continuous transfusion are required (GoR 2A).
  • During OM, salvage of at least a part of the spleen is debated and could not be suggested (GoR 2B).
  • Laparoscopic splenectomy in early trauma scenario in bleeding patients could not be recommended (GoR 2A).

Follow-up

Short- and long-term follow-up: [21]

Short- and long-term follow-up
Adults Pediatrics
  • Clinical and laboratory observation associated to bed rest in moderate and severe lesions is the cornerstone in the first 48–72 h follow-up (GoR 1C).
  • In hemodynamic stable children without drop in hemoglobin levels for 24 h, bed rest should be suggested (GoR 2B).
  • CT scan repetition during the admission should be considered in patients with moderate and severe lesions or in decreasing hematocrit, in presence of vascular anomalies or underlying splenic pathology or coagulopathy, and in neurologically impaired patients (GoR 2A).
  • The risk of pseudo-aneurysm after splenic trauma is low, and in most of cases, it resolves spontaneously (GoR 2B).
  • In the presence of underlying splenic pathology or coagulopathy and in neurologically impaired patients CT follow-up is to be considered after the discharge (GoR 2B).
  • Angioembolization should be taken into consideration when a pesudoaneurysm is found (GoR 2B).
  • Activity restriction may be suggested for 4–6 weeks in minor injuries and up to 2–4 months in moderate and severe injuries (GoR 2C).
  • US (DUS, CEUS) follow-up seems reasonable to minimize the risk of life-threatening hemorrhage and associated complications in children (GoR 1B).
  • After NOM in moderate and severe injuries, the reprise of normal activity could be considered safe after at least 6 weeks (GoR 2B).


  • Diagnostic procedures: [21]
Diagnostic procedures
Adults Pediatrics
  • The choice of diagnostic technique at admission must be based on the hemodynamic status of the patient (GoR 1A).
  • The role of E-FAST in the diagnosis of pediatric spleen injury is still unclear (GoR 1A).
  • E-FAST is effective and rapid to detect free fluid (GoR 1A).
  • A positive E-FAST examination in children should be followed by an urgent CT in stable patients (GoR 1B).
  • CT scan with intravenous contrast is the gold standard in hemodynamically stable or stabilized trauma patients (GoR 1A).
  • Complete abdominal US may avoid the use of CT in stable patients (GoR 1B).
  • Doppler US and contrast-enhanced US are useful to evaluate splenic vascularization and in follow-up (GoR 1B)
  • Contrast-enhanced CT scan is the gold standard in pediatric splenic trauma (GoR 1A).
  • Injury grade on CT scan, extent of free fluid, and the presence of PSA do not predict NOM failure or the need of OM (GoR 1B)
  • Doppler US and contrast-enhanced US are useful to evaluate splenic vascularization (GoR 1B).
  • CT scan is suggested in children at risk for head and thoracic injuries, need for surgery, recurrent bleeding, and if other abdominal injuries are suspected (GoR 1A).
  • Injury grade on CT scan, free fluid amount, contrast blush, and the presence of pseudo-aneurysm do not predict NOM failure or the need for OM (GoR 1B).




Staging and TNM Classification related to Incidence, Treatment, and Prognosis
Stage TNM Classification Clinical Classification Incidence at diagnosis (%) 5-year survival rate (%)
0 Tis, N0, M0 Resectable 7.5 15.2
IA T1, N0, M0
IB T2, N0, M0
IIA T3, N0, M0
IIB T1-3, N1, M0 Locally advanced 29.3 6.3
III T4, any N, M0
IV Any T, any N, M1 Metastatic 47.2 1.6

1[22]



  • Stage grouping of pancreatic cancer:[22]
Stage grouping of pancreatic cancer:
Primary tumor
Stage T N M
0 Tis N0 M0
IA T1 N0 M0
IB T2 N0 M0
IIA T3 N0 M0
IIB T1 N1 M0
T2 N1 M0
T3 N1 M0
III T4 Any N M0
IV Any T Any N M1

[22]



  • TNM classification for pancreatic cancer:[23] [22]
TNM Classification for Pancreatic Cancer:
Primary tumor
TX Primary tumor cannot be assessed
T0 No evidence of primary tumor
Tis Carcinoma in situ
T1 Tumor limited to the pancreas, ≤2 cm in greatest dimension
T2 Tumor limited to the pancreas, >2 cm in greatest dimension
T3 Tumor extends beyond the pancreas but without involvement of the celiac axis or the superior mesenteric artery
T4 Tumor involves the celiac axis or the superior mesenteric artery (unresectable primary tumor)
Regional lymph nodes
NX Regional lymph nodes cannot be assessed
N0 No regional lymph node metastasis
N1 Regional lymph node metastasis
Distant metastases
MX Distant metastasis cannot be assessed
M0 No distant metastasis
M1 Distant metastasis


  • Types of Pancreatic Intraepithelial Neoplasia (PanIN):[23]
Types of Pancreatic Intraepithelial Neoplasia (PanIN)
PanIN 1 (low grade)
  • Minimal degree of atypia
  • Subclassified into PanIN 1A: absence of micropapillary infoldings of the epithelium; and 1B, presence of micropapillary infoldings of the epithelium
PanIN 2 (intermediate grade)
  • Moderate degree of atypia, including loss of polarity, nuclear crowding, enlarged nuclei, pseudostratification, and hyperchromatism
  • Mitoses are rarely seen
PanIN 3 (high grade/carcinoma in situ)
  • Severe atypia, with varying degrees of cribriforming, luminal necrosis, and atypical mitoses
  • Contained within the basement membrane


  • Risk factors for Pancreatic Cancers:[23]
Risk factors for Pancreatic Cancer
Risk factors
  • Smoking
  • Alcohol
  • Increased BMI
  • Diabetes mellitus
  • Chronic pancreatitis
  • Family history of pancreatic cancer
Familial Cancer Syndromes
  • BRCA1, BRCA2
  • Familial adenomatous polyposis (FAP)
  • Peutz-Jeghers syndrome
  • Familial atypical multiple mole melanoma syndrome (FAMMM)
  • Lynch syndrome
  • von Hippel-Lindau syndrome
  • Multiple endocrine neoplasia type 1
  • Gardner syndrome
Other medical conditions
  • Inflammatory bowel disease
  • Periodontal disease
  • Peptic ulcer disease


  • Risk Factors and Inherited Syndromes associated with Pancreatic Cancer:[24]
Risk Factors and Inherited Syndromes associated with Pancreatic Cancer
Risk Factor Approximate Risk
Smoking 2-3 %
Long-standing Diabetes mellitus 2 %
Nonhereditery and Chronic Pancreatitis 2-6 %
Obesity, Inactivity or both 2 %
Non O Blood Group 1-2 %
Genetic SYndrome and Associated Gene or Genes
Hereditary pancreatitis (PRSS1, SPINK1) 50 %
Familial atypical multiple mole and melanoma syndrome (p16) 10-20 %
Hereditary breast and ovarian cancer syndromes (BRCA1, BRCA2, PALB2) 1-2 %
Peutz-Jeghers syndrome (STK11 [LKB1]) 30-40 %
Hereditary nonpolyposis colon cancer (Lynch syndrome) (MLH1, MSH2, MSH6) 4 %
Ataxia-telangiectasia (ATM) Unknown
Li-Fraumeni syndrome (P53) Unknown


Aravind
Reddy Reddy Reddy Reddy




Functional Pancreatic Neuroendocrine Tumors and their Characteristics
Tumor type and syndrome Location in pancreas Signs and symptoms Circulating biomarkers
Insulinoma (Whipple’s triad)
  • Head, body, tail (evenly distributed)
  • Hypoglycemia, dizziness, sweating, tachycardia, tremulousness, confusion, seizure
  • CgA and CgB, insulin inappropriate for blood glucose level, proinsulin, C-peptide
Gastrinoma (Zollinger–Ellison)
  • Gastrinoma triangle Often extrapancreatic (duodenal); can be found anywhere in gland
  • Gastric acid hypersecretion, peptic ulcer, diarrhea, esophagitis, epigastric pain
  • CgA, gastrin, PP (35%)
VIPoma (Verner– Morrison syndrome, WDHA)
  • Distal pancreas (body and tail) Often spread outside pancreas
  • Watery diarrhea, hypokalemia, achlorhydria (or acidosis)
  • CgA, VIP
Glucagonoma
  • Body and tail of pancreas Often large and spread outside pancreas
  • Diabetes (hyperglycemia), necrolytic migratory erythema, stomatitis, glossitis, angular cheilitis
  • CgA, glucagon, glycentin
Somatostatinoma
  • Pancreatoduodenal groove, ampullary, periampullary
  • Gallstones, diabetes (hyperglycemia), steatorrhea
  • CgA, somatostatin
Ppoma
  • Head of pancreas
  • None
  • CgA, PP
Gastritis staging in clinical practice: The OLGA staging system
Atrophy Score Corpus
No Atrophy (Score: 0) Mild Atrophy (Score: 1) Moderate Atrophy (Score: 2) Severe Atrophy (Score: 3)

