Show Script Cover & Table of Contents
The dynamic process by which the single-cell human zygote(zī΄gōt)[1] becomes a 100 trillion (1014) cell adult[2] is perhaps the most remarkable phenomenon in all of nature.
Researchers now know that many of the routine functions performed by the adult body become established during pregnancy – often long before birth.[3]
The developmental period before birth is increasingly understood as a time of preparation during which the developing human acquires the many structures, and practices the many skills, needed for survival after birth.
Den dynamiska process i vilken en enda befruktad mänsklig äggcell blir till en vuxen med 100 biljoner celler är kanske naturens allra mest märkliga fenomen.
Forskare vet nu att många av de vanliga funktionerna hos den vuxna kroppen grundläggs under graviditeten - ofta långt innan födelsen.
Utvecklingsperioden innan födseln förstås alltmer som en tid av förberedelse under vilken den blivande människan förvärvar de många system, och övar de många färdigheter, som behövs för att överleva efter födseln.
Pregnancy in humans normally lasts approximately 38 weeks[4] as measured from the time of fertilization,[5] or conception,[6] until birth.
During the first 8 weeks following fertilization, the developing human is called an embryo,[7] which means "growing within."[8] This time, called the embryonic period,[9] is characterized by the formation of most major body systems.[10]
From the completion of 8 weeks until the end of pregnancy, "the developing human is called a fetus," which means "unborn offspring." During this time, called the fetal period, the body grows larger and its systems begin to function.[11]
All embryonic and fetal ages in this program refer to the time since fertilization.[12]
Den mänskliga graviditeten varar i ungefär 38 veckor mätt från tiden för befruktning, eller konception, till födseln.
De första åtta veckorna efter befruktningen, kallas den blivande människan för embryo, vilket betyder "växer inuti". Den här tiden, som kallas den embryonala perioden, kännetecknas av bildandet av de flesta av kroppens system.
Från den åttonde fullbordade veckan, fram till graviditetens slut "kallas den blivande människan för foster", vilket betyder "ofödd avkomma". Under den här tiden, som kallas fosterperioden, växer kroppen sig större och organen börjar fungera.
Alla embryonal- och fosteråldrar i det här programmet beräknas sedan tidpunkten för befruktningen.
Click any superscript in the text to view footnote. Click any footnote number to view source text. Click on any author name to view the full reference in the Bibliography. Then click your browser’s back button to return to source footnote.
[1]
Gasser, 1975, 1.
[2]
Guyton and Hall, 2000, 2;
Lodish et al., 2000, 12.
[3]
Vindla and James, 1995, 598.
[4]
Cunningham et al., 2001, 226;
O’Rahilly and Müller, 2001, 92.
[5]
O’Rahilly and Müller, 1987, 9.
[6]
Spraycar, 1995, 377 & 637.
[7]
O’Rahilly and Müller, 2001, 87.
[8]
Quote from Ayto, 1990, 199.
[9]
Human development during the 8-week embryonic period has been divided into a series of 23 stages called Carnegie Stages. These stages are well described in O’Rahilly and Müller, 1987. Because human growth is unique and dependent on multiple factors, different embryos may reach a certain developmental milestone or a certain size at slightly different ages. This internationally-accepted staging system provides a way to describe development independent of age and size. Each of the 23 Carnegie Stages has specific structural features. As we describe various milestones of development, the Carnegie Stage at which they occur will be noted by a designation such as: [Carnegie Stage 2]. See Appendix B for additional information relating embryonic staging and age assignments.
[10]
Moore and Persaud, 2003, 3.
[11]
Quotes from Moore and Persaud, 2003, 3: “After the embryonic period (eight weeks), the developing human is called a fetus.“ Also see O’Rahilly and Müller, 2001, 87.
[12]
This convention, termed “postfertilization age“ by O’Rahilly, has been long preferred by embryologists. [see Mall, 1918, 400;
O’Rahilly and Müller, 1999b, 39;
O’Rahilly and Müller, 2001, 88 & 91.] Obstetricians and radiologists typically assign age based on the time elapsed since the first day of the last menstrual period prior to fertilization. This is correctly termed “postmenstrual age“ and begins 2 weeks before fertilization occurs. To summarize: postmenstrual age = postfertilization age + 2 weeks. Therefore, postmenstrual age equals approximately 2 weeks at the time of fertilization. The commonly used term “gestational age“ has been used with both age conventions and is best either avoided or carefully defined with each use.
Page 3
Biologically speaking, "human development begins at fertilization,"[13] when a woman and a man each combine 23 of their own chromosomes through the union of their reproductive cells.
A woman's reproductive cell is commonly called an "egg" but the correct term is oocyte (ō´ō-sīt).[14]
Likewise, a man's reproductive cell is widely known as a "sperm," but the preferred term is spermatozoon (sper´mă-tō-zō´on).[15]
Following the release of an oocyte from a woman's ovary in a process called ovulation (ov´yū-lā´shŭn),[16] the oocyte and spermatozoon join within one of the uterine tubes,[17] which are often referred to as Fallopian tubes.
The uterine tubes link a woman's ovaries to her uterus or womb.
The resulting single-celled embryo is called a zygote,[18] meaning "yoked or joined together."[19]
Biologiskt sett, "börjar den mänskliga utvecklingen vid befruktningen", när en kvinna och en man vardera förenar 23 av sina egna kromosomer genom sammansmältningen av sina könsceller.
En kvinnas könscell kallas vanligen ett "ägg" men den korrekta termen är oocyt.
På samma sätt kallas en manlig könscell vanligen för en "spermie" men den korrekta termen är spermatozo.
Efter att en oocyt har lossnat från kvinnans äggstock i en process som kallas ovulation, förenas oocyten och spermatozoen i en av äggledarna, vilka ofta benämns ovidukter.
Äggledarna förbinder kvinnans äggstockar med hennes uterus eller livmoder.
Det encelliga embryo som bildas kallas en zygot, vilket betyder "okad eller sammankopplad".
DNA
The zygote's 46 chromosomes[20] represent the unique first edition of a new individual's complete genetic blueprint. This master plan resides in tightly coiled molecules called DNA. They contain the instructions for the development of the entire body.
DNA molecules resemble a twisted ladder known as a double helix.[21] The rungs of the ladder are made up of paired molecules, or bases, called guanine, cytosine, adenine, and thymine.
Guanine pairs only with cytosine, and adenine with thymine.[22] Each human cell contains approximately 3 billion (3×109) base pairs.[23]
The DNA of a single cell contains so much information that if it were represented in printed words, simply listing the first letter of each base would require over 1.5 million (1.5×106) pages of text![24]
If laid end-to-end, the DNA in a single human cell measures 3⅓ feet or 1 meter.[25]
If we could uncoil all of the DNA within an adult's 100 trillion (1014) cells, it would extend over 63 billion (6.3×1010) miles. This distance reaches from the earth to the sun and back 340 times.[26]
Cell Division
Approximately 24 to 30 hours after fertilization, the zygote completes its first cell division.[27] Through the process of mitosis, one cell splits into two, two into four, and so on.[28]
Early Pregnancy Factor (EPF)
As early as 24 to 48 hours after fertilization begins, pregnancy can be confirmed by detecting a hormone called "early pregnancy factor" in the mother's blood.[29]
DNA
Zygotens 46 kromosomer utgör den unika första utgåvan av en ny individs kompletta genetiska karta. Denna generalplan finns i hårt spiralvridna molekyler som kallas DNA. De innehåller instruktioner för utvecklingen av hela kroppen.
DNA-molekyler påminner om en snurrad stege, den så kallade dubbelspiralen. Stegpinnarna består av parvisa molekyler, eller baser, som kallas guanin, cytosin, adenin och tymin.
Guanin parar endast ihop sig med cytosin, och adenin med tymin. Varje mänsklig cell innehåller ungefär tre miljarder sådana baspar.
En enda cells DNA innehåller så mycket information att om det skulle motsvaras av skrivna ord, skulle bara den första bokstaven i varje bas kräva mer än 1,5 miljoner sidor text!
Om de lades på rad, skulle DNA:n i en enda mänsklig cell räcka 3 1/3 fot eller 1 meter.
Om vi kunde räta ut all DNA i en vuxen persons 100 biljoner celler, skulle det räcka över 101 miljarder kilometer. Det avståndet räcker från jorden till solen och tillbaka 340 gånger.
Cell Division
Ungefär 24 till 30 timmar efter befruktningen, delar sig zygoten för första gången. Genom denna process, som kallas mitos, delar sig en cell i två, två celler i fyra, och så vidare.
Early Pregnancy Factor (EPF)
Så tidigt som 24 till 48 timmar efter befruktningen, kan graviditeten konstateras genom att detektera ett hormon som kallas "tidig graviditetsindikator" i moderns blod.
[13]
Quote from Moore and Persaud, 2003, 16;
From O’Rahilly and Müller, 1987, 9: “Fertilization is the procession of events that begins when a spermatozoon makes contact with an oocyte or its investments and ends with the intermingling of maternal and paternal chromosomes at metaphase of the first mitotic division of the zygote.“ See Carlson, 2004, 3;
O’Rahilly and Müller, 2001, 8. [Carnegie Stage 1]
[14]
O’Rahilly and Müller, 2001, 25: “The term ‘egg’ should be discarded from human embryology.“ From O’Rahilly and Müller, 1987, 9: “The term ‘egg’ is best reserved for a nutritive object frequently seen on the breakfast table.“
[15]
O’Rahilly and Müller, 2001, 23-24.
[16]
O’Rahilly and Müller, 2001, 30.
[17]
Dorland and Bartelmez, 1922, 372;
Gasser, 1975, 1;
Mall, 1918, 421;
O’Rahilly and Müller, 2001, 31.
[18]
Gasser, 1975, 1;
O’Rahilly and Müller, 2001, 33.
[19]
Quote from Saunders, 1970, 1;
Spraycar, 1995, 1976.
[20]
Guyton and Hall, 2000, 34.
[21]
Guyton and Hall, 2000, 24;
Watson and Crick, 1953, 737.
[22]
Guyton and Hall, 2000, 24;
Lodish et al., 2000, 103;
Watson and Crick, 1953, 737.
[23]
Lodish et al., 2000, 456.
[24]
See Appendix A.
[25]
See Appendix A;
Alberts et al., 1998, 189.
[26]
See Appendix A.
[27]
Hertig, 1968, 26;
Hertig and Rock, 1973, 130;
(cited by O’Rahilly and Müller, 1987, 12);
Shettles, 1958, 400.
[28]
Guyton and Hall, 2000, 34.
[29]
Moore and Persaud, 2003, 33 & 60;
Morton et al., 1992, 72;
Nahhas and Barnea, 1990, 105.
Page 4
By 3 to 4 days after fertilization, the dividing cells of the embryo assume a spherical shape and the embryo is called a morula (mōr´ū-lă).[30]
By 4 to 5 days, a cavity forms within this ball of cells and the embryo is then called a blastocyst.[31]
The cells inside the blastocyst are called the inner cell mass and give rise to the head, body, and other structures vital to the developing human.[32]
Cells within the inner cell mass are called embryonic stem cells because they have the ability to form each of the more than 200 cell types contained in the human body.[33]
Tre till fyra dagar efter befruktningen antar embryots delande celler en sfärisk form och embryot kallas en morula.
Vid fyra till fem dagar formas en hålighet inom detta klot av celler och embryot kallas då en blastocyt.
Cellerna inne i blastocyten kallas den inre cellmassan och ger upphov till huvud, kropp, och andra delar som den blivande människan behöver.
Cellerna i den inre cellmassan kallas embryonala stamceller eftersom de har förmågan att bilda vilken som helst av de mer än 200 celltyper som finns i människokroppen.
After traveling down the uterine tube, the early embryo embeds itself into the inner wall of the mother's uterus. This process, called implantation, begins 6 days and ends 10 to 12 days after fertilization.[34]
Cells from the growing embryo begin to produce a hormone called human chorionic gonadotropin (human kō-rē-on'ik gō'nad-ō-trō'pin), or hCG, the substance detected by most pregnancy tests.[35]
HCG directs maternal hormones to interrupt the normal menstrual cycle, allowing pregnancy to continue.[36]
Efter att ha färdats ner längs äggledaren, bäddar det tidiga embryot in sig själv i den inre väggen på moderns livmoder. Den här processen, som kallas implantation, påbörjas sex dagar och avslutas tio till toly dagar efter befruktningen.
Celler från det växande embryot börjar producera ett hormon som kallas humant choriongonadotropin, eller hCG, det ämne som detekteras i de flesta graviditetstest.
