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The Gist of the Matter
- In Archaeogastropods, the Acmaea, the torsion takes place by muscles contraction alone.
- The rotation of 180° is completed in two stages, the first movement takes place by the contraction of larval retractor muscle and second rotation is slower by different growth. It is very common as in Patella, Haliotis etc.
- The rotation of 180° takes place by only differential growth processes like Vivapara.
- Rotation by differential growth processes, with anus coming to a position appropriate to the adult state like Aplysia.
- Torsion is no longer recognizable as a movement of viscera-pallium, the organs in the post-torsional position from their first appearance as in Adalaria.
- Displacement of mantle cavity: The mantle cavity was primarily present on the posterior side. The elongation of the ventral foot which was primarily very small. After torsion, the mantle cavity opens just behind the head and its associated parts are shifted forwards.
- Changes in relative position: Before torsion, the anus, ctenidia and excretory opening were placed on the posterior side and the auricles were placed behind the ventricle but after torsion the anus, ctenidia and excretory opening become anterior and the auricles lie in front of the ventricle. The original posterior face of the visceral sac becomes the anterior face so that the visceral organs morphologically of the original right side change into the left side.
- Looping of alimentary canal: The alimentary canal which was originally straight from mouth to anus, after torsion, it changes into a loop.
- Chiastoneury: The long, uncoiled pleuro-visceral nerve connectives become a figure of "8" after twisting. The right connective with its ganglion passes over the intestine to form the supra-intestinal connective, while the next connective pass under the intestine to form the infra-intestinal connective.
- Endogastric coil: The coil of visceral sac and shell, which was primarily dorsal or exogastric become ventral and endogastric after torsion.
- Loss of Symmetry of Atrophy: The anus changes their original position towards the right side of the pallial cavity so that the original symmetrical condition disturbed.
Pearl is secreted by the mantle as a means of protection against a small external particle. When an external particle or body, such as a grain of sand or a small parasite invades in between the mantle and the shell it becomes enclosed in a sac of mantle epithelium which produces irritation. The irritation stimulates the mantle epithelium to secrete thin concentric layers of mother of pearl around the foreign body. The amount of deposition is in direct proportion to the degree of irritation. After several years, a pearl will be formed, usually, it requires 3 to 4 years to produce a pearl of considerable size but a large pearl requires about 7 years. The foreign particles in the pearl are called nucleus whereas the thin nacre layers are concentric and called the mother of pearl.
- Towel or soft cloth
- Blackhead removal strips or pads
- Salicylic acid (C7H6O3)
|DISTILLED WATER||REVERSE OSMOSIS (RO) WATER||DEIONIZED (DI) WATER|
|Distillation is employed in the main in laboratories and factories, wherever it's required. Reverse diffusion is widely employed in water treatment plants, each reception and for the manufacture of assorted drinks, drinking water, etc.||
||DI water is as pure because the water or maybe purer|
- Hyperthyroidism: Elevation of both T4 and T3 values along with decrease of TSH are indicative of primary hyperthyroidism.
- Increased thyroxine-binding globulin: If concentration of TBG increases, free hormone level falls, release of TSH from pituitary is stimulated, and free hormone concentration is restored to normal. Reverse occurs if concentration of binding proteins falls. In either case, level of free hormones remains normal, while concentration of total hormone is altered. Therefore, estimation of only total T4 concentration can cause misinterpretation of results in situations that alter concentration of TBG.
- Factitious hyperthyroidism
- Pituitary TSH-secreting tumor.
- Primary hypothyroidism: The combination of decreased T4 and elevated TSH are indicative of primary hypothyroidism.
- Secondary or pituitary hypothyroidism
- Tertiary or hypothalamic hypothyroidism
- Hypoproteinaemia, e.g. nephrotic syndrome
- Drugs: oestrogen, danazol
- Severe non-thyroidal illness.
- Diagnosis of T3 thyrotoxicosis: Hyperthyroidism with low TSH and elevated T3, and normal T4/FT4 is termed T3 thyrotoxicosis.
- Early diagnosis of hyperthyroidism: In early stage of hyperthyroidism, total T4 and free T4 levels are normal, but T3 is elevated.
- Confirmation of diagnosis of secondary hypothyroidism
- Evaluation of suspected hypothalamic disease
- Suspected hyperthyroidism
- A baseline blood sample is collected for estimation of basal serum TSH level.
- TRH is injected intravenously (200 or 500 μg) followed by measurement of serum TSH at 20 and 60 minutes.