A

N

T

R

U

M

No Atrophy (Score: 0) (including incisura angularis) STAGE 0 STAGE I STAGE II STAGE II
Mild Atrophy (Score: 1) (including incisura angularis) STAGE I STAGE I STAGE II STAGE III
Moderate Atrophy (Score: 2) (including incisura angularis) STAGE II STAGE II STAGE III STAGE IV
Severe Atrophy (Score: 3) (including incisura angularis) STAGE III STAGE III STAGE IV STAGE IV

Sydney system for grading of chronic gastritis

Sydney system for grading of chronic gastritis
Feature Definition Grading guidelines
Chronic inflammation
  • Mild, moderate or severe increase in density
Activity
  • Mild: less than one-third of pits and surface infiltrated
  • Moderate: one-third to two-thirds
  • Severe: more than two-thirds
Atrophy
  • Loss of specialized glands from either antrum or corpus
  • Mild, moderate, or severe loss
Helicobacter pylori
  • Mild colonization: scattered organisms covering less than one-third of the surface
  • Moderate colonization: intermediate numbers
  • Severe colonization: large clusters or a continuous layer over two-thirds of surface
Intestinal Metaplasia
  • Mild: less than one-third of mucosa involved
  • Moderate: one-third to two-thirds
  • Severe: more than two-thirds
Feature Non-atrophic

Helicobacter

Atrophic Helicobacter Autoimmune
Inflammation pattern Antral or diffuse Antrum & corpus, mild inflammation Corpus only
Atrophy & metaplasia Nil Atrophy present, metaplasia at incisura Corpus only
Antral predominant gastritis Corpus predominant gastritis
More predominant in antrum in developed countries Less predominant in developed countries
High acid output Low acid output
Associated with duodenal ulceration

Classification Gastritis

Classification and grading of Gastritis: Updated Sydney System
Type of Gastritis Etiology Gastritis synonyms
Non-atrophic
  • Helicobacter pylori
  • Other factors
  • Superficial
  • Diffuse antral gastritis (DAG)
  • Chronic antral gastritis (CAG)
  • Interstitial - follicular
  • Hypersecretory
  • Type B*
Atrophic Autoimmune
  • Autoimmunity
  • Type A*
  • Diffuse corporal
  • Pernicious anemia-associated
Multifocal atrophic
  • Helicobacter pylori
  • Type B*, type AB*
  • Dietary
  • Environmental
  • Environmental factors
  • Metaplastic
Special forms Chemical
  • Chemical irritation
  • Reactive
  • Bile
  • Reflux
  • NSAIDs
  • NSAID
  • Other agents
  • Type C
Radiation
  • Radiation injury
Lymphocytic
  • Idiopathic? Immune mechanisms
  • Varioliform (endoscopic)
  • Gluten
  • Celiac disease-associated
  • Drug (ticlopidine)
  • H. pylori
Noninfectious granulomatous
  • Crohn's disease
  • Sarcoidosis
  • Granulomatosis with polyangiitis and other vasculitides
  • Foreign substances
  • Idiopathic
  • Isolated granulomatous
Eosinophilic
  • Food sensitivity
  • Allergic
  • Other allergies
Other infectious gastritides
  • Bacteria (other than H. pylori)
  • Phlegmonous
  • Viruses
  • Fungi
  • Parasites
Classification and grading of gastritis: Updated Sydney System
Type of gastritis Etiologic factors Gastritis synonyms
Nonatrophic
  • Helicobacter pylori
  • Other factors
  • Superficial
  • Diffuse antral gastritis (DAG)
  • Chronic antral gastritis (CAG)
  • Interstitial - follicular
  • Hypersecretory
  • Type B*
Aravind
Reddy Reddy Reddy Reddy




The table below differentiates Gastritis from other conditions

Differential Diagnosis
Disease Cause Symptoms Diagnosis Other findings
Pain Nausea & Vomiting Heartburn Belching or Bloating Weight loss Loss of Appetite Stools Endoscopy findings
Location Aggravating Factors Alleviating Factors
Acute gastritis Food Antacids - Black stools -
Chronic gastritis Food Antacids - H. pylori gastritis

Lymphocytic gastritis

  • Enlarged folds
  • Aphthoid erosions
 -
Atrophic gastritis Epigastric pain - - - - H. pylori

Autoimmune

Crohn's disease - - - - -
  • Mucosal nodularity with cobblestoning
  • Multiple aphthous ulcers
  • Linier or serpiginous ulcerations
  • Thickened antral folds
  • Antral narrowing
  • Hypoperistalsis
  • Duodenal strictures
GERD
  • Spicy food
  • Tight fitting clothing

(Suspect delayed gastric emptying)

- - - - Other symptoms:

Complications

Peptic ulcer disease

Duodenal ulcer

  • Pain aggravates with empty stomach

Gastric ulcer

  • Pain aggravates with food
  • Pain alleviates with food
 - - - Gastric ulcers
  • Discrete mucosal lesions with a punched-out smooth ulcer base with whitish fibrinoid base
  • Most ulcers are at the junction of fundus and antrum
  • 0.5-2.5cm

Duodenal ulcers

Other diagnostic tests
Gastrinoma - -

(suspect gastric outlet obstruction)

- - - Useful in collecting the tissue for biopsy

Diagnostic tests

Gastric Adenocarcinoma - - Esophagogastroduodenoscopy
  • Multiple biopsies are taken to establish the diagnosis
 Other symptoms
Primary gastric lymphoma - - - - - - - Useful in collecting the tissue for biopsy Other symptoms