HCG skickar graviditetshormoner för att avbryta den normala menstruationscykeln och låta graviditeten fortsätta.
Following implantation, cells on the periphery of the blastocyst give rise to part of a structure called the placenta (plă-sen'tă), which serves as an interface between the maternal and embryonic circulatory systems.
The placenta delivers maternal oxygen, nutrients, hormones, and medications to the developing human; removes all waste products; and prevents maternal blood from mixing with the blood of the embryo and fetus.[37]
The placenta also produces hormones and maintains embryonic and fetal body temperature slightly above that of the mother's.[38]
The placenta communicates with the developing human through the vessels of the umbilical (ŭm-bil'i-kăl) cord.[39]
The life support capabilities of the placenta rival those of intensive care units found in modern hospitals.
Efter implantationen bildar celler i utkanten av blastocyten en del av den del som kallas moderkakan, vilken fungerar som gränsyta mellan moderns och embryots cirkulationssystem.
Moderkakan förmedlar syre, näringsämnen, hormoner, och hälsobringande ämnen från modern till den blivande människan; tar bort alla restprodukter; och förhindrar att moderns blod blandar sig med embryots och fostrets blod.
Moderkakan producerar även hormoner och håller embryots och fostrets kroppstemperatur något över moderns.
Moderkakan kommunicerar med den blivande människan genom kärlen i navelsträngen.
De livsuppehållande möjligheterna hos moderkakan motsvarar dem som finns på intensivvårdsavdelningar på moderna sjukhus.
[30]
Gasser, 1975, 1;
O’Rahilly and Müller, 2001, 37;
Spraycar, 1995, 1130: “Morula“ is derived from the Latin word morus meaning “mulberry.“ [Carnegie Stage 2]
[31]
O’Rahilly and Müller, 2001, 39. [Carnegie Stage 3]
[32]
Gasser, 1975, 1;
O’Rahilly and Müller, 2001, 39;
Sadler, 2005, 6.
[33]
Alberts et al., 1998, 32. For a discussion and definition of embryonic stem cells see the website of the National Institutes of Health: http://stemcells.nih.gov/infoCenter/stemCellBasics.asp#3
[34]
O’Rahilly and Müller, 2001, 40;
Implantation begins with attachment of the blastocyst at about 6 days after fertilization. [Attachment of the blastocyst to the inner wall of the uterus is a transient event and is the hallmark of Carnegie Stage 4.] See also Adams, 1960, 13-14;
Cunningham et al., 2001, 20;
Hamilton, 1949, 285-286;
Hertig, 1968, 41;
Hertig and Rock, 1944, 182;
Hertig and Rock, 1945, 81 & 83;
Hertig and Rock, 1949, 183;
Hertig et al., 1956, 444. [Carnegie Stage 5]
[35]
Chartier et al., 1979, 134;
Cunningham et al., 2001, 27;
O’Rahilly and Müller, 2001, 43.
[36]
Cunningham et al., 2001, 20 & 26-27;
O’Rahilly and Müller, 2001, 31.
[37]
Hertig, 1968, 16;
Cunningham et al., 2001, 86 & 136;
For a detailed description of the placenta see Hamilton and Boyd, 1960. For a detailed description of the placenta vasculature see Harris and Ramsey, 1966. This separation of maternal and fetal blood is almost but not quite perfect as a
small number of fetal cells may be found in the maternal circulation and vice-versa. See Cunningham et al., 2001, 96 & 136.
[38]
Liley, 1972, 101;
O’Rahilly and Müller, 2001, 78-79.
[39]
For a detailed description of umbilical cord formation see Florian, 1930.
Page 5
By 1 week, cells of the inner cell mass form two layers called the hypoblast and epiblast.[40]
The hypoblast gives rise to the yolk sac,[41] which is one of the structures through which the mother supplies nutrients to the early embryo.[42]
Cells from the epiblast form a membrane called the amnion (am-nē-on),[43] within which the embryo and later the fetus develop until birth.
Vid en vecka bildar cellerna i den inre cellmassan två lager, som kallas hypoblast och epiblast.
Hypoblasten ger upphov till gulesäcken, som är en av de delar genom vilken modern förser det tidiga embryot med näring.
Celler från epiblasten bildar ett membran som kallas amnion, inom vilket embryot och senare fostret utvecklas fram till födseln.
By approximately 2½ weeks, the epiblast has formed 3 specialized tissues, or germ layers, called ectoderm, endoderm, and mesoderm.[44]
Ectoderm gives rise to numerous structures including the brain, spinal cord, nerves, skin, nails, and hair.
Endoderm produces the lining of the respiratory system and digestive tract and generates portions of major organs such as the liver and pancreas.
Mesoderm forms the heart, kidneys, bones, cartilage, muscles, blood cells, and other structures.[45]
By 3 weeks the brain is dividing into 3 primary sections called the forebrain, midbrain, and hindbrain.[46]
Development of the respiratory and digestive systems is also underway.[47]
As the first blood cells appear in the yolk sac,[48] blood vessels form throughout the embryo, and the tubular heart emerges.[49]
Almost immediately, the rapidly growing heart folds in upon itself as separate chambers begin to develop.[50]
The heart begins beating 3 weeks and 1 day following fertilization.[51]
The circulatory system is the first body system, or group of related organs, to achieve a functional state.[52]
Efter ungefär 2 1/2 vecka har epiblasten bildat tre specialiserade vävnader, eller groddblad, som kallas ektoderm, endoderm och mesoderm.
Ektoderm ger upphov till många delar, däribland hjärna, ryggmärg, nerver, hud, naglar och hår.
Endoderm bildar profilen till andningsorganen och matsmältningssystemet, och bildar delar av viktiga organ, såsom levern och bukspottkörteln.
Mesoderm bildar hjärta, njurar, ben, brosk, muskler, blodkroppar och andra delar.
Vid den tredje veckan delar sig hjärnan i tre delar som kallas framhjärna, mitthjärna och bakhjärna.
Utveckling av andnings- och matsmältningssystemet pågår också.
Då de första blodkropparna framträder i gulesäcken bildas blodkärl i hela embryot, och det rörformade hjärtat framträder.
Nästan genast börjar det snabbt växande hjärtat vecka ihop sig och separata kammare börjar utvecklas.
Hjärtat börjar slå tre veckor och en dag efter befruktningen.
Cirkulationssystemet är kroppens första system, eller organgrupp, att nå funktionell nivå.
Between 3 and 4 weeks, the body plan emerges as the brain, spinal cord, and heart of the embryo are easily identified alongside the yolk sac.
Rapid growth causes folding of the relatively flat embryo.[53] This process incorporates part of the yolk sac into the lining of the digestive system and forms the chest and abdominal cavities of the developing human.[54]
Mellan den tredje och fjärde veckan framträder kroppens uppbyggnad, då embryots hjärna, ryggmärg, och hjärta lätt kan identifieras jämte gulesäcken.
Den snabba tillväxten får det relativt platta embryot att vecka sig. Den här processen innesluter delar av gulesäcken i innerkanten av matsmältningssystemet och bildar bröstet och bukhålan hos den blivande människan.
[40]
O’Rahilly and Müller, 2001, 39.
[41]
Moore and Persaud, 2003, 50;
O’Rahilly and Müller, 2001, 82. [Carnegie Stages 5 & 6];
In humans, the term “yolk sac“ has fallen out of favor among some embryologists (including O’Rahilly and Müller) because it is not a nutrient reservoir and does not contain yolk. The technically preferred term is umbilical vesicle. This structure plays a vital role in the transfer of nutrients from mother to embryo before placental circulation becomes fully functional.
[42]
Campbell et al., 1993, 756;
Kurjak et al., 1994, 437;
O’Rahilly and Müller, 2001, 82.
[43]
O’Rahilly and Müller, 1987, 29;
O’Rahilly and Müller, 2001, 43. [Carnegie Stages 4-5]
[44]
O’Rahilly and Müller, 2001, 14 & 135. [Carnegie Stage 7];
It should be noted there are many examples of organs derived from multiple germ layers. For instance, the liver is largely derived from endoderm but contains blood vessels and blood cells derived from mesoderm and nerves of ectodermal origin.
[45] Moore
and Persaud, 2003, 80 & 83; Sadler, 2005, 9.
[46]
Bartelmez, 1923, 236;
Müller and O’Rahilly, 1983, 419-420 & 429;
O’Rahilly and Gardner, 1979, 123 & 129;
O’Rahilly and Müller, 1984, 422;
O’Rahilly and Müller, 1987, 90;
O’Rahilly and Müller, 1999a, 47 & 52. [Carnegie Stage 9]
[47]
DiFiore and Wilson, 1994, 221;
Fowler et al., 1988, 793;
Grand et al., 1976, 793-794 & 796 & 798;
O’Rahilly, 1978, 125;
O’Rahilly and Boyden, 1973, 238-239;
O’Rahilly and Müller, 1984, 421;
O’Rahilly and Tucker, 1973, 6 & 8 & 23;
Streeter, 1942, 232 & 235.
[48]
Carlson, 2004, 117.
[49]
Gilmour, 1941, 28;
O’Rahilly and Müller, 1987, 86. [Carnegie Stage 9]
[50]
Campbell, 2004, 14;
Carlson, 2004, 116 & 446;
Navaratnam, 1991, 147-148;
O’Rahilly and Müller, 1987, 99. [Carnegie Stage 10]
[51]
Campbell, 2004, 14;
Carlson, 2004, 430;
De Vries and Saunders, 1962, 96;
Gardner and O’Rahilly, 1976, 583;
Gilbert-Barness and Debich-Spicer, 1997, 650;
Gittenger-de Groot et al., 2000, 17;
van Heeswijk et al., 1990, 151;
Kurjak and Chervenak, 1994, 439;
Navaratnam, 1991, 147-148;
O’Rahilly and Müller, 1987, 99;
Wisser and Dirschedl, 1994, 108. [Carnegie Stage 10, possibly late Stage 9]
[52]
Moore and Persaud, 2003, 70: “The cardiovascular system is the first organ system to reach a functional state.“
[53]
Moore and Persaud, 2003, 78.
[54]
Gasser, 1975, 26;
Moore and Persaud, 2003, 78.
Page 6
The heart typically beats about 113 times per minute.[57]
Note how the heart changes color as blood enters and leaves its chambers with each beat.
The heart will beat approximately 54 million (5.4×107) times before birth and over 3.2 billion (3.2×109) times over the course of an 80-year lifespan.[58]
Upper and lower limb development begins with the appearance of the limb buds by 4 weeks.[59]
The skin is transparent at this point because it is only one cell thick.
As the skin thickens, it will lose this transparency, which means that we will only be able to watch internal organs develop for about another month.[60]
Övre och undre extremiteter börjar utvecklas i och med utvecklingen av extremitetsutskotten vid fjärde veckan.
Huden är genomskinlig vid den här tiden eftersom den bara består av ett enda cellager.
Allteftersom huden tjocknar, kommer genomskinligheten att försvinna, vilket innebär att vi endast kommer att kunna se de inre organen utvecklas i ungefär en månad till.
Between 4 and 5 weeks, the brain continues its rapid growth and divides into five distinct sections.[61]
The head comprises about one-third of the embryo's total size.[62]
The cerebral (ser'ĕ-brăl) hemispheres appear,[63] gradually becoming the largest parts of the brain.[64]
Functions eventually controlled by the cerebral hemispheres include thought, learning, memory, speech, vision, hearing, voluntary movement, and problem-solving.[65]
Mellan den fjärde och femte veckan fortsätter hjärnan sin snabba tillväxt och delar sig i fem distinkta delar.
Huvudet upptar cirka 1/3 av embryots totala storlek.
Storhjärnshemisfärerna framträder och utvecklas gradvis till hjärnans största delar.
Funktioner som så småningom kommer att styras av storhjärnshemisfärerna är bland annat tänkande, inlärning, minne, tal, syn, hörsel, tankestyrd rörelse och problemlösning.
[55]
Gasser, 1975, 30;
O’Rahilly and Müller, 2001, 80.
[56]
O’Rahilly and Müller, 2001, 81.
[57]
van Heeswijk et al., 1990, 153.
[58]
See Appendix A.
[59]
Gasser, 1975, 49 & 59;
O’Rahilly and Gardner, 1975, 11;
O’Rahilly and Müller, 1985, 148 & 151;
O’Rahilly and Müller, 1987, 143;
Streeter, 1945, 30;
Uhthoff, 1990, 7 & 141. [upper and lower limb buds: Carnegie Stages 12 & 13]
[60]
Moore and Persaud, 2003, 486;
O’Rahilly, 1957, 459;
O’Rahilly and Müller, 2001, 165. For information about the first-trimester, direct-imaging technique used in this program (called embryoscopy), see Cullen et al., 1990.