- Normal response: A rise of TSH > 2 mU/L at 20 minutes, and a small decline at 60 minutes.
- Exaggerated response: A further significant rise in already elevated TSH level at 20 minutes followed by a slight decrease at 60 minutes; occurs in primary hypothyroidism.
- Flat response: There is no response; occurs in secondary (pituitary) hypothyroidism.
- Delayed response: TSH is higher at 60 minutes as compared to its level at 20 minutes; seen in tertiary (hypothalamic) hypothyroidism.
Box 864.1 Thyroid autoantibodies
- Hyperthyroidism due to Graves’ disease, toxic multinodular goiter, toxic adenoma, TSH-secreting tumor.
- Hyperthyroidism due to administration of thyroid hormone, factitious hyperthyroidism, subacute thyroiditis.
- Differential diagnosis of high RAIU thyrotoxicosis:
– Graves’ disease: Uniform or diffuse increase in uptake
– Toxic multinodular goiter: Multiple discrete areas of increased uptake
– Adenoma: Single area of increased uptake
- Evaluation of a solitary thyroid nodule:
– ‘Hot’ nodule: Hyperfunctioning
– ‘Cold’ nodule: Non-functioning; about 20% cases are malignant.
|1. TSH Normal, FT4 Normal||Euthyroid|
|2. Low TSH, Low FT4||Secondary hypothyroidism|
|3. High TSH, Normal FT4||Subclinical hypothyroidism|
|4. High TSH, Low FT4||Primary hypothyroidism|
|5. Low TSH, Normal FT4, Normal FT3||Subclinical hyperthyroidism|
|6. Low TSH, Normal FT4, High FT3||T3 toxicosis|
|7. Low TSH, High FT4||Primary hyperthyroidism|
|Box 863.1 Terminology in thyroid disorders
|Box 863.2 Thyroid function tests in hyperthyroidism
|Parameter||Primary hyperthyroidism||Secondary hyperthyroidism|
|1. Serum TSH||Low||Normal or high|
|2. Serum free thyroxine||High||High|
|3. TSH receptor antibodies||May be positive||Negative|
|4. Causes||Graves’ disease, toxic multinodular goiter, toxic adenoma||Pituitary adenoma|
|Parameter||Primary hypothyroidism||Secondary hypothyroidism|
|1. Cause||Hashimoto’s thyroiditis||Pituitary disease|
|2. Serum TSH||High||Low|
|3. Thyrotropin releasing hormone stimulation test||Exaggerated response||No response|
|4. Antimicrosomal antibodies||Present||Absent|
Box 863.3 Thyroid function tests in hypothyroidism
1. Hypothalamic-pituitary dysfunction:
2. Ovarian dysfunction:
|3. Dysfunction in passages:|
|4. Dysfunction of sexual act: Dyspareunia|
- Regular cycles, mastalgia, and laparoscopic direct visualization of corpus luteum indicate ovulatory cycles. Anovulatory cycles are clinically characterized by amenorrhea, oligomenorrhea, or irregular menstruation. However, apparently regular cycles may be associated with anovulation.
- Endometrial biopsy: Endometrial biopsy is done during premenstrual period (21st-23rd day of the cycle). The secretory endometrium during the later half of the cycle is an evidence of ovulation.
- Ultrasonography (USG): Serial ultrasonography is done from 10th day of the cycle and the size of the dominant follicle is measured. Size >18 mm is indicative of imminent ovulation. Collapse of the follicle with presence of few ml of fluid in the pouch of Douglas is suggestive of ovulation. USG also is helpful for treatment (i.e. timing of coitus or of intrauterine insemination) and diagnosis of luteinized unruptured follicle (absence of collapse of dominant follicle). Transvaginal USG is more sensitive than abdominal USG.
- Basal body temperature (BBT): Patient takes her oral temperature at the same time every morning before arising. BBT falls by about 0.5°F at the time of ovulation. During the second (progestational) half of the cycle, temperature is slightly raised above the preovulatory level (rise of 0.5° to 1°F). This is due to the slight pyrogenic action of progesterone and is therefore presumptive evidence of functional corpus luteum.
- Cervical mucus study:
• Fern test: During estrogenic phase, a characteristic pattern of fern formation is seen when cervical mucus is spread on a glass slide (Figure 862.4). This ferning disappears after the 21st day of the cycle. If previously observed, its disappearance is presumptive evidence of corpus luteum activity.