Aravind
Reddy Reddy Reddy Reddy
Aravind
Reddy Reddy Reddy Reddy
Chronology of Yersinia pestis infection Outbreaks("WHO | Plague".)
Date Region Affected Suspected, Probable & Confirmed Cases Deaths Details
15 October 2017 Seychelles - Suspected Plague (Ex- Madagascar) 1 0
  • On 10 October 2017, the Seychellois Ministry of Health notified WHO of a probable case of pneumonic plague
  • The probable case is a 34-year-old man who had visited Madagascar and returned to Seychelles on 6 October 2017. He developed symptoms on 9 October 2017 and presented to a local health centre(pneumonic plague infection suspected, isolated and treated)
  • 11 October, rapid diagnostic test (RDT) preformed, sputum sample was weakly positive.
  • October 9 to 11 2017, eight of his contacts developed mild symptoms and have been isolated
  • October 13 was the last day of monitoring of over 320 contact persons of the probable case
  • Contact tracing is done thoroughly and 577 children and 63 teachers in potential contact with one of the individual identified by contact tracing were given antibiotics.
2 October 2017 Madagascar 73 17
  • The outbreak started following the death of a 31-year-old male from Ankazobe District in the Central Highlands (Hauts-Plateaux), a plague-endemic area. Since then, the Ministry of Public Health of Madagascar enhanced field investigations, contact tracing, surveillance, and monitoring all close contacts
  • As of 30 September, 10 cities have reported pneumonic plague cases and the three most affected districts include: the capital city and suburbs of Antananarivo (27 cases, 7 deaths), Toamasina (18 cases, 5 deaths), and Faratshio (13 cases, 1 death)
  • In addition to the 73 cases of pneumonic plague, from 1 August to 30 September, 58 cases of bubonic plague including seven deaths have been reported. One additional case of septicaemic plague has also been reported, and one case where the type is not specified
29 September 2017 Madagascar 51 12
  • On 23 August 2017, a 31-year-old male from Tamatave, visiting Ankazobe District in central highlands, developed malaria-like symptoms. On 27 August, he developed respiratory symptoms during his journey in a shared public taxi from Ankazobe District to Tamatave (via Antananarivo). His condition worsened and he died.
  • In addition to the 51 suspected, probable and confirmed cases of pneumonic plague, and during the same period another 53 cases of bubonic plague including seven deaths have been reported throughout the country. One case of septicaemic plague has also been identified and they were not directly linked to the outbreak.
  • Additionally, 31 people who came into contact with this case either through direct contact with the primary case or had other epidemiological links, became ill, and four cases of them died
  • The outbreak was detected on 11 September, following the death of a 47-year-old woman from Antananarivo, who was admitted to a hospital with respiratory failure caused by pneumonic plague
9 January 2017 Madagascar 62 cases (6 confirmed, 5 probable, 51 suspected) 26 (case fatality rate of 42%)
  • Of the 11 samples tested, 5 were positive for plague on rapid diagnostic test and 6 are now confirmed at Institut Pasteur laboratory. Of the total reported cases, 5 are classified as pneumonic plague cases and the remaining as bubonic plague
  • Retrospective investigations carried out in those two districts showed that it is possible that the outbreak might have started in mid-August 2016. The investigation in neighbouring villages is still ongoing. On 29 December, an investigation carried out within 25 km of the initial foci in Befotaka district has reported three deaths and is being investigated further for possible linkage to the outbreak
6 September 2015 Madagascar 14 10
  • The Ministry of Health of Madagascar has notified WHO of an outbreak of plague. The first case was identified on 17 August in a rural township in Moramanga district. The case passed away on 19 August
  • All confirmed cases are of the pneumonic form. Since 27 August, no new cases have been reported from the affected or neighbouring districts
21 November 2014 Madagascar 119 40
  • On 4 November 2014, WHO was notified by the Ministry of Health of Madagascar of an outbreak of plague. The first case, a male from Soamahatamana village in the district of Tsiroanomandidy, was identified on 31 August. The patient died on 3 September
  • Only 2% of reported cases are of the pneumonic form
  • Cases have been reported in 16 districts of seven regions. Antananarivo, the capital and largest city in Madagascar, has also been affected with 2 recorded cases of plague, including 1 death. There is now a risk of a rapid spread of the disease due to the city’s high population density and the weakness of the healthcare system. The situation is further complicated by the high level of resistance to deltamethrin (an insecticide used to control fleas) that has been observed in the country
10 August 2010 Peru 17 -
  • As of 30 July 2010, the Ministry of Health in Peru confirmed a total of 17 cases of plague in Ascope province of Department La Libertad. Of these, four are pneumonic plague, 12 are bubonic plague and one was septicemic plague. The onset of symptoms for the last reported case of pneumonic plague was on 11 July 2010. During the investigations, 10 strains of Y. pestis were isolated from humans, rodents and domestic cats
11 August 2009 China 12 3
  • On 1 August 2009, a cluster outbreak of pulmonary plague cases in the remote town of Ziketan, Qinghai province was reported by the Ministry of Health (MoH), China.
  • On 26th July 2009, the first case was a 32 year old male herdsman, who developed fever and hemoptysis was reported. He died enroute to hospital.
  • On 30 July, 11 people who had close contact with the case (mainly relatives who attended the funeral) were all hospitalized as they developed fever and cough. They were all tested positive for plague.
  • On 2 August 2009, 2 people who helped to bury the corpse, 64 year old father-in-law of the first case and a 37 year old male neighbour of the first case also died.
  • On August 6 2009, the local health authority isolated 332 close contacts for further medical observation, and implemented traffic control around affected area. Preventive measures were taken to stop teh spread.
  • Epidemiological investigation showed that the source of this outbreak was a wild marmot, which had contact with the dog of the index case.
7 November 2006 Democratic Republic of the Congo 1174 50
  • As of 29 September 2006, WHO received reports of a suspected pneumonic plague outbreak in 4 health zones in Haut-Uele district, Oriental province in the north-eastern part of the country.
  • More than 50 samples have been collected and analysed; however, the diagnosis of plague has not been finally laboratory confirmed.
13 October 2006 Democratic Republic of the Congo 626 42
  • WHO has received reports of a suspected pneumonic plague outbreak in 2 health zones in Haut-Uele district, the majority reported from Wamba health zone in Oriental province in the northern part of the country
  • However, the low case fatality ratio is unusual for pneumonic plague which suggests that the number of suspected cases may be an overestimation
  • Preliminary results from a rapid diagnosis test in the field found three samples positive, out of eight
14 June 2006 Democratic Republic of the Congo 100 19
  • Suspected cases of bubonic plague have also been reported but the total number is not known at this time. Preliminary results from rapid diagnostic tests in the area confirm pneumonic plague.
  • Ituri is known to be the most active focus of human plague worldwide, reporting around 1000 cases a year. The first cases in this outbreak occurred in a rural area, in the Zone de Santé of Linga, in mid-May
15 March 2005 Plague in the Democratic Republic of the Congo - update 4 130 57
  • Reported in Zobia, Bas-Uélé district, Oriental province
  • No cases of bubonic plague have been detected
9 March 2005 Plague in the Democratic Republic of the Congo - update 3 114 cases (110 suspect cases, 4 probable cases) 54
  • Reported in Zobia, Bas-Uélé district, Oriental province
4 March 2005 Plague in the Democratic Republic of the Congo - update 2 57 cases (54 suspect cases, 3 probable cases) 16
  • Reported in Zobia, Bas-Uélé district, Oriental province
1 March 2005 Plague in the Democratic Republic of the Congo - update 4 probable cases and 4 suspect cases 1
  • Reported in Zobia, Bas-Uélé district, Oriental province
18 February 2005 Plague in the Democratic Republic of the Congo - 61
  • Reported in Bas-Uele district, Oriental province
  • Preliminary results from rapid diagnostic tests in the area confirm pneumonic plague, and the cases had clinical features compatible with this disease
  • Cases have occurred in workers in a diamond mine in Zobia where c. 7000 people work. The mine was re-opened on 16 December 2004 and the first case occurred on 20 December
10 July 2003 Plague in Algeria - Update 2 10 laboratory confirmed cases and 1 probable case -
  • Reported in oran district
3 July 2003 Plague in Algeria - Update 10 cases of which 8 have been laboratory confirmed -
  • Reported by Ministry of Health, Algeria
  • 8 cases of bubonic plague and 2 of septicemic plague, of which one was fatal
24 June 2003 Plague in Algeria 10 cases, 8 cases of bubonic plague and 2 of septicemic plague one fatal case reported
  • Reported by the Ministry of Health, Algeria in Tafraoui, on the outskirts of Oran
5 June 2002 2002 - Plague in Malawi 71 -
  • Reported by the Malawian Ministry of Health
  • 71 cases of bubonic plague in the district of Nsanje since the onset of the outbreak on 16 April 2002
  • Outbreak has so far affected 26 villages, 23 in the Ndamera area, 2 in Chimombo and 1 village in neighbouring Mozambique
20 February 2002 2002 - Plague in India 16 cases of pneumonic plague 4 deaths in Hat Koti village
  • Reported by the Ministry of Health, India
26 March 2001 2001 - Plague in Zambia 23 hospitalized cases 3 deaths in Petauke district, Eastern Province
  • The last case reported was 15 March 2001
Chronology of Marburg Hemorrhagic Fever Outbreaks ("Marburg Hemorrhagic Fever". Center for Disease Control and Prevention. Center for Disease Control and Prevention (CDC).)
Years Country Apparent or suspected origin Reported number of human cases Reported number (%) of deaths among cases Situation
2014 Uganda Uganda 1 1 (100%) Ninety-nine individuals were quarantined after a 30-year-old male health-worker died of Marburg hemorrhagic fever on the 28th of September.
2012 Uganda Kabale 15 4 (27%) Testing at CDC/UVRI identified a Marburg virus disease outbreak in the districts of Kabale, Ibanda, Mbarara, and Kampala over a 3 week time period[25]
2008 Netherlands ex Uganda Cave in Maramagambo forest in Uganda, at the southern edge of Queen Elizabeth National Park 1 1 (100%) A 40-year-old Dutch woman with a recent history of travel to Uganda was admitted to hospital in the Netherlands. Three days prior to hospitalization, the first symptoms (fever, chills) occurred, followed by rapid clinical deterioration. The woman died on the 10th day of the illness.
2007 Uganda Lead and gold mine in Kamwenge District, Uganda 4 1 (25%) Small outbreak, with 4 cases in young males working in a mine. To date, there have been no additional cases identified[26]
2004-2005 Angola Uige Province, Angola 252 227 (90%) Outbreak believed to have begun in Uige Province in October 2004. Most cases detected in other provinces have been linked directly to the outbreak in Uige[27]
1998-2000 Democratic Republic of Congo (DRC) Durba, DRC 154 128 (83%) Most cases occurred in young male workers at a gold mine in Durba, in the north-eastern part of the country, which proved to be the epicenter of the outbreak. Cases were subsequently detected in the neighboring village of Watsa.[26]
1990 Russia Russia 1 1 (100%) Laboratory contamination.[26]
1987 Kenya Kenya 1 1 (100%) A 15-year-old Danish boy was hospitalized with a 3-day history of headache, malaise, fever, and vomiting. Nine days prior to symptom onset, he had visited Kitum Cave in Mount Elgon National Park. Despite aggressive supportive therapy, the patient died on the 11th day of illness. No further cases were detected[28]
1980 Kenya Kenya 2 1 (50%) A man with a recent travel history to Kitum Cave in Kenya's Mount Elgon National Park. Despite specialized care in Nairobi, the male patient died. A doctor who attempted resuscitation developed symptoms 9 days later but recovered[29]
1975 Johannesburg, South Africa Zimbabwe 3 1 (33%) A man with a recent travel history to Zimbabwe was admitted to hospital in South Africa. Infection spread from the man to his traveling companion and a nurse at the hospital. The man died, but both women were given vigorous supportive treatment and eventually recovered.[30]
1967 Germany and Yugoslavia Uganda 31 7 (23%) Simultaneous outbreaks occurred in laboratory workers handling African green monkeys imported from Uganda. In addition to the 31 reported cases, an additional primary case was retrospectively diagnosed by serology. [31]
Marburg hemorrhagic fever: Symptoms and Disease Progression
Generalisation Phase (Day 1 to Day 5)
  • Fever
  • Headache
  • Chills
  • Myalgia
  • Malaise
  • Fatigue
  • Nausea
  • Vomiting
  • Diarrhoea
  • Abdominal Pain
  • Conjunctivitis
  • Rash
  • Pharyngitis
Early Organ Phase (Day 6 to Day 13)
  • Fever
  • Bloody Diarrhoea(Malena)
  • Hematemesis
  • Exanthema
  • Petechiae?Ecchymoses
  • Muscosal hemorrhage
  • Visceral hemorrhage
  • Dyspnea
  • Conjunctival injection
  • Edema
  • Apathy/Depression
  • Irritability/aggression
Late Organ or Convalescence Phase (Day 14 to Day 21)
  • Fever
  • Obtundation
  • Dementia
  • Coma
  • Convulsions
  • Diffuse coagulopathy
  • Metabolic disturbances
  • Shock
  • Myalgia
  • Arthralgia
  • Hepatitis
  • Asthenia
  • Ocular disease
  • Psychosis
  • Social separation