[61]
O’Rahilly and Müller, 1999a, 134;
Sadler, 2005, 106. [Carnegie Stage 15]
[62]
Laffont, 1982, 5.
[63]
Bartelmez and Dekaban, 1962, 25;
Campbell, 2004, 17;
O’Rahilly and Gardner, 1979, 130;
O’Rahilly et al., 1984, 249;
O’Rahilly and Müller, 1999a, 115;
van Dongen and Goudie, 1980, 193. [Carnegie Stage 14]
[64]
Moore, 1980, 938.
[65]
Guyton and Hall, 2000, 663-677.
Page 7
In the respiratory system, the right and left main stem bronchi (brong'kī) are present[66] and will eventually connect the trachea (trā´kē-ă), or windpipe, with the lungs.
Note the massive liver filling the abdomen adjacent to the beating heart.
The permanent kidneys appear by 5 weeks.[67]
The yolk sac contains early reproductive cells called germ cells. By 5 weeks these germ cells migrate to the reproductive organs adjacent to the kidneys.[68]
[66]
Moore and Persaud, 2003, 245;
O’Rahilly and Boyden, 1973, 239;
O’Rahilly and Müller, 2001, 291;
Sparrow et al., 1999, 550.
[67]
Angtuaco et al., 1999, 13;
Lipschutz, 1998, 384; Moore and Persaud, 2003, 288;
O’Rahilly and Müller, 1987, 167 & 182;
O’Rahilly and Müller, 2001, 301;
Sadler, 2005, 72. [Carnegie Stage 14]
[68]
O’Rahilly and Müller, 2001, 23;
Waters and Trainer, 1996, 16;
Witschi, 1948, 70, 77 & 79.
[69]
O’Rahilly and Müller, 1987, 175;
Streeter, 1948, 139. [Carnegie Stage 15 ]
[70]
O’Rahilly and Gardner, 1975, 4. [Carnegie Stages 16 and 17 ]
Page 8
By 6 weeks the cerebral hemispheres are growing disproportionately faster than other sections of the brain.
The embryo begins to make spontaneous and reflexive movements.[71] Such movement is necessary to promote normal neuromuscular development.
A touch to the mouth area causes the embryo to reflexively withdraw its head.[72]
Vid den sjätte veckan växer storhjärnshemisfärerna oproportionerligt mycket fortare än andra delar av hjärnan.
Embryot börjar utföra spontana och reflexmässiga rörelser. Sådana rörelser är nödvändiga för att främja den normala neuromuskulära utvecklingen.
En snuddning vid munnen får embryot att reflexmässigt dra tillbaka huvudet.
The diaphragm (dī'ă-fram), the primary muscle used in breathing, is largely formed by 6 weeks.[75]
A portion of the intestine now protrudes temporarily into the umbilical cord. This normal process, called physiologic herniation (fiz-ē-ō-loj'ik her-nē-ā'shŭn), makes room for other developing organs in the abdomen.[76]
Diafragman, den viktigaste muskeln vid andningen, är i princip färdig vid den sjätte veckan.
En del av tarmarna vandrar nu tillfälligt in i navelsträngen. Denna helt normala process, som kallas fysiologisk bråckbildning, ger plats i bukhålan för andra organ att utvecklas.
[71]
Birnholz et al., 1978, 539;
de Vries et al., 1982, 301 & 304: “The first movements were observed at 7.5 weeks postmenstrual age.“ [or 5½ weeks postfertilization age];
Humphrey, 1964, 99: earliest reflex 5½ weeks;
Humphrey, 1970, 12;
Humphrey and Hooker, 1959, 76;
Humphrey and Hooker, 1961, 147;
Kurjak and Chervenak, 1994, 48;
Visser et al., 1992, 175-176: “Endogenously generated fetal movements can first be observed after 7 weeks postmenstrual age (i.e. 5 weeks after conception);“
Natsuyama, 1991, 13;
O’Rahilly and Müller, 1999a, 336: 5½ weeks postfertilization;
Sorokin and Dierker, 1982, 723 & 726;
Visser et al., 1992, 175-176;
Natsuyama, 1991, 13: Spontaneous movement observed by “Carnegie stage 15“ (about 33 days postfertilization);
Hogg, 1941, 373: Reflex activity begins at 6½ weeks [adjusted to postfertilization age].
[72]
Goodlin, 1979, D-128.
[73]
Karmody and Annino, 1995, 251;
O’Rahilly and Müller, 2001, 480;
Streeter, 1948, 190.
[74]
Kurjak and Chervenak, 1994, 19.
[75]
de Vries et al., 1982, 320.
[76]
Gilbert-Barness and Debich-Spicer, 1997, 774;
Grand et al., 1976, 798;
O’Rahilly and Müller, 1987, 213;
Sadler, 2005, 66;
Spencer, 1960, 9;
Timor-Tritsch et al., 1990, 287.
[77]
O’Rahilly and Müller, 1987, 202-203.
[78]
Borkowski and Bernstine, 1955, 363 (cited by Bernstine, 1961, 63 & 66;
O’Rahilly and Müller, 1999a, 195;
van Dongen and Goudie, 1980, 193.);
Hamlin, 1964, 113. For a summary of in utero fetal encephalography (measuring brainwaves) in the near- term fetus using abdominal and vaginal electrodes see Bernstine et al., 1955.
Page 9
Nipples appear along the sides of the trunk shortly before reaching their final location on the front of the chest.[79]
[79]
O’Rahilly and Müller, 1985, 155: “The nipple appears at stages 17 and 18.“ [41-44 days postfertilization];
Wells, 1954, 126.
[80]
O’Rahilly and Müller, 2001, 221;
Streeter, 1948, 187.
[81]
Carlson, 2004, 189;
O’Rahilly and Gardner, 1972, 293;
O’Rahilly and Gardner, 1975, 19;
O’Rahilly and Müller, 2001, 385;
Sperber, 1989, 122 & 147. [Carnegie Stage 19]
[82]
de Vries et al., 1982, 305 & 311;
Visser et al., 1992, 176.
[83]
de Vries et al., 1988, 96;
Visser et al., 1992, 176.
[84]
Cooper and O’Rahilly, 1971, 292;
James, 1970, 214; Jordaan, 1979, 214;
Streeter, 1948, 192;
Vernall, 1962, 23: “The four chambers of the heart and the associated major vessels are externally apparent in a close approximation to their adult positions.“ [Carnegie Stage 18]
[85]
van Heeswijk et al., 1990, 153.
[86]
Straus et al., 1961, 446 (cited by Gardner and O’Rahilly, 1976, 571.): “…an electrocardiogram with the classical P, QRS, and T configuration has been obtained from a 23mm human embryo (Straus, Walker, and Cohen, 1961).“
[87]
O’Rahilly and Müller, 2001, 320. [Carnegie Stage 20]
[88]
Andersen et al., 1965, 646;
O’Rahilly, 1966, 35;
O’Rahilly and Müller, 1987, 259;
Pearson, 1980, 39;
Streeter, 1951, 193. [Carnegie Stage 22] Pigment within the retina is present from about 37 days postfertilization per O’Rahilly, 1966, 25. [Carnegie Stage 16]
[89]
Streeter, 1951, 191;
reiterated by O’Rahilly and Müller, 1987, 257.
[90] O’Rahilly and Gardner, 1975, 11;
O’Rahilly and Müller, 1987, 262.
Page 10
By 8 weeks, 75 percent of embryos exhibit right-hand dominance. The remainder is equally divided between left-handed dominance and no preference. This is the earliest evidence of right- or left-handed behavior.[93]
Pediatric textbooks describe the ability to "roll over" as appearing 10 to 20 weeks after birth.[94] However, this impressive coordination is displayed much earlier in the low-gravity environment of the fluid-filled amniotic sac.[95] Only the lack of strength required to overcome the higher gravitational force outside the uterus prevents newborns from rolling over.[96]
The embryo is becoming more physically active during this time.
Motions may be slow or rapid, single or repetitive, spontaneous or reflexive.
Head rotation, neck extension, and hand-to-face contact occur more often.[97]
Touching the embryo elicits squinting, jaw movement, grasping motions, and toe pointing.[98]
Pediatriska böcker beskriver förmågan att vända sig som något som uppträder 10 till 20 veckor efter födseln. Men denna imponerande koordination visar sig mycket tidigare i den låga gravitation som finns i den vätskefyllda fostersäcken. Det är endast avsaknaden av den styrka som behövs för att övervinna den starkare gravitationskraften utanför livmodern som förhindrar nyfödda från att vända sig.
Embryot blir mer fysiskt aktiv under den här tiden.
Rörelser kan vara långsamma eller snabba, enstaka eller upprepade, spontana eller reflexmässiga.
Huvudvridningar, sträckningar på nacken, och kontakt mellan hand och ansikte förekommer oftare.
Beröring av embryot framkallar skelande, käkrörelser, griprörelser och pekanden med tårna.
Between 7 and 8 weeks, the upper and lower eyelids rapidly grow over the eyes and partially fuse together.[99]
Although there is no air in the uterus, the embryo displays intermittent breathing motions by 8 weeks.[100]
By this time, kidneys produce urine which is released into the amniotic fluid.[101]
In male embryos, the developing testes begin to produce and release testosterone (tes-tos´tĕ-rōn).[102]
Trots att det inte finns någon luft i livmodern uppvisar embryot oregelbundna andningsrörelser vid den åttonde veckan.
Vid den här tiden producerar njurarna urin som släpps ut i fostervattnet.
Hos pojkar börjar de utvecklande testiklarna att producera och avge testosteron.
The bones, joints, muscles, nerves, and blood vessels of the limbs closely resemble those in adults.[103]
By 8 weeks the epidermis, or outer skin, becomes a multi-layered membrane,[104] losing much of its transparency.
Eyebrows grow as hair appears around the mouth.[105]
Benen, lederna, musklerna, nerverna, och blodkärlen i extremiteterna liknar mycket dem som finns hos vuxna.
Vid den åttonde veckan blir epidermis, eller ytterhuden, till ett mångskiktat membran, som förlorar mycket av sin genomskinlighet.
Ögonbrynen växer, då hår framträder runt munnen.
Eight weeks marks the end of the embryonic period.
During this time, the human embryo has grown from a single cell into the nearly 1 billion (109) cells[106] which form over 4,000 (4×103) distinct anatomic structures.
The embryo now possesses more than 90 percent of the structures found in adults.[107]
Den åttonde veckan innebär slutet på den embryonala perioden.
Under den här tiden har det mänskliga embryot vuxit från en enda cell till nästan 1 miljard celler som bildar över 4000 olika anatomiska strukturer.
Embryot har nu mer än 90 % av de delar som vuxna personer har.
[91]
O’Rahilly and Müller, 1999a, 288: “The brain at [Carnegie] Stage 23 is far more advanced morphologically than is generally appreciated, to such an extent that functional considerations are imperative.“
[92]
Jordaan, 1979, 149.
[93]
Hepper et al., 1998, 531;
McCartney and Hepper, 1999, 86.
[94]
Bates, 1987, 534.
[95]
de Vries et al., 1982, 320;
Goodlin and Lowe, 1974, 348;
Humphrey, 1970, 8.
[96]
Liley, 1972, 101.
[97]
de Vries et al., 1982, 311.
[98]
Humphrey, 1964, 102;
Humphrey, 1970, 19.
[99]
Process described by Andersen et al., 1965, 648-649;
O’Rahilly, 1966, 36-37;
O’Rahilly and Müller, 1987, 261. [Carnegie Stage 23]
[100]
Connors et al., 1989, 932;
de Vries et al., 1982, 311;
McCray, 1993, 579;
Visser et al.,1992, 177.
[101]
O’Rahilly and Müller, 2001, 304;
Windle, 1940, 118; (Windle reports urine formation begins at nine weeks.)
[102]
Moore and Persaud, 2003, 307;
Waters and Trainer, 1996, 16-17.
[103]
O’Rahilly and Gardner, 1975, 15: ”By the end of the embryonic proper (Stage 23, 8 postovulatory weeks), all of the major skeletal, articular, muscular, neural, and vascular elements of the limbs are present in a form and arrangement closely resembling those of the adult.“ See O’Rahilly,
1957, for a summary of joint types and a description of limb joint development during the embryonic period. See Gray et al., 1957, for a detailed examination of the bones and joints of the hand throughout the embryonic and fetal periods.
[104]
Hogg, 1941, 407;
Pringle, 1988, 178.