• Spinnbarkeit test: Cervical mucus is elastic and withstands stretching upto a distance of over 10 cm. This phenomenon is called Spinnbarkeit or the thread test for the estrogen activity. During the secretory phase, viscosity of the cervical mucus increases and it gets fractured when stretched. This change in cervical mucus is evidence of ovulation.
- Vaginal cytology: Karyopyknotic index (KI) is high during estrogenic phase, while it becomes low in secretory phase. This refers to percentage of super-ficial squamous cells with pyknotic nuclei to all mature squamous cells in a lateral vaginal wall smear. Usually minimum of 300 cells are evaluated. The peak KI usually corresponds with time of ovulation and may reach upto 50 to 85.
- Estimation of progesterone in mid-luteal phase (day 21 or 7 days before expected menstruation): Progesterone level > 10 nmol/L is a reliable evidence of ovulation if cycles are regular (Figure 862.5). A mistimed sample is a common cause of abnormal result.
- Measurement of LH, FSH, and estradiol during days 2 to 6: All values are low in hypogonadotropic hypogonadism (hypothalamic or pituitary failure).
- Measurement of TSH, prolactin, and testosterone if cycles are irregular or absent:
Increased TSH: Hypothyroidism
Increased prolactin: Pituitary adenoma
Increased testosterone: Polycystic ovarian disease (PCOD), congenital adrenal hyperplasia (To differentiate PCOD from congenital adrenal hyperplasia, ultrasound and estimation of dihydroepiandrosterone or DHEA are done).
- Transvaginal ultrasonography: This is done for detection of PCOD.
- Infectious disease: These tests include endometrial biopsy for tuberculosis and test for chlamydial IgG antibodies for tubal factor in infertility.
- Hysterosalpingography (HSG): HSG is a radiological contrast study for investigation of the shape of the uterine cavity and for blockage of fallopian tubes (Figure 862.6). A catheter is introduced into the cervical canal and a radiocontrast dye is injected into the uterine cavity. A real time X-ray imaging is carried out to observe the flow of the dye into the uterine cavity, tubes, and spillage into the uterine cavity.
- Hysterosalpingo-contrast sonography: A catheter is introduced into the cervical canal and an echocontrast fluid is introduced into the uterine cavity. Shape of the uterine cavity, filling of fallopian tubes, and spillage of contrast fluid are noted. In addition, ultrasound scan of the pelvis provides information about any fibroids or polycystic ovarian disease.
- Laparoscopy and dye hydrotubation test with hysteroscopy: In this test, a cannula is inserted into the cervix and methylene blue dye is introduced into the uterine cavity. If tubes are patent, spillage of the dye is observed from the ends of both tubes. This technique also allows visualization of pelvic organs, endometriosis, and pelvic adhesions. If required, endometriosis and tubal blockage can be treated during the procedure.
2. Hypothalamic-pituitary dysfunction (hypogonadotropic hypogonadism)
3. Testicular dysfunction:
4. Dysfunction of passages and accessory sex glands:
5. Dysfunction of sexual act:
- History: This includes type of lifestyle (heavy smoking, alcoholism), sexual practice, erectile dysfunction, ejaculation, sexually transmitted diseases, surgery in genital area, drugs, and any systemic illness.
- Physical examination: Examination of reproductive system should includes testicular size, undescended testes, hypospadias, scrotal abnormalities (like varicocele), body hair, and facial hair. Varicocele can occur bilaterally and is the most common surgically removable abnormality causing male infertility.
- Semen analysis: See article Semen Analysis. Evaluation of azoospermia is shown in Figure 861.3. Evaluation of low semen volume is shown in Figure 861.4.
- Chromosomal analysis: This can reveal Klinefelter’s syndrome (e.g. XXY karyotype) (Figure 861.5), deletion in Y chromosome, and autosomal Robertsonian translocation. It is necessary to screen for cystic fibrosis carrier state if bilateral congenital absence of vas deferens is present.
- Hormonal studies: This includes measurement of FSH, LH, and testosterone to detect hormonal abnormalities causing testicular failure (Table 861.2).
- Testicular biopsy: Testicular biopsy is indicated when differentiation between obstructive and non-obstructive azoospermia is not evident (i.e. normal FSH and normal testicular volume).
|Follicle stimulating hormone||Luteinizing hormone||Testosterone||Interpretation|
|Low||Low||Low||Hypogonadotropic hypogonadism (Hypothalamic or pituitary disorder)|
|High||High||Low||Hypergonadotropic hypogonadism (Testicular disorder)|
|Normal||Normal||Normal||Obstruction of passages, dysfunction of accessory glands|