Disease Gene Chromosome Differentiating Features Components of MEN Diagnosis
Parathyroid Pitutary Pancreas
von Hippel-Lindau syndrome Von Hippel–Lindau tumor suppressor 3p25.3
  • Angiomatosis, 
  • Hemangioblastomas,
  • Pheochromocytoma, 
  • Renal cell carcinoma,
  • Pancreatic cysts (pancreatic serous cystadenoma)
  • Endolymphatic sac tumor,
  • Bilateral papillary cystadenomas of the epididymis (men) or broad ligament of the uterus (women)
 - - +
  • Clinical diagnosis
  • In hereditary VHL, disease techniques such as Southern blotting and gene sequencing can be used to analyse DNA and identify mutations.
Carney complex  PRKAR1A 17q23-q24
  • Myxomas of the heart
  • Hyperpigmentation of the skin (lentiginosis)
  • Endocrine (ACTH-independent Cushing's syndrome due to primary pigmented nodular adrenocortical disease)
 - - -
  • Clinical diagnosis
Neurofibromatosis type 1 RAS 17 - - - Prenatal
  • Chorionic villus sampling or amniocentesis can be used to detect NF-1 in the fetus.

Postnatal Cardinal Clinical Features" are required for positive diagnosis.

  • Six or more café-au-lait spots over 5 mm in greatest diameter in pre-pubertal individuals and over 15 mm in greatest diameter in post-pubertal individuals.
  • Two or more neurofibromas of any type or 1 plexiform neurofibroma
  • Freckling in the axillary (Crowe sign) or inguinal regions
  • Optic glioma
  • Two or more Lisch nodules (pigmented iris hamartomas)
  • A distinctive osseous lesion such as sphenoid dysplasia, or thinning of the long bone cortex with or without pseudarthrosis.
Li-Fraumeni syndrome TP53 17 Early onset of diverse amount of cancers such as - - -

Criteria

  • Sarcoma at a young age (below 45)
  • A first-degree relative diagnosed with any cancer at a young age (below 45)
  • A first or second degree relative with any cancer diagnosed before age 60.
Gardner's syndrome APC  5q21
  • Multiple polyps in the colon 
  • Osteomas of the skull
  • Thyroid cancer,
  • Epidermoid cysts,
  • Fibromas
  • Desmoid tumors
 - - -
  • Clinical diagnosis
  • Colonoscopy
Multiple endocrine neoplasia type 2 RET - + - -

Criteria Two or more specific endocrine tumors

Cowden syndrome PTEN -  Hamartomas - - -
  • PTEN mutation probability risk calculator
Acromegaly/gigantism - - - + -
Pituitary adenoma - - - + -
Hyperparathyroidism - - - + - -
  • An elevated concentration of serum calcium with elevated parathyroid hormone level is diagnostic of primary hyperparathyroidism.
  • Most consistent laboratory findings associated with the diagnosis of secondary hyperparathyroidism include elevated serum parathyroid hormone level and low to normal serum calcium.
  • An elevated concentration of serum calcium with elevated parathyroid hormone level in post renal transplant patients is diagnostic of tertiary hyperparathyoidism.
Pheochromocytoma/paraganglioma

VHL RET NF1   SDHB  SDHD

- Characterized by - - -
  • Increased catecholamines and metanephrines in plasma (blood) or through a 24-hour urine collection.
Adrenocortical carcinoma
  • p53
  • Retinoblastoma h19
  • Insulin-like growth factor II (IGF-II)
  • p57kip2
 17p, 13q  - - -
  • Increased serum glucose
  • Increased urine cortisol
  • Serum androstenedione and dehydroepiandrosterone
  • Low serum potassium
  • Low plasma renin activity
  • High serum aldosterone.
  • Excess serum estrogen.
Adapted from Toledo SP, Lourenço DM, Toledo RA. A differential diagnosis of inherited endocrine tumors and their tumor counterparts, journal=Clinics (Sao Paulo), volume= 68, issue= 7, 07/24/2013[32]