[105]
Hogg, 1941, 387;
O’Rahilly and Müller, 2001, 169.
[106]
Pringle, 1988, 176.
[107]
O’Rahilly and Müller, 2001, 87: “It has been estimated that more than 90% of the more than 4500 named structures of
the adult body become apparent during the embryonic period (O’Rahilly).“
Page 11
The fetal period continues until birth.
By 9 weeks, thumb sucking begins[108] and the fetus can swallow amniotic fluid.[109]
The fetus can also grasp an object,[110] move the head forward and back, open and close the jaw, move the tongue, sigh,[111] and stretch.[112]
Nerve receptors in the face, the palms of the hands, and the soles of the feet can sense light touch.[113]
"In response to a light touch on the sole of the foot," the fetus will bend the hip and knee and may curl the toes.[114]
The eyelids are now completely closed.[115]
In the larynx, the appearance of vocal ligaments signals the onset of vocal cord development.[116]
In female fetuses, the uterus is identifiable[117] and immature reproductive cells called oogonia (ō-ō-gō′nē-ă) are replicating within the ovary.[118]
External genitalia begin to distinguish themselves as either male or female.[119]
Fosterperioden fortsätter fram till födseln.
Vid den nionde veckan börjar fostret suga på tummen och kan svälja fostervatten.
Fostret kan också gripa tag i föremål, röra huvudet fram och tillbaka, öppna och stänga käkarna, röra på tungan, sucka och sträcka på sig.
Nervreceptorer i ansiktet, handflatorna, och fotsulorna kan känna lätt beröring.
"Som reaktion på en lätt beröring på fotsulan" böjer fostret på höften och knäet och böjer eventuellt på tårna.
Ögonlocken är nu helt stängda.
I struphuvudet visar bildandet av ligamenta vocalia att stämbanden börjat bildas.
Hos flickfoster kan livmodern urskiljas och omogna könsceller, som kallas primordialägg, mångfaldigas i äggstockarna.
Yttre könsdelar börjar särskilja sig som antingen manliga eller kvinnliga.
A burst of growth between 9 and 10 weeks increases body weight by over 75 percent.[120]
By 10 weeks, stimulation of the upper eyelid causes a downward rolling of the eye.[121]
The fetus yawns and often opens and closes the mouth.[122]
Most fetuses suck the right thumb.[123]
Sections of intestine within the umbilical cord are returning to the abdominal cavity.[124]
Ossification is underway in most bones.[125]
Fingernails and toenails begin to develop.[126]
Unique fingerprints appear 10 weeks after fertilization. These patterns can be used for identification throughout life.[127]
En mycket snabb tillväxt mellan den nionde och tionde veckan ökar kroppsvikten med över 75 %.
Vid den tionde veckan orsakar retning av det övre ögonlocket att ögat vrider sig nedåt.
Fostret gäspar och öppnar och stänger munnen ofta.
De flesta foster suger på höger tumme.
Delar av tarmarna inne i navelsträngen återgår till bukhålan.
Ossifikationen pågår i de flesta ben.
Fingernaglar och tånaglar börjar utvecklas.
Unika fingeravtryck framträder tio veckor efter befruktningen. Dessa mönster kan användas för identifiering hela livet.
By 11 weeks the nose and lips are completely formed.[128] As with every other body part, their appearance will change at each stage of the human life cycle.
The intestine starts to absorb glucose and water swallowed by the fetus.[129]
Though sex is determined at fertilization, external genitalia can now be distinguished as male or female.[130]
Vid den elfte veckan är näsan och läpparna helt utvecklade. Liksom alla andra kroppsdelar kommer deras utseende att förändras vid varje etapp av den mänskliga livscykeln.
Tarmarna börjar absorbera glukos och vatten som fostret sväljer.
Även om könet avgörs vid befruktningen är det nu som de yttre könsorganen kan urskiljas som manliga eller kvinnliga.
[108]
Liley, 1972, 103.
[109]
Campbell, 2004, 24;
de Vries, 1982, 311;
Petrikovsky et al., 1995, 605.
[110]
Robinson and Tizard, 1966, 52;
Valman and Pearson, 1980, 234.
[111]
de Vries et al., 1982, 305-307.
[112]
de Vries et al., 1982, 311.
[113]
Humphrey, 1964, 96;
Humphrey, 1970, 16-17 (cited by Reinis and Goldman,
1980, 232);
Humphrey and Hooker, 1959, 77-78.
[114]
Robinson and Tizard, 1966, 52;
Quote from Valman and Pearson, 1980, 234.
[115]
Andersen et al., 1965, 648-649;
O’Rahilly and Müller, 2001,
465; Pearson, 1980, 39-41.
[116]
O’Rahilly and Müller, 1984, 425. See also Campbell, 2004, 29.
[117]
O’Rahilly, 1977a, 128;
O’Rahilly, 1977b, 53;
O’Rahilly and Müller, 2001, 327.
[118]
O’Rahilly and Müller, 2001, 25 & 322.
[119]
Campbell, 2004, 28 & 35;
O’Rahilly and Müller, 2001, 336.
[120]
Brenner et al., 1976, 561.
[121]
Goodlin, 1979, D-128;
Humphrey, 1964, 102.
[122]
de Vries et al., 1982, 309.
[123]
Hepper et al., 1991, 1109.
[124]
Grand et al., 1976, 798;
Pringle, 1988, 178;
Sadler, 2005, 66;
Spencer, 1960, 9. [Pringle reports the bowel returns into the abdomen during the ninth or tenth week.]
[125]
Cunningham et al., 2001, 133.
[126]
O’Rahilly and Müller, 2001, 170-171.
[127]
Babler, 1991, 95;
Penrose and Ohara, 1973, 201;
For an overview of ridge formation in the skin of the hands see Cummins, 1929.
[128]
Timor-Tritsch et al., 1990, 291.
[129]
Koldovský et al., 1965, 186.
[130]
O’Rahilly and Müller, 2001, 336;
Wilson, 1926, 29.
Page 12
Between 11 and 12 weeks, fetal weight increases nearly 60 percent.[131]
Twelve weeks marks the end of the first third, or trimester, of pregnancy.
Distinct taste buds now cover the inside of the mouth. By birth, taste buds will remain only on the tongue and roof of the mouth.[132]
Bowel movements begin as early as 12 weeks and continue for about 6 weeks.[133]
The material first expelled from the fetal and newborn colon is called meconium (mĭ-kō'nē-ŭm).[134] It is composed of digestive enzymes, proteins, and dead cells shed by the digestive tract.[135]
By 12 weeks, upper limb length has nearly reached its final proportion to body size. The lower limbs take longer to attain their ultimate proportions.[136]
With the exception of the back and the top of the head, the body of the entire fetus now responds to light touch.[137]
Sex-dependent developmental differences appear for the first time. For instance, female fetuses exhibit jaw movement more frequently than males.[138]
In contrast to the withdrawal response seen earlier, stimulation near the mouth now evokes a turning toward the stimulus and an opening of the mouth.[139] This response is called the "rooting reflex" and it persists after birth, helping the newborn find his or her mother's nipple during breastfeeding.[140]
The face continues to mature as fat deposits begin to fill out the cheeks[141] and tooth development begins.[142]
By 15 weeks, blood-forming stem cells arrive and multiply in the bone marrow. Most blood cell formation will occur here.[143]
Although movement begins in the 6-week embryo, a pregnant woman first senses fetal movement between 14 and 18 weeks.[144] Traditionally, this event has been called quickening.[145]
Mellan den elfte och tolfte veckan ökar fostrets vikt med nästan 60 %.
Den tolfte veckan markerar slutet på den första tredjedelen, eller trimestern, av graviditeten.
Tydliga smaklökar täcker nu munnens insida. Vid födseln kommer smaklökarna bara att finnas kvar på tungan och gommen.
Tarmrörelser börjar så tidigt som vid tolfte veckan och pågår i ungefär sex veckor.
Det som först stöts ut från fostrets och den nyföddes tjocktarm kallas barnbeck. Det består av matspjälkningsenzymer, proteiner och döda celler som stöts ut av matspjälkningssystemet.
Vid den tolfte veckan har armlängden nästan nått sin slutliga proportion till kroppsstorleken. För benen tar det längre tid att uppnå sina slutgiltiga proportioner.
Med undantag för ryggen och huvudets ovansida svarar fostrets hela kropp nu på lätt beröring.
Könsberoende skillnader i utvecklingen uppträder för första gången. Flickfoster uppvisar exempelvis oftare käkrörelser än pojkfoster.
I motsats till den reaktion som nämndes tidigare orsakar retning nära munnen nu att huvudet vänds mot retningen och att munnen öppnar sig. Denna reaktion kallas "sugreflexen" och kvarstår efter födseln, för att hjälpa den nyfödda att hitta sin mammas bröstvårta vid amning.
Ansiktet fortsätter att utvecklas då fettlager börjar fylla ut kinderna och tandutvecklingen påbörjas.
Vid den femtonde veckan framträder blodbildande stamceller som flerdubblas i benmärgen. Större delen av blodkroppsbildningen kommer att äga rum här.
Även om rörelser börjar vid sex veckor i ett embryo känner en gravid kvinna fosterrörelser först mellan fjortonde och artonde veckan. Traditionellt kallas den här händelsen sparkar.
[131]
Brenner, 1976, 561.
[132]
Lecanuet and Schaal, 1996, 3;
Miller, 1982, 169;
Mistretta and Bradley, 1975, 80.
[133]
Abramovich and Gray, 1982, 296;
Ramón y Cajal and Martinez, 2003, 154-155, report visualizing defecation (bowel movements) with ultrasound in utero in all 240 fetuses studied between 15 and 41 weeks [postmenstrual age].
[134]
O’Rahilly and Müller, 2001, 257;
For a description of meconium by Aristotle see Grand et al., 1976, 791.
[135]
Grand et al., 1976, 806.
[136]
Moore and Persaud, 2003, 105.
[137]
Lecanuet and Schaal, 1996, 2;
Reinis and Goldman, 1980, 232.
[138]
Hepper et al., 1997, 1820.
[139]
Mancia, 1981, 351.
[140]
Bates, 1979, 419.
[141]
Poissonnet et al., 1983, 7;
Poissonnet et al., 1984, 3: In a study of 488 fetuses, Poissonnet’s group found that adipose tissue (fat) appears in the face from 14 weeks postfertilization. By 15 weeks, fat appears in the abdominal wall, back, kidneys, and shoulders. By 16 weeks, fat is also present throughout the upper and lower limbs.
[142]
Pringle, 1988, 178. [Thirteenth week postfertilization]
[143]
Pringle, 1988, 179.
[144]
Sorokin and Dierker, 1982, 720;
Leader, 1995, 595: “Some pregnant women reported fetal flutters as early as 12 weeks (quickening).“ Women also tend to accurately
recognize fetal movement at earlier fetal ages during second and subsequent pregnancies as compared to first pregnancies.
[145]
Spraycar, 1995, 1479;
Timor-Tritsch et al., 1976, 70.
Page 13
By 16 weeks, procedures involving the insertion of a needle into the abdomen of the fetus trigger a hormonal stress response releasing noradrenalin, or norepinephrin (nor-ep'i-nef'rin), into the bloodstream.[146]
In the respiratory system, the bronchial tree is now nearly complete.[147]
A protective white substance, called vernix caseosa (ver'niks caseo'sa), now covers the fetus. Vernix protects the skin from the irritating effects of amniotic fluid.[148]
From 19 weeks fetal movement, breathing activity, and heart rate begin to follow daily cycles called circadian (ser-kā'dē-ăn) rhythms.[149]
Vid den sextonde veckan orsakar en införing av en nål i fostrets buk en hormonell stressreaktion som utlöser noradrenalin, eller norepinefrin, i blodet.
I andningssystemet är bronkialträdet nu nästan fullständigt.
Ett skyddande vitt ämne, som kallas vernix caseosa, täcker nu fostret. Vernix skyddar huden från att bli irriterad av fostervattnet.
Från den nittonde veckan börjar fostrets rörelser, andning och hjärtrytm följa dagliga cykler, så kallade cirkadiska rytmer.
By 20 weeks the cochlea, which is the organ of hearing, has reached adult size[150] within the fully developed inner ear. From now on, the fetus will respond to a growing range of sounds.[151]
Hair begins to grow on the scalp.
All skin layers and structures are present, including hair follicles and glands.[152]
By 21 to 22 weeks after fertilization, the lungs gain some ability to breathe air.[153] This is considered the age of viability because survival outside the womb becomes possible for some fetuses.[154]
Vid den tjugonde veckan har öronsnäckan, som utgör hörselorganet, nått vuxen storlek inne i det fullt utvecklade innerörat. Från och med nu kommer fostret att reagera på allt fler ljud.
Hår börjar växa på huvudet.
Alla hudlager och delar finns, inklusive hårsäckar och körtlar.
Mellan vecka 21 och 22 efter befruktningen får lungorna en viss förmåga att andas luft. Detta anses vara gränsen för livsduglighet eftersom det blir möjligt att överleva utanför livmodern för vissa foster.
[146]
Giannakoulopoulos et al., 1999, 494 & 498-499;
Glover and Fisk, 1999, 883;
Smith et al., 2000, 161. Cortisol levels also rise after invasive procedures following 21 weeks postfertilization - see Giannakoulopoulos et al., 1994, 80.
[147]
DiFiore and Wilson, 1994, 221-222;
Pringle, 1988, 178. [There is some disagreement among experts regarding when the bronchial tree is complete. Some say completion occurs as early as 16 weeks postfertilization while others say it occurs after birth.]
[148]
Campbell, 2004, 48;
Moore and Persaud, 2003, 107;
O’Rahilly and Müller, 2001, 168.
[149]
de Vries et al., 1987, 333;
Goodlin and Lowe, 1974, 349;
Okai et al., 1992, 391 & 396;
Romanini and Rizzo, 1995, 121;
For a description of the circadian system, see Rosenwasser, 2001, 127;
From Vitaterna et al., 2001, 92: Glossary: “Circadian: A term derived from the Latin phrase “circa diem,“ meaning “about a day;“ refers to biological variations or rhythms with a cycle of approximately 24 hours.“
[150]
Lecanuet and Schaal, 1996, 5-6;
Querleu et al., 1989, 410.
[151]
Glover and Fisk, 1999, 882;
Hepper and Shahidullah, 1994, F81;
Querleu et al., 1989, 410;
Sorokin and Dierker, 1982, 725 & 730;
Valman and Pearson, 1980, 233-234.
[152]
Pringle, 1988, 180.
[153]
Hansen and Corbet, 1998, 542.
[154]
O’Rahilly and Müller, 2001, 92, report the age of viability as 20 weeks postfertilization; Draper et al., 1999, 1094, report a survival rate of 2% at 20 weeks postfertilization, 6% at 21 weeks, and 16% at 22 weeks. Moore
and Persaud, 2003, 103, report viability at 22 weeks;
Wood et al., 2000, 379, report survival rates of 11% at 21 weeks, 26% at 22 weeks and 44% at 23 weeks (postfertilization weeks) based on premature birth data from the United Kingdom during 1995. Cooper et al. 1998, 976, (Figure 2) report infants with a birth weight over 500 grams experienced survival rates (all approximate) of 28% at 21 weeks postfertilization, 50% at 22 weeks, 67% at 23 weeks, and 77% at 24 weeks. Draper et al., 2003, updated their previously published survival tables for premature infants and now report an overall survival rate of 7% at 20 weeks, 15% at 21 weeks, 29% at 22 weeks, 47% at 23 weeks and 65% at 24 weeks. [All ages corrected to reflect postfertilization age.] These survival tables are available online at http://bmj.bmjjournals.com/cgi/content/full/319/7217/1093/DC1. Their methodology is described in their earlier paper (Draper et al., 1999, 1093-1094.) Note: These published survival tables reflect postmenstrual ages. Hoekstra et al., 2004, e3, report a survival rate of 66% at 23 weeks and 81% at 24 weeks “gestational age“ [not specifically defined] for premature births from 1996 to 2000 at their center in Minneapolis, Minnesota.
Page 14
By 24 weeks the eyelids reopen[155] and the fetus exhibits a blink-startle response.[156] This reaction to sudden, loud noises typically develops earlier in the female fetus.[157]
Several investigators report exposure to loud noise may adversely affect fetal health. Immediate consequences include prolonged increased heart rate, excessive fetal swallowing, and abrupt behavioral changes.[158] Possible long-term consequences include hearing loss.[159]
The fetal respiratory rate can rise as high as 44 inhalation-exhalation cycles per minute.[160]
During the third trimester of pregnancy, rapid brain growth consumes more than 50 percent of the energy used by the fetus. Brain weight increases between 400 and 500 percent.[161]
By 26 weeks the eyes produce tears.[162]
The pupils respond to light as early as 27 weeks.[163] This response regulates the amount of light reaching the retina[164] throughout life.
All components required for a functioning sense of smell are operational. Studies of premature babies reveal the ability to detect odors as early as 26 weeks after fertilization.[165]
Placing a sweet substance in the amniotic fluid increases the rate of fetal swallowing. In contrast, decreased fetal swallowing follows the introduction of a bitter substance. Altered facial expressions often follow.[166]
Through a series of step-like leg motions similar to walking, the fetus performs somersaults.[167]
The fetus appears less wrinkled as additional fat deposits form beneath the skin.[168] Fat plays a vital role in maintaining body temperature and storing energy after birth.
Vid vecka 24 öppnas ögonlocken igen och fostret reagerar med att blinka. Denna reaktion på plötsliga, höga ljud utvecklas vanligen tidigare hos flickfoster.
Flera forskare rapporterar att exponering för höga ljud kan försämra fostrets hälsa. Omedelbara effekter omfattar långvarigt ökad hjärtfrekvens, omfattande sväljningar, och abrupta ändringar i beteendet. Möjliga långtidseffekter omfattar försämrad hörsel.
Fostrets andningsfrekvens kan öka till så mycket som 44 cykler av inandning och utandning per minut.
Under den tredje trimestern av graviditeten kräver den snabba hjärntillväxten mer än 50 % av den energi som fostret förbrukar. Hjärnans vikt ökar med mellan 400 och 500 %.
Vid vecka 26 producerar ögonen tårar.
Pupillerna reagerar på ljus så tidigt som vid vecka 27. Denna reaktion reglerar vilken ljusmängd som når näthinnan genom hela livet.
Alla delar som behövs för ett fungerande luktsinne fungerar. Studier av för tidigt födda barn visar på förmågan att uppfatta dofter så tidigt som 26 veckor efter befruktningen.
Ett sött ämne som tillförs fostervattnet får fostret att svälja oftare. Däremot minskar antalet sväljningar om ett beskt ämne tillsätts. Ofta följer ändrade ansiktsuttryck.
Genom en serie stegliknande benrörelser som liknar gångrörelser, gör fostret kullerbyttor.
Fostret ser mindre skrynkligt ut allt eftersom mer fett lagras under huden. Fett spelar en avgörande roll i att hålla kroppstemperaturen och lagra energi efter födseln.
[155]
Open eyes are visualized by 4D ultrasound following 22 weeks postfertilization per Campbell 2002, 3; De Lia, 2002, personal communication;
O’Rahilly and Müller, 2001, 465. For a detailed ultrastructural study of the union between the upper and lower eyelids see Andersen et al., 1967, 293.
[156]
Birnholz and Benacerraf, 1983, 517 (cited by Drife, 1985, 778);
See also Campbell, 2002, 3: Professor Stuart Campbell correctly points out that the eyes of the fetus are closed most of the time and a true blink requires the eyes to be open. Perhaps the “blink-startle“ response would be more accurately termed “squint-startle.“
[157]
Lecanuet and Schaal, 1996, 9.
[158]
Visser et al., 1989, 285.
[159]
Gerhardt, 1990, 299;
Petrikovsky et al., 1993, 548-549;
Pierson, 1996, 21 & 26.
[160]
Natale et al., 1988, 317.
[161]
Growth of the human brain, 1975, 6;
Mancuso and Palla, 1996, 290.
[162]
Isenberg et al., 1998, 773-774.
[163]
Robinson and Tizard, 1966, 52.
[164]
Noback et al., 1996, 263.
[165]
Lecanuet and Schaal, 1996, 3.
[166]
Lecanuet and Schaal, 1996, 3;
Liley, 1972, 102;
Moore and Persaud, 2003, 219;
Reinis and Goldman, 1980, 227.
[167]
Liley, 1972, 100.
[168]
England, 1983, 29.
Page 15
By 28 weeks the fetus can distinguish between high- and low-pitched sounds.[169]
By 30 weeks, breathing movements are more common and occur 30 to 40 percent of the time in an average fetus.[170]
During the last 4 months of pregnancy, the fetus displays periods of coordinated activity punctuated by periods of rest. These behavioral states reflect the ever-increasing complexity of the central nervous system.[171]
Vid vecka 28 kan fostret skilja mellan hög- och lågfrekventa ljud.
Vid vecka 30 är andningsrörelser vanligare och förekommer 30 till 40 % av tiden hos ett genomsnittligt foster.
Under de sista fyra månaderna av graviditeten uppvisar fostret stunder av koordinerad aktivitet avbrutna av stunder av vila. Detta beteendemönster speglar den allt ökande komplexiteten hos det centrala nervsystemet.
By approximately 32 weeks, true alveoli (al-vē'ō-lī), or air "pocket" cells, begin developing in the lungs. They will continue to form until 8 years after birth.[172]
At 35 weeks the fetus has a firm hand grasp.[173]
Fetal exposure to various substances appears to affect flavor preferences after birth. For instance, fetuses whose mothers consumed anise, a substance which gives licorice its taste, showed a preference for anise after birth. Newborns without fetal exposure disliked anise.[174]
Vid ungefär vecka 32 börjar riktiga alveoler, eller lungblåsor, utvecklas i lungorna. De kommer att fortsätta att utvecklas fram till åtta år efter födseln.
Vid vecka 35 kan fostret gripa ordentligt.
Vilka ämnen fostret utsätts för tycks påverka smakpreferenserna efter födseln. Foster vars mödrar åt anis, en produkt som ger lakritsen dess smak, uppvisade exempelvis en preferens för anis efter födseln. Nyfödda som inte exponerats under fosterperioden ogillade anis.
The fetus initiates labor[175] by releasing large amounts of a hormone called estrogen (es´trō-jen)[176] and thus begins the transition from fetus to newborn.
Labor is marked by powerful contractions of the uterus, resulting in childbirth.[177]
From fertilization to birth and beyond, human development is dynamic, continuous, and complex. New discoveries about this fascinating process increasingly show the vital impact of fetal development on lifelong health.
As our understanding of early human development advances, so too will our ability to enhance health––both before and after birth.
Fostret initierar värkar genom att frigöra stora mängder av ett hormon kallat östrogen och påbörjar på så sätt övergången från foster till nyfödd.
Värkarna kännetecknas av kraftiga sammandragningar i livmodern, vilket resulterar i förlossningen.
Från befruktningen till födsel och därefter är den mänskliga utvecklingen dynamisk, fortgående, och komplex. Nya upptäckter kring denna fascinerande process visar alltmer den stora betydelse fosterutvecklingen har på hälsan under hela livet.
Allt eftersom vår förståelse för den tidiga mänskliga utvecklingen förbättras, så ökar också våra möjligheter att förbättra hälsan - både före och efter födseln.
[169]
Glover and Fisk, 1999, 882;
Hepper and Shahidullah, 1994, F81.
[170]
Connors et al., 1989, 932;
de Vries et al., 1985, 117;
Patrick et al., 1980, 26 & 28;
Visser et al., 1992, 178.
[171]
DiPietro et al., 2002, 2: “One of the hallmarks of development before birth is the coalescence of patterns of fetal and behavioral and cardiac function into behavioral states, which is widely viewed as reflective of the developing integration of the central nervous system.“
[172]
Lauria et al., 1995, 467.
[173]
Moore and Persaud, 2003, 108.
[174]
Schaal et al., 2000, 729.
[175]
Liley, 1972, 100.
[176]
Moore and Persaud, 2003, 131.
[177]
Cunningham et al., 2001, 252.
Page 16
Given:
1. The DNA molecule measures 3.4×10-9 meters per 10 base pairs.[178]
2. There are 3 billion (3×109) base pairs per cell.
3. There are an estimated 100 trillion (1014) cells per adult.
4. The distance from the earth to the sun is approximately 93 million miles.
5. There are 2.54 centimeters (cm) per inch.
Step 1 Compute the length of DNA in a single cell:
3.4×10-9 meters/10 base pairs × 3×109 base pairs/cell = 1.02 meters of DNA per cell
Step 2 Compute the total length of DNA in an adult’s 100 trillion cells:
1.02 meters of DNA/cell × 1014 cells = 1.02×1014 meters of DNA per adult*
Step 3 Convert 1.02×1014 meters to miles:
1.02×1014 meters × 100 cm/meter × 1inch/2.54 cm × 1 foot/12 inches × 1 mile/5,280 feet
= 6.3379×1010miles of DNA
Step 4 Compute how many round trips from the earth to the sun:
6.3379×1010 miles of DNA ÷ (93,000,000 miles/trip × 2 trips/round trip) =
Therefore, the DNA in a single adult, if oriented in linear fashion, would exceed 63 billion miles in length. This is long enough to extend from the earth to the sun and back––340 times.