Disease Definition
von Hippel-Lindau syndrome An autosomal dominant genetic disorder causing abnormal growth of blood vessels in different parts of the body.
Tuberous sclerosis A rare multi-system genetic disease that causes benign tumors to grow in the brain and on other vital organs such as the kidneys, heart, eyes, lungs, and skin.
Carney complex An autosomal dominant condition comprising myxomas of the heart and skin, hyperpigmentation of the skin (lentiginosis), and endocrine overactivity.
Neurofibromatosis type 1 An autosomal dominant tumor disorder of central nervous system due to germline mutations in neurofibromin manifesting as scoliosis (curvature of the spine), learning disabilities, vision disorders, cutaneous lesions and epilepsy.
Li-Fraumeni syndrome An autosomal dominant rare disorder due to germline mutations of the TP53 tumor suppressor gene characterized by early onset of diverse amount of cancers such as sarcoma, cancers of the breast, brain and adrenal glands.
Gardner's syndrome Familial colorectal polyposis is an autosomal dominant form of polyposis characterized by the presence of multiple polyps in the colon together with tumors outside the colon .
Multiple endocrine neoplasia type 2 An autosomal dominant disorder characterized by medullary thyroid carcinoma (MTC), pheochromocytoma and primary hyperparathyroidism.
Cowden syndrome A rare autosomal dominant disorder due to germline mutation of PTEN, a tumor suppressor gene characterized by multiple tumor-like growths called hamartomas.
Cushing's syndrome A disorder due to prolonged exposure to cortisol characterized by hypertension, abdominal obesity but with thin arms and legs, purple abdominal striae, moon facies, buffalo lump, weak muscles, weak bones, acne, and fragile skin that heals poorly.
Acromegaly/gigantism A rare syndrome due to excess growth hormone characterized by enlargement of the hands, feet, nose, lips and ears, and a general thickening of the skin, hypertrichosis, hyperpigmentation and hyperhidrosis and carpal tunnel syndrome.
Hyperaldosteronism A disorder due to excess production of the aldosterone by the adrenal glands characterized by hypertension, muscular weakness, muscle spasms, tingling sensations and excessive urination.
Pituitary adenoma A tumor in pituitary gland characterized by visual field defects, classically bitemporal hemianopsia, increased intracranial pressure, migraine and lateral rectus palsy.
Hyperparathyroidism A disorder due to excess production of parathyroid hormone characterized by kidney stones, hypercalcemia, constipation, peptic ulcers and depression.
Thyroid carcinoma A tumor of the thyroid gland characterized by signs and symptoms of hyperthryroidism or hypothyroidism.
Pheochromocytoma/paraganglioma A neuroendocrine tumor of the medulla of the adrenal glands characterized by episodic hypertension, palpitations, anxiety, diaphoresis and weight loss.
Adrenocortical carcinoma An aggressive cancer originating in the cortex of the adrenal gland that may either by non-secretory (asymptomatic) or secretory with signs and symptoms of Cushing syndrome (cortisol hypersecretion), Conn syndrome (aldosterone hypersecretion), virilization (testosterone hypersecretion)
Adapted from Toledo SP, Lourenço DM, Toledo RA. A differential diagnosis of inherited endocrine tumors and their tumor counterparts, journal=Clinics (Sao Paulo), volume= 68, issue= 7, 07/24/2013[32]

Risk factors of VTE may be categorized in to modifiable, non-modifiable, temporary and other risk factors.

Modifiable Risk Factors Non-Modifiable Risk Factors Temporary Risk Factors Other Risk Factors

❑ Modifiable risk factors are reversible based upon lifestyle/behavior modification.
Obesity is defined as a body-mass index (BMI) above 30 kg/m2.[33] [34] [35]
Smoking:[33] Smoking significantly increases the risk of DVT, particularly among women who are taking oral contraceptive pills as well as among obese people.
❑ Use of oral contraceptives[36]
Hyperhomocysteinemia:[37] Hyperhomocysteinemia can be reduced with vitamin B supplementation.

❑ Advanced age
Heart failure
Thrombophilia or hypercoagulable state
Polycythemia vera

Factor V Leiden
Prothrombin G20210A mutation
Protein C deficiency
Protein S deficiency
Activated protein C resistance
Antithrombin III deficiency
Factor VIII mutation
Antiphospholipid syndrome
Heparin induced thrombocytopenia
Nephrotic syndrome
Paroxysmal nocturnal hemoglobinuria

Pregnancy and the peri-partum period
❑ Active cancer
Central venous catheter

❑ Other possible factors associated with VTE include:[38]

❑ Nutrition low in fish
Psychological stress
❑ Cardiovascular risk factors such as diabetes and hypercholesterolemia
Functional (Nuclear) Imaging for Thyrotoxicosis
Diagnosis Degree of Thyrotoxicosis Radioactive iodine Uptake Scintigraphy Image
Toxic multinodular goiter +/++ Normal or +/++ Enlarged gland with multiple "hot" or "cold" nodules
Grave's disease ++++ ++++ Enlarged gland with homogenous uptake
Thyrotoxic phase of subacute thyroiditis ++++ <1% at 4 or 24 hr. Absent isotope uptake
Toxic adenoma +/++ Normal or +/++ Dominant "hot" nodule with low or absent uptake in the surrounding normal gland.
Multiple Endocrine Neoplasia-1 (MEN-1) Syndrome Tumors
Enteropancreatic tumor
  • Gastrinoma
  • Insulinoma
  • Glucagonoma
  • Nonfunctioning and PPoma
  • VIPoma
Pituitary adenoma
  • Prolactinoma
  • Somatotrophinoma
  • Corticotropinoma
  • Nonfunctioning
Associated tumors
  • Adrenal cortical tumor
  • Pheochromocytoma
  • Bronchopulmonary NET
  • Thymic NET
  • Gastric NET
  • Lipomas
  • Angiofibromas
  • Collagenomas
  • Meningiomas
Parathyroid adenoma

-

|- ! colspan="1" style="background: #4479BA; padding: 5px 5px;" | Parathyroid adenoma | style="padding: 5px 5px; background: #F5F5F5;" | Parathyroid adenoma

Laboratory Findings of Familial Hypocalciuric Hypercalcemia
Condition PTH Serum Calcium Serum phosphate Urine Calcium Urine Calcium/Serum Creatinine Ratio
Familial Hypocalciuric Hypercalcemia Normal Normal or ↑ Normal
Primary Hyperparathyroidism Normal
Cause of dementia Characteristics and clinical and cognitive features
Alzheimer's disease Brain disease that encompasses predementia and dementia phases. Memory changes and AD biomarker evidence required for diagnosis of probable AD. Slow cognitive and functional decline with early loss of awareness. Amnestic and nonamnestic phenotypes
Lewy body dementia Spectrum of disorders with movement, cognitive, autonomic changes. Includes dementia with Lewy bodies and Parkinson's disease dementia. Early visual hallucinations, muscle rigidity, sleep disturbance. α-synuclein deposits present in neurons
Frontotemporal lobar degeneration Focal atrophy of frontal and temporal lobes; knife-edge atrophy noted on MRI. Younger onset, changes in personality and behavior, language impairment, strong familial component.
Vascular dementia Stepwise progression and focal neurologic signs (also known as multi-infarct dementia or poststroke dementia). Dysexecutive syndrome, slowed processing speed, retrieval difficulties, depression, mild motor signs in subcortical vascular dementia. Symptoms overlap with alzheimer's disease.
Causes of Hypergastrinemia
Appropriate hypergastrinemia
  • Atrophic gastritis with or without pernicious anemia
  • Antisecretory therapy (PPIs or high-dose histamine H2-receptor antagonist)
  • Chronic renal failure
  • H pylori pangastritis
  • Vagotomy
Inappropriate hypergastrinemia
  • ZES (sporadic or associated with MEN-1)
  • Antral-predominant H pylori infection
  • Retained-antrum syndrome
  • Gastric-outlet obstruction
  • Small-bowel resection
Spurious hypergastrinemia
  • Nonfasting patient
  • Inaccurate assay
Cause of dementia Characteristics and clinical and cognitive features
AD Brain disease that encompasses predementia and dementia phases. Memory changes and AD biomarker evidence required for diagnosis of probable AD. Slow cognitive and functional decline with early loss of awareness. Amnestic and nonamnestic phenotypes
Lewy body dementia Spectrum of disorders with movement, cognitive, autonomic changes. Includes dementia with Lewy bodies and Parkinson's disease dementia. Early visual hallucinations, muscle rigidity, sleep disturbance. α-synuclein deposits present in neurons
Frontotemporal lobar degeneration Focal atrophy of frontal and temporal lobes; knife-edge atrophy noted on MRI. Younger onset, changes in personality and behavior, language impairment, strong familial component
VaD Stepwise progression and focal neurologic signs (also known as multi-infarct dementia or poststroke dementia). Dysexecutive syndrome, slowed processing speed, retrieval difficulties, depression, mild motor signs in subcortical VaD. Symptoms overlap with AD
Cause of dementia Characteristics and clinical and cognitive features
AD Brain disease that encompasses predementia and dementia phases. Memory changes and AD biomarker evidence required for diagnosis of probable AD. Slow cognitive and functional decline with early loss of awareness. Amnestic and nonamnestic phenotypes
Lewy body dementia Spectrum of disorders with movement, cognitive, autonomic changes. Includes dementia with Lewy bodies and Parkinson's disease dementia. Early visual hallucinations, muscle rigidity, sleep disturbance. α-synuclein deposits present in neurons
Frontotemporal lobar degeneration Focal atrophy of frontal and temporal lobes; knife-edge atrophy noted on MRI. Younger onset, changes in personality and behavior, language impairment, strong familial component
VaD Stepwise progression and focal neurologic signs (also known as multi-infarct dementia or poststroke dementia). Dysexecutive syndrome, slowed processing speed, retrieval difficulties, depression, mild motor signs in subcortical VaD. Symptoms overlap with AD
Clinical Dementia Rating
Based on the severity of Impairment
Criteria Minimal Questionable Mild Moderate Severe
Memory No memory loss or slight inconsistent forgetfulness Consistent slight forgetfulness; partial recollection of events; “benign” forgetfulness Moderate memory loss; more marked for recent events; defect interferes with everyday activities Severe memory loss; only highly learned material retained; new material rapidly lost Severe memory loss; only fragments remain
Orientation Fully oriented Fully oriented except for slight difficulty with time relationships Moderate difficulty with time relationships; oriented for place at examination; may have geographic disorientation elsewhere Severe difficulty with time relationships; usually disoriented to time, often to place Oriented to person only
Judgment and problem solving Solves everyday problems and handles business and financial affairs well; judgment good in relation to past performance Slight impairment in solving problems, determining similarities and differences Moderate difficulty in solving problems, determining similarities and differences; social judgment usually maintained Severely impaired in solving problems, determining similarities and differences; social judgment usually impaired Unable to make judgments or solve problems
Community affairs Independent function at usual level in job, shopping, and volunteer and social groups Slight impairment in these activities Unable to function independently at these activities, although may still be engaged in some; appears normal to casual inspection No pretense of independent function outside of home; appears well enough to be taken to functions outside a family home No pretense of independent function outside of home; appears too ill to be taken to functions outside a family home
Home and hobbies Life at home, hobbies, and intellectual interests well maintained Life at home, hobbies, and intellectual interests slightly impaired Mild but definite impairment of function at home; more difficult chores abandoned; more complicated hobbies and interests abandoned Only simple chores preserved; interests very restricted and poorly maintained No significant function in home
Personal care Fully capable of self-care Fully capable of self-care Needs prompting Requires assistance in dressing, hygiene, keeping of personal effects Requires much help with personal care; frequent incontinence
Sandbox: Dr.Reddy
File:.jpg
xxx