* Approximately 25 trillion red blood cells are present in the adult.[179] It should be noted that red blood cells contain DNA early in their maturation phase but this DNA degenerates and is not present in the mature form. This calculation includes the DNA from red blood cells.
[178]
Lodish et al., 2000, 104.
[179]
Guyton and Hall, 2000, 2.
Page 17
The following page contains a list of 3,808 capital letters each of which represents a single base.
Given:
1. A, G, T, and C each represent a base within the DNA of a single cell.
2. Each line contains 68 letters without spaces representing 68 bases.
3. Each page contains 56 lines. (Page size: 8½ × 11 inches, font: Times New Roman, font size: 10, spaces between letters: none, lines: single spaced, margins: as shown)
4. Each cell contains 3 billion base pairs equaling 6 billion bases.
The calculation of the number of pages required to list all DNA bases in a single cell is as follows:
68 bases/line × 56 lines/page = 3,808 bases/page
6,000,000,000 bases/cell ÷ 3,808 bases/page = 1,575,630 pages/cell
Page 18
Given:
1. The placenta maintains embryonic and fetal temperature between 0.5 ºC and 1.5 ºC above maternal core temperature.[180]
2. Maternal core temperature is approximately 99.6º Fahrenheit.
3. The formula to convert temperature from Fahrenheit (ºF) to Celsius (ºC) is:
ºC = 5/9 (ºF - 32)
The calculation to compute the range of embryonic and fetal body temperature is as follows:
Step 1 Convert maternal core temperature to Celsius:
Maternal core temperature in ºC: ºC = 5/9 (99.6 - 32) = 37.56 ºC
Step 2 Compute lower and upper ranges of fetal body temperature in Celsius:
Lower range (Celsius) = maternal core temperature + 0.5 ºC = 37.56 + 0.5 = 38.2 ºC
Upper range (Celsius) = maternal core temperature + 1.5 ºC = 37.56 + 1.5 = 39.2 ºC
Step 3 Convert results to Fahrenheit:
ºC = 5/9 (ºF - 32) 9/5 ºC = (ºF - 32) ºF = 9/5 ºC + 32
Substituting to find the lower limit of fetal body temperature
ºF = 9/5 ºC + 32 ºF = 9/5 (38.16) + 32 ºF = 100.7º
Substituting to find the upper limit of fetal body temperature
ºF = 9/5 ºC + 32 ºF = 9/5 (39.16) + 32 ºF = 102.5º
Summary of Normal Embryonic and Fetal Body Temperature Range
ºF | ºC | |
---|---|---|
Lower Limit | 100.7 | 38.2 |
Upper Limit | 102.5 | 39.2 |
Page 19
The Embryonic Period
Various authors agree the heart rate peaks at 7 weeks. Reported heart rates vary however. Van Heeswijk et al. report a peak heart rate of 167 ± 8 beats per minute (bpm)[181] while Leeuwen et al. report a peak rate of 175 bpm.[182] Van Lith et al. report the median fetal heart rate peaks at 177 bpm at 7 weeks.[183] One hundred seventy (170) bpm has been chosen as the peak heart rate for illustration purposes in this calculation. The heart rate for the various weeks from 7 through 38 have been calculated via linear interpolations[184] assuming heart rates of 170 bpm at 7 weeks and 140 bpm at term or 38 weeks.[185]
(Note: Heart rates are estimated. Living conditions and individual experience can and will vary.)
The Fetal Period
Week # | Average Heart Rate (Beats per Minute) |
Beats per Week | Running Total |
---|---|---|---|
9 | 168.06 | 1,694,090 | 9,103,216 |
10 | 167.10 | 1,684,336 | 10,787,551 |
11 | 166.13 | 1,674,581 | 12,462,132 |
12 | 165.16 | 1,664,826 | 14,126,958 |
13 | 164.19 | 1,655,071 | 15,782,029 |
14 | 163.23 | 1,645,316 | 17,427,346 |
15 | 162.26 | 1,635,562 | 19,062,907 |
16 | 161.29 | 1,625,807 | 20,688,714 |
17 | 160.32 | 1,616,052 | 22,304,766 |
18 | 159.35 | 1,606,297 | 23,911,063 |
19 | 158.39 | 1,596,542 | 25,507,605 |
20 | 157.42 | 1,586,787 | 27,094,393 |
21 | 156.45 | 1,577,033 | 28,671,425 |
22 | 155.48 | 1,567,278 | 30,238,703 |
23 | 154.52 | 1,557,523 | 31,796,226 |
24 | 153.55 | 1,547,768 | 33,343,994 |
25 | 152.58 | 1,538,013 | 34,882,008 |
26 | 151.61 | 1,528,259 | 36,410,266 |
27 | 150.65 | 1,518,504 | 37,928,770 |
28 | 149.68 | 1,508,749 | 39,437,519 |
29 | 148.71 | 1,498,994 | 40,936,513 |
30 | 147.74 | 1,489,239 | 42,425,752 |
31 | 146.77 | 1,479,484 | 43,905,237 |
32 | 145.81 | 1,469,730 | 45,374,966 |
33 | 144.84 | 1,459,975 | 46,834,941 |
34 | 143.87 | 1,450,220 | 48,285,161 |
35 | 142.90 | 1,440,465 | 49,725,626 |
36 | 141.94 | 1,430,710 | 51,156,337 |
37 | 140.97 | 1,420,956 | 52,577,292 |
38 | 140.00 | 1,411,201 | 53,988,493 |
(Approximately 54 million beats before birth) |
Counting the Beats of a Lifetime
The Postnatal Period from Birth to 80 Years
Year # | Average Heart Rate (Beats per Minute)*[186] |
Beats per Year | Running Total |
---|---|---|---|
1 | 120 | 63,115,200 | 63,115,200 |
2 | 110 | 57,855,600 | 120,970,800 |
3 | 103 | 54,173,880 | 175,144,680 |
4 | 103 | 54,173,880 | 229,318,560 |
5 | 103 | 54,173,880 | 283,492,440 |
6 | 103 | 54,173,880 | 337,666,320 |
7 | 95 | 49,966,200 | 387,632,520 |
8 | 95 | 49,966,200 | 437,598,720 |
9 | 95 | 49,966,200 | 487,564,920 |
10 | 95 | 49,966,200 | 537,531,120 |
11 | 85 | 44,706,600 | 582,237,720 |
12 | 85 | 44,706,600 | 626,944,320 |
13 | 85 | 44,706,600 | 671,650,920 |
14 | 85 | 44,706,600 | 716,357,520 |
15 | 80 | 42,076,800 | 758,434,320 |
16 | 80 | 42,076,800 | 800,511,120 |
17 | 75 | 39,447,000 | 839,958,120 |
18 | 75 | 39,447,000 | 879,405,120 |
19 | 70 | 36,817,200 | 916,222,320 |
20 | 70 | 36,817,200 | 953,039,520 |
21-80 | 70 | 2,209,032,000 | 3,162,071,520 |
(Approximately 3.16 billion beats from birth to age 80 years) | |||
Estimated Total Heart Beats From the 3-Week Embryo to Age 80 Years |
3,216,060,000 | ||
(Approximately 3.2 Billion Beats Per Lifetime) |
[181]
van Heeswijk et al., 1990, 153.
[182]
Leeuwen et al., 1999, 265.
[183]
van Lith et al., 1992, 741.
[184]
See Appendix A.
[185]
DiPietro et al., 1996, 2559.
[186]
Age appropriate pediatric heart rates adapted from Bates, 1987, 541.
Page 20
O'Rahilly and Müller's Age Assignments vs. Carnegie Stages, 1987 to 2001
Carnegie Stage |
Number of Somites |
Greatest Length (mm) |
1987 Age [187] Convention (in PF Days*) |
1999 Age [188] Convention (in PF Days*) |
2001 Age [189] Convention (in PF Days*) |
---|---|---|---|---|---|
1 | 0.1 - 0.15 | 1 | - | 1 | |
2 | 0.1 - 0.2 | 1½ - 3 | 2 - 3 | 2 - 3 | |
3 | 0.1 - 0.2 | 4 | 4 - 5 | 4 - 5 | |
4 | 0.1 - 0.2 | 5 - 6 | 6 | 6 | |
5 | 0.1 - 0.2 | 7 - 12 | 7 - 12 | - | |
5a | 0.1 | 7 - 8 | - | 7 - 8 | |
5b | 0.1 | 9 | - | 9 | |
5c | 0.15 - 0.2 | 11 - 12 | - | 11 - 12 | |
6 | 0.2 | 13 | 17 | 17 | |
6a | - | - | - | - | |
6b | - | - | - | - | |
7 | 0.4 | 16 | 19 | 19 | |
8 | 1.0 - 1.5 | 18 | 23 | - | |
8a | - | - | - | 23 | |
8b | - | - | - | 23 | |
9 | 1-3 | 1.5 - 2.5 | 20 | 26 | 25 |
10 | 4-12 | 2 - 3.5 | 22 | 29 | 28 |
11 | 13-20 | 2.5 - 4.5 | 24 | 30 | 29 |
12 | 21-29 | 3 - 5 | 26 | 31 | 30 |
13 | 30+ | 4 - 6 | 28 | 32 | 32 |
14 | 5 - 7 | 32 | 33 | 33 | |
15 | 7 - 9 | 33 | 35 | 36 | |
16 | 8 - 11 | 37 | 37 | 38 | |
17 | 11 - 14 | 41 | 40 | 41 | |
18 | 13 - 17 | 44 | 42 | 44 | |
19 | 16 - 18 | 47½ | 44 | 46 | |
20 | 18 - 22 | 50½ | 47 | 49 | |
21 | 22 - 24 | 52 | 50 | 51 | |
22 | 23 - 28 | 54 | 52 | 53 | |
23 | 27 - 31 | 56½ | 56 | 56 |
* PF Days = Postfertilization Days
There is international agreement among embryologists that human development during the embryonic period be divided into 23 stages (which were initially proposed by Mall, described by Streeter, and amended by O'Rahilly and Müller in 1987).[190] These have come to be known as Carnegie Stages. Particular internal and external features are required for inclusion in any given embryonic stage. These stages are independent of age and length and the use of the term 'stage' should be reserved for reference to this system per O'Rahilly and Müller in multiple publications.
Along with nearly-universal acceptance of the human embryonic staging system, a variety of age assignments have been proposed for each embryonic stage. Streeter believed the embryonic period spanned a 47- to 48-day period instead of the 56-day period accepted today. The Endowment for Human Development adopts the convention set forth by O'Rahilly and Müller in 1987 which has received widespread, but not universal, acceptance. O'Rahilly and Müller have since proposed amending this convention in light of transvaginal ultrasound data through a personal communication with Dr. Josef Wisser in 1992.[191] These alternate proposals are provided for the interested reader.
For instance, the onset of embryonic cardiac contraction (onset of the heartbeat) has long been described as a Carnegie Stage 10 or possibly a late Stage 9 event.[192] We report this event occurring at an age of 3 weeks, 1 day (22 days) postfertilization using the 1987 convention. Others may report this occurrence at 28 or 29 days as shown above. Of interest is a paper by Wisser and Dirschedl who reported using transvaginal ultrasound to visualize the embryonic heartbeat 23 days postfertilization in two embryos fertilized in vitro “with exactly known … age” and “in embryos from 2 mm of greatest length onwards.”[193] This finding most closely coincides with the 1987 age convention. Schats et al. reported the earliest cardiac activity at 25 days after follicle aspiration in embryos conceived in vitro.[194] Tezuka et al. reported the earliest cardiac activity at 23 days postfertilization in embryos conceived naturally.[195]
There is considerable variation in normal human development during the postnatal period. The prenatal period is no different with variations in the size, rate of growth, and order of appearance of some structures or functions. No one knows the exact age range for each stage with absolute certainty. These approximations may change in the future as additional knowledge is gained through careful, published research.
[187]
O'Rahilly and Müller, 1987, 3. Greatest length data is essentially uniform throughout the various texts.
[188]
O'Rahilly and Müller, 1999a. Various pages.
[189]
O'Rahilly and Müller, 2001, 490. Table A-1 – essentially unchanged from the 1996 edition. The 2001 convention
differs only slightly from the 1999 convention as shown.
[190]
O'Rahilly and Müller, 2001, 3.