{| class="wikitable"

!Condition !T3 !T4 !TSH |- |Thyrotoxicosis |Increased |Increased |Supressed |- |T3 Toxicosis |2X (Increased Twice) |Normal |Supressed |- |Hypothyroidism |Low/Normal |Low |Increased |} ↓ β

Differentiating Thyroid adenoma from other Diseases

The table below summarizes the findings that differentiate thyroid adenoma from other conditions that cause neck swelling.[39]

Disease Findings
Multinodular goiter Multinodular goiter is the multinodular enlargement of the thyroid gland. They are large nodules of more than 1 cm that produces symptoms of hyperthyroidism.
Grave's disease Grave's disease is an autoimmune disease that affects the thyroid. It frequently results in hyperthyroidism and an enlarged thyroid. Pretibial myxedema and ophthalmopathy are some of the findings of grave's disease.
Hashimoto's disease Hashimoto's disease is an autoimmune disease in which the thyroid gland is attacked by a variety of cell-mediated and antibody-mediated immune processes, causing primary hypothyroidism.
Medullary thyroid carcinoma Medullary thyroid carcinoma is a form of thyroid carcinoma which originates from the parafollicular cells (C cells), which produce the hormone calcitonin.
Thyroid lymphoma Thyroid lymphoma is a rare malignant tumor which manifests as rapidly enlarging neck mass causing respiratory difficulty.
De Quervain's thyroiditis De Quervain's thyroiditis is a subacute granulomatous thyroiditis preceded by an upper respiratory tract infection.
Acute suppurative thyroiditis Acute suppurative thyroiditis is an uncommon thyroid disorder usually caused by bacterial infection.

Thyroid adenoma must be differentiated from other causes of hyperthyroidism such as Grave's disease and toxic nodular goiter.

Cause of thyrotoxicosis TSH receptor antibodies Thyroid US Color flow Doppler Radioactive iodine uptake/Scan Other features
Graves' disease + Hypoechoic pattern ? ? Ophthalmopathy, dermopathy, acropachy
Toxic nodular goiter - Multiple nodules - Hot nodules at thyroid scan -
Toxic adenoma - Single nodule - Hot nodule -
Subacute thyroiditis - Heterogeneous hypoechoic areas Reduced/absent flow ? Neck pain, fever, and
elevated inflammatory index
Painless thyroiditis - Hypoechoic pattern Reduced/absent flow ? -
Amiodarone induced thyroiditis-Type 1 - Diffuse or nodular goiter ?/Normal/? ? but higher than in Type 2 High urinary iodine
Amiodarone induced thyroiditis-Type 2 - Normal Absent ?/absent High urinary iodine
Central hyperthyroidism - Diffuse or nodular goiter Normal/? ? Inappropriately normal or high TSH
Trophoblastic disease - Diffuse or nodular goiter Normal/? ? -
Factitious thyrotoxicosis - Variable Reduced/absent flow ? ? Serum thyroglobulin
Struma ovarii - Variable Reduced/absent flow ? Abdominal RAIU
Disease Findings
Thyroiditis Direct chemical toxicity with inflammation Amiodarone, sunitinib, pazopanib, axitinib, and other tyrosine kinase inhibitors may also be associated with a destructive thyroiditis.[40][41]
Radiation thyroiditis Patients treated with radioiodine may develop thyroid pain and tenderness 5 to 10 days later, due to radiation-induced injury and necrosis of thyroid follicular cells and associated inflammation.
Drugs that interfere with the immune system Interferon-alfa is a well-known cause of thyroid abnormality. It mostly leads to the development of de novo antithyroid antibodies.[42]
Lithium Patients treated with lithium are at a high risk of developing painless thyroiditis and Graves' disease.
Palpation thyroiditis Manipulation of the thyroid gland during thyroid biopsy or neck surgery and vigorous palpation during the physical examination may cause transient hyperthyroidism.
Exogenous and ectopic hyperthyroidism Factitious ingestion of thyroid hormone The diagnosis is based on the clinical features, laboratory findings, and 24-hour radioiodine uptake.[43]
Acute hyperthyroidism from a levothyroxine overdose The diagnosis is based on the clinical features, laboratory findings, and 24-hour radioiodine uptake.[44]
Struma ovarii Functioning thyroid tissue is present in an ovarian neoplasm.
Functional thyroid cancer metastases Large bony metastases from widely metastatic follicular thyroid cancer cause symptomatic hyperthyroidism.
Hashitoxicosis It is an autoimmune thyroid disease that initially presents with hyperthyroidism and a high radioiodine uptake caused by TSH-receptor antibodies similar to Graves' disease. It is then followed by the development of hypothyroidism due to the infiltration of the thyroid gland with lymphocytes and the resultant autoimmune-mediated destruction of thyroid tissue, similar to chronic lymphocytic thyroiditis.[45]
Toxic adenoma and toxic multinodular goiter Toxic adenoma and toxic multinodular goiter are results of focal/diffuse hyperplasia of thyroid follicular cells independent of TSH regulation. Findings of single or multiple nodules are seen on physical examination or thyroid scan.[46]
Iodine-induced hyperthyroidism It is uncommon but can develop after an iodine load, such as administration of contrast agents used for angiography or computed tomography (CT), or iodine-rich drugs such as amiodarone.
Trophoblastic disease and germ cell tumors Thyroid-stimulating hormone and HCG have a common alpha-subunit and a beta-subunit with considerable homology. As a result, HCG has weak thyroid-stimulating activity and high titer HCG may mimic hyperthyroidism.[47]
Sandbox: Dr.Reddy
Diagnostic accuracy of imaging for localization of gastrinoma
CT 50% Tumors enhance on early arterial phase because of high vascularity; sensitivity decreases for tumors <2cm
MRI
Diagnostic accuracy of imaging for localization of gastrinoma
Modality Sensitivity Comments
  • CT
  • MRI
  • SRS
  • EUS
  • Angiography / Arterial Stimulation
  • 50%
  • 25-50%
  • 80%
  • 70%
  • 40-60%
  • Tumors enhance on early arterial phase because of high vascularity; sensitivity decreases for tumors <2cm
  • Low T1 and high T2 signal intensity.
  • Additional ability to detect extra abdominal metastatic lesions; enhanced sensitivity when combined with single photon emission computed tomography (SPECT)
  • Much higher sensitivity for pancreatic compared with duodenal lesions; can guide needle biopsy to obtain tissue diagnosis.
  • Contrast administered into GDA and inferior pancreaticoduodenal artery; may be performed intraoperatively
Sporadic and MEN-1-associated ZES
Factors Sopradic ZES MEN-1 ZES
  • Prevalence
  • Family History
  • Other Endocrinopathies
  • Gastrinoma Size
  • Number of tumors
  • Most Common Tumor Location
  • Lymph Node Primary
  • Surgical Cure Rate
  • Malignant Potential
  • 80%
  • No
  • No
  • >2cm
  • Single
  • Pancreas
  • 10%
  • 60%
  • High
  • 20%
  • Yes
  • Yes
  • <2cm
  • Multiple
  • Duodenum
  • No
  • Rare
  • Low
Causes of Hypergastrinemia
Appropriate hypergastrinemia
  • Atrophic gastritis with or without pernicious anemia
  • Antisecretory therapy (PPIs or high-dose histamine H2-receptor antagonist)
  • Chronic renal failure
  • H pylori pangastritis
  • Vagotomy
Inappropriate hypergastrinemia
  • ZES (sporadic or associated with MEN-1)
  • Antral-predominant H pylori infection
  • Retained-antrum syndrome
  • Gastric-outlet obstruction
  • Small-bowel resection
Spurious hypergastrinemia
  • Nonfasting patient
  • Inaccurate assay
Surgical approach to gastrinoma in sporadic ZES and ZES associated with MEN-1
sporadic ZES MEN-1 ZES
  • ABCD
  • abcd
  • 1234
Surgical approach to gastrinoma in sporadic ZES and ZES associated with MEN-1
sporadic ZES MEN-1 ZES
  • ABCD
  • abcd
  • 1234
Classification of Androgen Insensitivity Syndrome Phenotypes
Type External Genitalia Findings
CAIS - (Complete androgen insensitivity syndrome) Female (“testicular feminization”)
  • Absent OR rudimentary wolffian duct derivatives.
  • Absence or presence of epididymides and/or vas deferens.
  • Inguinal, labial, or abdominal testes.
  • Short blind-ending vagina.
  • Scant OR absent pubic AND/OR axillary hair.
Predominantly female (“incomplete AIS”)
  • Inguinal OR labial testes.
  • Clitoromegaly and labial fusion.
  • Distinct urethral and vaginal openings OR a urogenital sinus.
PAIS - (Partial androgen insensitivity syndrome) Ambiguous
  • Microphallus (<1 cm) with clitoris-like underdeveloped glans; labia majora-like bifid scrotum.
  • Descended OR undescended testes.
  • Perineoscrotal hypospadias OR urogenital sinus.
  • Gynecomastia (development of breasts) in puberty.
Predominantly male
  • Simple (glandular or penile) OR severe (perineal) “isolated” hypospadias with a normal-sized penis and descended testes OR severe hypospadias with micropenis, bifid scrotum, and either descended OR undescended testes.
  • Gynecomastia in puberty.
MAIS - (Mild androgen insensitivity syndrome) Male (“undervirilized male syndrome”)
  • Impaired spermatogenesis AND/OR impaired pubertal virilization.
  • Gynecomastia in puberty.