[191]
O'Rahilly and Müller, 1999a, 13.
[192]
See footnote #51.
[193]
Quotes from Wisser and Dirschedl, 1994, 108.
[194]
Schats et al., 1990, 989.
[195]
Tezuka, 1991, 211.
Page 21
Abramovich D, Gray E. 1982. Physiological fetal defecation in midpregnancy. Obstet Gynecol. 60(3):294-296.
Adams WE. 1960. Early human development. N Z Med J. 59:7-17.
Alberts B, Bray D, Johnson A, Lewis J, Raff M, Roberts K, Walter P. 1998. Essential cell biology. New York: Garland.
Andersen H, Ehlers N, Matthiessen ME. 1965. Histochemistry and development of the human eyelids. Acta Opthalmol. 43(5):642-668.
Andersen H, Ehlers N, Matthiessen ME, Claesson MH. 1967. Histochemistry and development of the human eyelids II. Acta Opthalmol. 45(3):288-293.
Angtuaco TL, Collins HB, Quirk JG. 1999. The fetal genitourinary tract. Semin Roentgenol. 34(1):13-28.
Ayto J. 1990. Dictionary of word origins. New York: Arcade.
Babler WJ. 1991. Embryologic development of epidermal ridges and their configurations. In: Plato CC, Garruto RM, Schaumann BA, editors. Dermatoglyphics: science in transition. New York: Wiley-Liss; p. 95-112.
Bartelmez GW. 1923. The subdivisions of the neural folds in man. J Comp Neurol. 35(3):231-247.
Bartelmez GW, Dekaban AS. 1962. The early development of the human brain. Carnegie Institution of Washington. Contrib Embryol. 35:13-32.
Bates B. 1979. A guide to physical examination. 2nd ed. Philadelphia: J.B. Lippincott.
Bates B. 1987. A guide to physical examination. 4th ed. Philadelphia: J.B. Lippincott.
Bernstine RL. 1961. Fetal electrocardiography and electroencephalography. Springfield: Charles C. Thomas.
Bernstine RL, Borkowski WJ, Price AH. 1955. Prenatal fetal electroencephalography. Am J Obstet Gynecol. 70(3):623-30.
Birnholz JC, Stephens JC, Faria M. 1978. Fetal movement patterns: a possible means of defining neurologic developmental milestones in utero. Am J Roentgenol. 130(3):537-540.
Birnholz JC, Benacerraf BR. 1983. The development of human fetal hearing. Science. 222(4623):516-518.
Borkowski WJ, Bernstine RL. 1955. Electroencephalography of the fetus. Neurology. 5(5):362-365.
Brenner WE, Edelman DA, Hendricks CH. 1976. A standard of fetal growth for the United States of America. Am J Obstet Gynecol. 126(5):555-564.
Campbell J, Wathen N, Perry G, Soneji S, Sourial N, Chard T. 1993. The coelomic cavity: an important site of materno-fetal nutrient exchange in the first trimester of pregnancy. Br J Obstet Gynaecol. 100(8):765-767.
Campbell S. 2002. 4D, or not 4D: that is the question. Ultrasound Obstet Gynecol. 19(1):1-4.
Campbell S. 2004. Watch me grow: A unique 3-dimensional week-by-week look at your baby’s behavior and development in the womb. New York: St. Martins.
Carlson BM. 2004. Human embryology & developmental biology. 3rd ed. Philadelphia: Mosby.
Chartier M, Roger M, Barrat J, Michelon B. 1979. Measurement of plasma human chorionic gonadotropin (hCG) and ß-hCG activities in the late luteal phase: evidence of the occurrence of spontaneous menstrual abortions in infertile women. Fertil Steril. 31(2):134-137.
Connors G, Hunse C, Carmichael L, Natale R, Richardson B. 1989. Control of fetal breathing in the human fetus between 24 and 34 weeks' gestation. Am J Obstet Gynecol. 160(4):932-938.
Cooper M, O'Rahilly R. 1971. The human heart at seven postovulatory weeks. Acta Anat. 79(2):280-299.
Cooper TR, Berseth CL, Adams JM, Weisman LE. 1998. Actuarial survival in the premature infant less than 30 weeks' gestation. Pediatrics. 101(6):975-978.
Cullen MT, Reece EA, Whetham J, Hobbins JC. 1990. Embryoscopy: description and utility of a new technique. Am J Obstet Gynecol. 162:82-86.
Cummins H. 1929. The topographic history of the volar pads (walking pads; tasballen) in the human embryo. Carnegie Institution of Washington. Contrib Embryol. 20:103-126.
Cunningham FG, Gant NF, Leveno KJ, Gilstrap LC, Hauth JC, Wenstrom KD, editors. 2001. Williams Obstetrics. 21st ed. New York: McGraw-Hill.
Page 22
De Lia, Julian E., M.D. Medical Director of International Institute for the Treatment of Twin to Twin Transfusion Syndrome, personal communication, November 2002.
de Vries JIP, Visser GHA, Prechtl HFR. 1982. The emergence of fetal behaviour. I. Qualitative aspects. Early Hum Dev. 7(4):301-322.
de Vries JIP, Visser GHA, Prechtl HFR. 1985. The emergence of fetal behaviour. II. Quantitative aspects. Early Hum Dev. 12(2):99-120.
de Vries JIP, Visser GHA, Prechtl HFR. 1988. The emergence of fetal behaviour. III. Individual differences and consistencies. Early Hum Dev. 16(1):85-103.
de Vries JIP, Visser GHA, Mulder EJH, Prechtl HFR. 1987. Diurnal and other variations in fetal movement and heart rate patterns at 20-22 weeks. Early Hum Dev. 15(6):333-348.
de Vries PA, Saunders JB. 1962. Development of the ventricles and spiral outflow tract in the human heart. Carnegie Institution of Washington. Contrib Embryol. 37:87-114.
DiFiore JW, Wilson JM. 1994. Lung development. Semin Pediatr Surg. 3(4):221-232.
DiPietro JA, Costigan KA, Pressman EK. 2002. Fetal state concordance predicts infant state regulation. Early Hum Dev. 68(1):1-13.
DiPietro JA, Hodgson DM, Costigan KA, Hilton SC. 1996. Fetal neurobehavioral development. Child Dev. 67(5):2553-2567.
Dorland WAN, Bartelmez GW. 1922. Clinical and embryological report of an extremely early tubal pregnancy; together with a study of decidual reaction, intra-uterine and ectopic. II. Am J Obstet Gynecol. 4(3):372-386.
Drife JO. 1985. Can the fetus listen and learn? Br J Obstet Gynaecol. 92(8):777-778.
Draper ES, Manktelow B, Field DJ, James D. 1999. Prediction of survival for preterm births by weight and gestational age: retrospective population based study. Br Med J. 391(7217):1093-97.
Draper ES, Manktelow B, Field DJ, James D. 2003. Prediction of survival for preterm births. Br Med J.; 327(7419):872. [Full text article available from: http://bmj.bmjjournals.com/cgi/eletters/319/7217/1093/DC1#37045; Survival tables available from: http://bmj.bmjjournals.com/cgi/content/full/319/7217/1093/DC1. [cited 2004 Feb 2]
England MA. 1983. Color atlas of life before birth, normal fetal development. Chicago: Year Book Medical.
Fowler CL, Pokorny WJ, Wagner ML, Kessler MS. 1988. Review of bronchopulmonary foregut malformations. J Pediatr Surg. 23(9):793-797.
Florian J. 1930. The formation of the connecting stalk and the extension of the amniotic cavity towards the tissue of the connecting stalk in young human embryos. J Anat. 64:454-476.
Gardner E, O'Rahilly R. 1976. The nerve supply and conducting system of the human heart at the end of the embryonic period proper. J Anat. 121(3):571-587.
Gasser RF. 1975. Atlas of human embryos. Maryland: Harper & Row.
Gerhardt KJ. 1990. Prenatal and perinatal risks of hearing loss. Semin Perinatol. 14(4):299-304.
Giannakoulopoulos X, Sepulveda W, Kourtis P, Glover V, Fisk NM. 1994. Fetal plasma cortisol and β-endorphin response to intrauterine needling. Lancet. 344(8915):77-81.
Giannakoulopoulos X, Teixeira J, Fisk N, Glover V. 1999. Human fetal and maternal noradrenaline responses to invasive procedures. Pediatr Res. 45(4 Pt 1):494-499.
Gilbert-Barness E, Debich-Spicer D. 1997. Cardiovascular system. In: Gilbert-Barness, editor. Potter's Pathology of the Fetus and Infant. Vol 1. St. Louis: Mosby.
Gilmour JR. 1941. Normal haemopoiesis in intra-uterine and neonatal life. J Pathol Bacteriol. 52:25-55.
Gittenger-de Groot AC, Bartelings MM, Poelmann RE. 2000. Normal and abnormal cardiac development. In: Allan L, Hornberger LK, Sharland G, editors. Textbook of fetal cardiology. London: Greenwich Medical Media Limited; p. 15-27.
Glover V, Fisk N. 1999. Fetal pain: implications for research and practice. Br J Obstet Gynaecol. 106(9):881-886.
Goodlin RC. 1979. Care of the fetus. New York: Masson.
Goodlin RC, Lowe EW. 1974. Multiphasic fetal monitoring, a preliminary evaluation. Am J Obstet Gynecol. 119(3):341-357.
Grand RJ, Watkins JB, Torti FM. 1976. Development of the human gastrointestinal tract. A review. Gastroenterology. 70(5 Pt. 1):790-810.
Gray DJ, Gardner E, O'Rahilly R. 1957. The prenatal development of the skeleton and joints of the human hand. Am J Anat. 101(2):169-223.
Growth of the human brain: some further insights. 1975. Nutr Rev. 33(1):6-7.
Guyton AC, Hall JE. 2000. Textbook of medical physiology. 10th ed. Philadelphia: W.B. Saunders.
Page 23
Hamilton WJ. 1949. Early stages of human development. Ann R Coll Surg Eng. 4:281-294.
Hamilton WJ, Boyd JD. 1960. Development of the human placenta in the first three months of gestation. J Anat. 94:297-328.
Hamlin H. 1964. Life or death by EEG. JAMA. 90(2):112-114.
Hansen T, Corbet A. 1998. Lung development and function. In: Taeusch HW, Ballard RA, Fletcher J, editors. Avery's diseases of the newborn. W.B. Saunders; p. 541-542.
Harris JWS, Ramsey EM. 1966. The morphology of human uteroplacental vasculature. Carnegie Institution of Washington. Contrib Embryol. 38:43-58.
Hepper PG, Shahidullah BS. 1994. Development of fetal hearing. Arch Dis Child. 71(2):F81-F87.
Hepper PG, Shahidullah S, White R. 1991. Handedness in the human fetus. Neuropsychologia. 29(11):1107-1111.
Hepper PG, Shannon EA, Dornan JC. 1997. Sex differences in fetal mouth movements. Lancet. 350(9094):1820-1821.
Hepper PG, McCartney GR, Shannon EA. 1998. Lateralised behavior in first trimester human foetuses. Neuropsychologia. 36(6):531-534.
Hertig AT, Rock J. 1944. On the development of the early human ovum, with special reference to the trophoblast of the pre-villous stage: a description of 7 normal and 5 pathologic human ova. Am J Obstet Gynecol. 47(2):149-184.
Hertig AT, Rock J. 1945. Two human ova of the pre-villous stage, having a developmental age of about seven and nine days respectively. Carnegie Institution of Washington. Contrib Embryol. 200:67-84.
Hertig AT, Rock J. 1949. Two human ova of the pre-villous stage, having a developmental age of about eight and nine days respectively. Carnegie Institution of Washington. Contrib Embryol. 221:171-186.
Hertig AT, Rock J. 1973. Searching for early fertilized human ova. Gynecol Invest. 4:121-139.
Hertig AT, Rock J, Adams EC. 1956. A description of 34 human ova within the first 17 days of development. Am J Anat. 98(3):435-493.
Hertig AT. 1968. Human trophoblast. Springfield: Thomas.
Hoekstra RE, Ferrara B, Couser RJ, Payne NR, Connett JE. 2004. Survival and long-term neurodevelopmental outcome of extremely premature infants born at 23–26 weeks' gestational age at a tertiary center. Pediatrics. 113(1 Pt 1):e1-e6.
Hogg ID. 1941. Sensory nerves and associated structures in the skin of human fetuses of 8 to 14 weeks of menstrual age correlated with functional capability. J Comp Neur. 75:371-410.