Template:Topic Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief:

Overview

Topic

References

  1. Ness W (2012). "Faecal incontinence: causes, assessment and management". Nurs Stand. 26 (42): 52–4, 56, 58–60. doi:10.7748/ns2012.06.26.42.52.c9162. PMID 22908765.
  2. 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 Alavi K, Chan S, Wise P, Kaiser AM, Sudan R, Bordeianou L (2015). "Fecal Incontinence: Etiology, Diagnosis, and Management". J Gastrointest Surg. 19 (10): 1910–21. doi:10.1007/s11605-015-2905-1. PMID 26268955.
  3. Muñoz-Yagüe T, Solís-Muñoz P, Ciriza de los Ríos C, Muñoz-Garrido F, Vara J, Solís-Herruzo JA (2014). "Fecal incontinence in men: causes and clinical and manometric features". World J Gastroenterol. 20 (24): 7933–40. doi:10.3748/wjg.v20.i24.7933. PMC 4069320. PMID 24976729.
  4. Nelson R, Norton N, Cautley E, Furner S (1995). "Community-based prevalence of anal incontinence". JAMA. 274 (7): 559–61. PMID 7629985.
  5. 5.0 5.1 5.2 5.3 Whitehead WE, Borrud L, Goode PS, Meikle S, Mueller ER, Tuteja A; et al. (2009). "Fecal incontinence in US adults: epidemiology and risk factors". Gastroenterology. 137 (2): 512–7, 517.e1–2. doi:10.1053/j.gastro.2009.04.054. PMC 2748224. PMID 19410574.
  6. Rey E, Choung RS, Schleck CD, Zinsmeister AR, Locke GR, Talley NJ (2010). "Onset and risk factors for fecal incontinence in a US community". Am J Gastroenterol. 105 (2): 412–9. doi:10.1038/ajg.2009.594. PMC 3189687. PMID 19844202.
  7. Staller K, Townsend MK, Khalili H, Mehta R, Grodstein F, Whitehead WE; et al. (2017). "Menopausal Hormone Therapy Is Associated With Increased Risk of Fecal Incontinence in Women After Menopause". Gastroenterology. 152 (8): 1915–1921.e1. doi:10.1053/j.gastro.2017.02.005. PMC 5447480. PMID 28209529.
  8. Andy UU, Vaughan CP, Burgio KL, Alli FM, Goode PS, Markland AD (2016). "Shared Risk Factors for Constipation, Fecal Incontinence, and Combined Symptoms in Older U.S. Adults". J Am Geriatr Soc. 64 (11): e183–e188. doi:10.1111/jgs.14521. PMID 27783401.
  9. Matthews CA (2014). "Risk factors for urinary, fecal, or double incontinence in women". Curr Opin Obstet Gynecol. 26 (5): 393–7. doi:10.1097/GCO.0000000000000094. PMID 25110978.
  10. Baxter NN, Rothenberger DA, Lowry AC (2003). "Measuring fecal incontinence". Dis Colon Rectum. 46 (12): 1591–605. doi:10.1097/01.DCR.0000098906.61097.1C. PMID 14668583.
  11. Vaizey CJ, Carapeti E, Cahill JA, Kamm MA (1999). "Prospective comparison of faecal incontinence grading systems". Gut. 44 (1): 77–80. PMC 1760067. PMID 9862829.
  12. van Meegdenburg MM, Heineman E, Broens PM (2015). "Pudendal Neuropathy Alone Results in Urge Incontinence Rather Than in Complete Fecal Incontinence". Dis Colon Rectum. 58 (12): 1186–93. doi:10.1097/DCR.0000000000000497. PMID 26544817.
  13. 13.0 13.1 Buhmann H, Nocito A (2014). "[Update on fecal incontinence]". Praxis (Bern 1994). 103 (22): 1313–21. doi:10.1024/1661-8157/a001831. PMID 25351694.
  14. Read M, Read NW, Barber DC, Duthie HL (1982). "Effects of loperamide on anal sphincter function in patients complaining of chronic diarrhea with fecal incontinence and urgency". Dig Dis Sci. 27 (9): 807–14. PMID 7105952.
  15. Santoro GA, Eitan BZ, Pryde A, Bartolo DC (2000). "Open study of low-dose amitriptyline in the treatment of patients with idiopathic fecal incontinence". Dis Colon Rectum. 43 (12): 1676–81, discussion 1681-2. PMID 11156450.
  16. Chassagne P, Jego A, Gloc P, Capet C, Trivalle C, Doucet J; et al. (2000). "Does treatment of constipation improve faecal incontinence in institutionalized elderly patients?". Age Ageing. 29 (2): 159–64. PMID 10791451.
  17. Heymen S, Scarlett Y, Jones K, Ringel Y, Drossman D, Whitehead WE (2009). "Randomized controlled trial shows biofeedback to be superior to pelvic floor exercises for fecal incontinence". Dis Colon Rectum. 52 (10): 1730–7. doi:10.1007/DCR.0b013e3181b55455. PMC 3855426. PMID 19966605.
  18. Landefeld CS, Bowers BJ, Feld AD, Hartmann KE, Hoffman E, Ingber MJ; et al. (2008). "National Institutes of Health state-of-the-science conference statement: prevention of fecal and urinary incontinence in adults". Ann Intern Med. 148 (6): 449–58. PMID 18268289.
  19. Boyle R, Hay-Smith EJ, Cody JD, Mørkved S (2012). "Pelvic floor muscle training for prevention and treatment of urinary and faecal incontinence in antenatal and postnatal women". Cochrane Database Syst Rev. 10: CD007471. doi:10.1002/14651858.CD007471.pub2. PMID 23076935.
  20. Norton C, Whitehead WE, Bliss DZ, Harari D, Lang J, Conservative Management of Fecal Incontinence in Adults Committee of the International Consultation on Incontinence (2010). "Management of fecal incontinence in adults". Neurourol Urodyn. 29 (1): 199–206. doi:10.1002/nau.20803. PMID 20025031.
  21. 21.0 21.1 21.2 21.3 21.4 21.5 Coccolini F, Montori G, Catena F, Kluger Y, Biffl W, Moore EE; et al. (2017). "Splenic trauma: WSES classification and guidelines for adult and pediatric patients". World J Emerg Surg. 12: 40. doi:10.1186/s13017-017-0151-4. PMC 5562999. PMID 28828034.
  22. 22.0 22.1 22.2 22.3 Seufferlein T, Bachet JB, Van Cutsem E, Rougier P, ESMO Guidelines Working Group (2012). "Pancreatic adenocarcinoma: ESMO-ESDO Clinical Practice Guidelines for diagnosis, treatment and follow-up". Ann Oncol. 23 Suppl 7: vii33–40. doi:10.1093/annonc/mds224. PMID 22997452.
  23. 23.0 23.1 23.2 Bond-Smith G, Banga N, Hammond TM, Imber CJ (2012). "Pancreatic adenocarcinoma". BMJ. 344: e2476. doi:10.1136/bmj.e2476. PMID 22592847.
  24. Ryan DP, Hong TS, Bardeesy N (2014). "Pancreatic adenocarcinoma". N Engl J Med. 371 (11): 1039–49. doi:10.1056/NEJMra1404198. PMID 25207767.
  25. Kuhn JH, Bao Y, Bavari S, Becker S, Bradfute S, Brister JR; et al. (2013). "Virus nomenclature below the species level: a standardized nomenclature for natural variants of viruses assigned to the family Filoviridae". Arch Virol. 158 (1): 301–11. doi:10.1007/s00705-012-1454-0. PMC 3535543. PMID 23001720.
  26. 26.0 26.1 26.2 "Outbreak of Marburg Hemorrhagic Fever Among Miners in Kamwenge and Ibanda Districts, Uganda, 2007". Missing or empty |url= (help)
  27. Towner JS, Khristova ML, Sealy TK, Vincent MJ, Erickson BR, Bawiec DA; et al. (2006). "Marburgvirus genomics and association with a large hemorrhagic fever outbreak in Angola". J Virol. 80 (13): 6497–516. doi:10.1128/JVI.00069-06. PMC 1488971. PMID 16775337.
  28. Mehedi M, Groseth A, Feldmann H, Ebihara H (2011). "Clinical aspects of Marburg hemorrhagic fever". Future Virol. 6 (9): 1091–1106. doi:10.2217/fvl.11.79. PMC 3201746. PMID 22046196.
  29. Smith DH, Johnson BK, Isaacson M, Swanapoel R, Johnson KM, Killey M; et al. (1982). "Marburg-virus disease in Kenya". Lancet. 1 (8276): 816–20. PMID 6122054.
  30. "WHO". Missing or empty |url= (help)
  31. Feldmann H, Slenczka W, Klenk HD (1996). "Emerging and reemerging of filoviruses". Arch Virol Suppl. 11: 77–100. PMID 8800808.
  32. 32.0 32.1 Toledo SP, Lourenço DM, Toledo RA (2013). "A differential diagnosis of inherited endocrine tumors and their tumor counterparts". Clinics (Sao Paulo). 68 (7): 1039–56. doi:10.6061/clinics/2013(07)24. PMC 3715026. PMID 23917672.
  33. 33.0 33.1 Holst AG, Jensen G, Prescott E (2010). "Risk factors for venous thromboembolism: results from the Copenhagen City Heart Study". Circulation. 121 (17): 1896–903. doi:10.1161/CIRCULATIONAHA.109.921460. PMID 20404252.
  34. Vayá A, Martínez-Triguero ML, España F, Todolí JA, Bonet E, Corella D (2011). "The metabolic syndrome and its individual components: its association with venous thromboembolism in a Mediterranean population". Metab Syndr Relat Disord. 9 (3): 197–201. doi:10.1089/met.2010.0117. PMID 21352080.
  35. Eichinger S, Hron G, Bialonczyk C, Hirschl M, Minar E, Wagner O; et al. (2008). "Overweight, obesity, and the risk of recurrent venous thromboembolism". Arch Intern Med. 168 (15): 1678–83. doi:10.1001/archinte.168.15.1678. PMID 18695082.
  36. Pomp ER, Rosendaal FR, Doggen CJ (2008). "Smoking increases the risk of venous thrombosis and acts synergistically with oral contraceptive use". Am J Hematol. 83 (2): 97–102. doi:10.1002/ajh.21059. PMID 17726684.
  37. den Heijer M, Koster T, Blom HJ, Bos GM, Briet E, Reitsma PH; et al. (1996). "Hyperhomocysteinemia as a risk factor for deep-vein thrombosis". N Engl J Med. 334 (12): 759–62. doi:10.1056/NEJM199603213341203. PMID 8592549.
  38. Konofal E, Lecendreux M, Cortese S (2010). "Sleep and ADHD". Sleep Med. 11 (7): 652–8. doi:10.1016/j.sleep.2010.02.012. PMID 20620109.
  39. Thyroid adenoma. Wikipedia. https://en.wikipedia.org/wiki/Thyroid_adenoma Accessed on October 11, 2015
  40. Lambert M, Unger J, De Nayer P, Brohet C, Gangji D (1990). "Amiodarone-induced thyrotoxicosis suggestive of thyroid damage". J. Endocrinol. Invest. 13 (6): 527–30. PMID 2258582.
  41. Ahmadieh H, Salti I (2013). "Tyrosine kinase inhibitors induced thyroid dysfunction: a review of its incidence, pathophysiology, clinical relevance, and treatment". Biomed Res Int. 2013: 725410. doi:10.1155/2013/725410. PMC 3824811. PMID 24282820.
  42. Vialettes B, Guillerand MA, Viens P, Stoppa AM, Baume D, Sauvan R, Pasquier J, San Marco M, Olive D, Maraninchi D (1993). "Incidence rate and risk factors for thyroid dysfunction during recombinant interleukin-2 therapy in advanced malignancies". Acta Endocrinol. 129 (1): 31–8. PMID 8351956.
  43. Cohen JH, Ingbar SH, Braverman LE (1989). "Thyrotoxicosis due to ingestion of excess thyroid hormone". Endocr. Rev. 10 (2): 113–24. doi:10.1210/edrv-10-2-113. PMID 2666114.
  44. Jha S, Waghdhare S, Reddi R, Bhattacharya P (2012). "Thyroid storm due to inappropriate administration of a compounded thyroid hormone preparation successfully treated with plasmapheresis". Thyroid. 22 (12): 1283–6. doi:10.1089/thy.2011.0353. PMID 23067331.
  45. Fatourechi V, McConahey WM, Woolner LB (1971). "Hyperthyroidism associated with histologic Hashimoto's thyroiditis". Mayo Clin. Proc. 46 (10): 682–9. PMID 5171000.
  46. Laurberg P, Pedersen KM, Vestergaard H, Sigurdsson G (1991). "High incidence of multinodular toxic goitre in the elderly population in a low iodine intake area vs. high incidence of Graves' disease in the young in a high iodine intake area: comparative surveys of thyrotoxicosis epidemiology in East-Jutland Denmark and Iceland". J. Intern. Med. 229 (5): 415–20. PMID 2040867.
  47. Oosting SF, de Haas EC, Links TP, de Bruin D, Sluiter WJ, de Jong IJ, Hoekstra HJ, Sleijfer DT, Gietema JA (2010). "Prevalence of paraneoplastic hyperthyroidism in patients with metastatic non-seminomatous germ-cell tumors". Ann. Oncol. 21 (1): 104–8. doi:10.1093/annonc/mdp265. PMID 19605510.

Template:WH Template:WS

Retrieved from "https://www.wikidoc.org/index.php?title=Sandbox:_Dr.Reddy&oldid=1436181"