Humphrey T. 1964. Growth and maturation of the brain - some correlations between the appearance of human fetal reflexes and the development of the nervous system. In: Dominick P, Purpura DP, Schadé JP, editors. Progress in brain research, Vol 4. Amsterdam: Elsevier; p. 93-135.
Humphrey T. 1970. The development of human fetal activity and its relation to postnatal behavior. Advances in child development and behavior, Vol 5. Reese HW, Lipsitt LP, editors. New York: Academic.
Humphrey T, Hooker D. 1959. Double simultaneous stimulation of human fetuses and the anatomical patterns underlying the reflexes elicited. J Comp Neurol. 112:75-102.
Humphrey T, Hooker D. 1961. Reflexes elicited by stimulating perineal and adjacent areas of human fetuses. Trans Am Neurol Assoc. 86:147-152.
Isenberg SJ, Apt L, McCarty J, Cooper LL, Lim L, Signore MD. 1998. Development of tearing in preterm and term neonates. Arch
Ophthalmol. 116(6):773-776.
James T. 1970. Cardiac conduction system: fetal and postnatal development. Am J Cardiol. 25(2):213-226.
Jordaan H. 1979. Development of the central nervous system in prenatal life. Obstet Gynecol. 53(2):146-150.
Karmody CS, Annino DJ. 1995. Embryology and anomalies of the external ear. Facial Plast Surg. 2(4):251-256.
Koldovský O, Heringová A, Jirsová V, Jirásek JE, Uher J. 1965. Transport of glucose against a concentration gradient in everted sacs of jejunum and ileum of human fetuses. Gastroenterology. 48(2):185-187.
Kurjak A, Chervenak FA, editors. 1994. The fetus as a patient. New York: Parthenon.
Kurjak A, Kupesic S, Kostovic L. 1994. Vascularization of yolk sac and vitelline duct in normal pregnancies studied by transvaginal color and pulsed doppler. J Perinat Med. 22:433-440.
Page 24
Laffont J. 1982. Embryology of the brain. J Neuroradiol. 9:5-14.
Lauria MR, Gonik B, Romero R. 1995. Pulmonary hypoplasia: pathogenesis, diagnosis and antenatal prediction. Obstet Gynecol. 86(3):467-475.
Leader LR. 1995. Studies in fetal behaviour. Br J Obstet Gynaecol. 102(8):595-597.
Lecanuet JP, Schaal B. 1996. Fetal sensory competencies. Eur J Obstet Gynecol Reprod Biol. 68(1-2):1-23.
Leeuwen PV, Lange S, Betterman H, Grönemeyer D, Hatzmann W. 1999. Fetal heart rate variability and complexity in the course of pregnancy. Early Hum Dev. 54(3):259-269.
Liley AW. 1972. The foetus as a personality. Aust N Z J Psychiatry. 6(2):99-105.
Lipschutz JH. 1998. Molecular development of the kidney: a review of the results of gene disruption studies. Am J Kidney Dis. 31(3):383-397.
Lodish H, Berk A, Zipursky SL, Matsudaira P, Baltimore D, Darnell J. 2000. Molecular cell biology. 4th ed. New York: W.H. Freeman.
Mall FP. 1918. On the age of human embryos. Am J Anat. 23:397-422.
Mancia M. 1981. On the beginning of mental life in the foetus. Int J Psychoanal. 62:351-357.
Mancuso S, Palla G. 1996. Intrauterine nutrition and development. Adv Contracept. 12(4):285-291.
McCartney G, Hepper P. 1999. Development of lateralized behavior in the human fetus from 12 to 27 weeks' gestation. Dev Med Child Neurol. 41(2):83-86.
McCray PB. 1993. Spontaneous contractility of human fetal airway smooth muscle. Am J Respir Cell Mol Biol. 8(5):573-580.
Miller AJ. 1982. Deglutition. Physiol Rev. 62(1):129-181.
Mistretta CM, Bradley RM. 1975. Taste and swallowing in utero. Br Med Bull. 31(1):80-84.
Moore KL. 1980. Clinically oriented anatomy. Baltimore: Williams & Wilkins.
Moore KL, Persaud TVN. 2003. The developing human, clinically oriented embryology. 7th ed. Philadelphia: W.B. Saunders.
Morton H, Rolfe BE, Cavanaugh AC. 1992. Early pregnancy factor. Semin Reprod Endocrinol. 10(2):72-82.
Müller F, O'Rahilly R. 1983. The first appearance of the major divisions of the human brain at stage 9. Anat Embryol. 168(3):419-432.
Nahhas F, Barnea E. 1990. Human embryonic origin early pregnancy factor before and after implantation. Am J Reprod Immunol. 22(3-4):105-108.
Natale R, Nasello-Paterson C, Connors G. 1988. Patterns of fetal breathing activity in the human fetus at 24 to 28 weeks of gestation. Am J Obstet Gynecol. 158(2):317-321.
National Institutes of Health (NIH). http://www.nih.gov/. Bethesda: NIH; public domain. [updated 2002 Sep; cited 2004 Feb 2]. Available from:
http://stemcells.nih.gov/infoCenter/stemCellBasics.asp#3
Natsuyama E. 1991. In utero behavior of human embryos at the spinal-cord stage of development. Biol Neonate. 60(Suppl 1):11-29.
Navaratnam V. 1991. Organisation and reorganisation of blood vessels in embryonic development. Eye. 5(Pt 2):147-150.
Noback CR, Strominger NL, Demarest RJ. 1996. The human nervous system. 5th ed. Baltimore: Williams & Wilkins.
Page 25
Okai T, Kozuma S, Shinozuka N, Kuwabara Y, Mizuno M. 1992. A study on the development of sleep-wakefulness cycle in the human fetus. Early Hum Dev. 29(1-3):391-396.
O'Rahilly R. 1957. The development of joints. Ir J Med Sci. 171(382):456-61.
O'Rahilly R. 1966. The early development of the eye in staged human embryos. Carnegie Institution of Washington. Publ. 626. Contrib Embryol. 38:1-42.
O'Rahilly R. 1977a. The development of the vagina in the human. Birth Defects Orig Artic Ser. 13(2):123-136.
O'Rahilly R. 1977b. Prenatal human development. In: Wynn RM, editor. The biology of the uterus. 2nd ed. New York: Plenum.
O'Rahilly R. 1978. The timing and sequence of events in the development of the human digestive system and associated structures during the embryonic period proper. Anat Embryol. 153(2):123-136.
O'Rahilly R, Boyden EA. 1973. The timing and sequence of events in the development of the human respiratory system during the embryonic period proper. Z Anat Entwicklungsgesch.. 141(3):237-250.
O'Rahilly R, Gardner E. 1972. The initial appearance of ossification in staged human embryos. Am J Anat. 134(3):291-308.
O'Rahilly R, Gardner E. 1975. The timing and sequence of events in the development of the limbs in the human embryo. Anat Embryol. 148(1):1-23.
O'Rahilly R, Gardner E. 1979. The initial development of the human brain. Acta Anat. 104(2):123-133.
O'Rahilly R, Müller F. 1984. Chevalier Jackson lecture. Respiratory and alimentary relations in staged human embryos. New embryological data and congenital anomalies. Ann Otol Rhinol Laryngol. 93(5 Pt 1):421-429.
O'Rahilly R, Müller F. 1985. The origin of the ectodermal ring in staged human embryos of the first 5 weeks. Acta Anat. 122(3):145-157.
O'Rahilly R, Müller F. 1987. Developmental stages in human embryos. Washington: Carnegie Institution.
O'Rahilly R, Müller F. 1999a. The embryonic human brain: an atlas of developmental stages. 2nd ed. New York: Wiley-Liss.
O'Rahilly R, Müller F. 1999b. Minireview: summary of the initial development of the human nervous system. Teratology. 60(1):39-41.
O'Rahilly R, Müller F. 2001. Human embryology and teratology. 3rd ed. New York: Wiley-Liss.
O'Rahilly R, Müller F, Hutchins GM, Moore GW. 1984. Computer ranking of the sequence of appearance of 100 features of the brain and related structures in staged human embryos during the first 5 weeks of development. Am J Anat. 171(3):243-257.
O'Rahilly R, Tucker JA. 1973. The early development of the larynx in staged human embryos. Part I: Embryos of the first five weeks (to stage 15). Ann Otol Rhinol Laryngol. 82:1-27.
Patrick J, Campbell K, Carmichael L, Natale R, Richardson B. 1980. Patterns of human fetal breathing during the last 10 weeks of pregnancy. Obstet Gynecol. 56(1):24-30.
Pearson AA. 1980. The development of the eyelids. Part I. External features. J Anat. 130(1):33-42.
Penrose LS, Ohara PT. 1973. The development of epidermal ridges. J Med Genet. 10(3):201-208.
Petrikovsky BM, Kaplan GP, Pestrak H. 1995. The application of color Doppler technology to the study of fetal swallowing. Obstet Gynecol. 86(4 Pt 1):605-608.
Petrikovsky B, Schifrin B, Diana L. 1993. Effects of fetal acoustic stimulation on fetal swallowing and amniotic fluid index. Obstet Gynecol. 81(4):548-550.
Pierson LL. 1996. Hazards of noise exposure on fetal hearing. Semin Perinatol. 20(1):21-29.
Poissonnet CM, Burdi AR, Bookstein FL. 1983. Growth and development of human adipose tissue during early gestation. Early Hum Dev. 8(1):1-11.
Poissonnet CM, Burdi AR, Garn SM. 1984. The chronology of adipose tissue appearance and distribution in the human fetus. Early hum Dev. 10(1-2):1-11.
Pringle KC. 1988. A reassessment of pregnancy staging. Fetal Ther. 3(3):173-184.
Querleu D, Renard X, Boutteville C, Crepin G. 1989. Hearing by the human fetus? Semin Perinatol. 13(5):409-420.
Ramón y Cajal CL, Martinez RO. 2003. Defecation in utero: a physiologic fetal function. Am J Obstet Gynecol. 188(1):153-6.
Reinis S, Goldman JM. 1980. Prenatal and early postnatal development of brain function. The development of the brain: biological and functional perspectives. Springfield: Charles C. Thomas.
Robinson RJ, Tizard JPM. 1966. Central nervous system in the new-born. Br Med Bull. 22(1):49-55.
Romanini C, Rizzo G. 1995. Fetal behaviour in normal and compromised fetuses. An overview. Early Hum Dev. 43(2):117-131.
Rosenwasser AM. 2001. Alcohol, antidepressants, and circadian rhythms. Alcohol Res Health. 25(2):126-135.
Page 26
Sadler TW. 2005. Langman’s essential embryology. Philadelphia: Lippincott Williams & Wilkins.
Saunders JW. 1970. Patterns and principles of animal development. New York: Macmillan.
Schaal B, Marlier L, Soussignan R. 2000. Human foetuses learn odours from their pregnant mother’s diet. Chem Senses. 25(6):729-737.
Schats R, Jansen CA, Wladimiroff JW. 1990. Embryonic heart activity: Appearance and development in early pregnancy. Br J Obstet Gynaecol. 97(11):989-994.
Shettles LB. 1958. The living human ovum. Am J Obstet Gynecol. 76:398-406.
Smith RP, Gitau R, Glover V, Fisk NM. 2000. Pain and stress in the human fetus. Eur J Obstet Gynecol Reprod Biol. 92(1):161-5.
Sorokin Y, Dierker LJ. 1982. Fetal movement. Clin Obstet Gynecol. 25(4):719-734.
Sparrow MP, Weichselbaum M, McCray PB. 1999. Development of the innervation and airway smooth muscle in human fetal lung. Am J Respir Cell Mol Biol. 20(4):550-560.
Spencer RP. 1960. The intestinal tract. Springfield: Charles C. Thomas.
Sperber GH. 1989. Craniofacial embryology. 4th ed. London: University.
Spraycar M, editor. 1995. Stedman's medical dictionary. 26th ed. Baltimore: Williams & Wilkins.
Straus R, Walker RH, Cohen M. 1961. Direct electrocardiographic recording of a twenty-three millimeter human embryo. Am J Cardiol. 8:443-447.
Streeter GL. 1942. Developmental horizons in human embryos – description of age group XI, 13 to 20 somites, and age group XII, 21 to 29 somites. Carnegie Institution of Washington. Publ. 541. Contrib Embryol. 30(197):209-244.
Streeter GL. 1945. Developmental horizons in human embryos – description of age group XIII, embryos about 4 or 5 millimeters long, and age group XIV, period of indentation of the lens vesicle. Carnegie Institution of Washington. Publ. 557. Contrib Embryol. 31(199):27-63.
Streeter GL. 1948. Developmental horizons in human embryos – description of age groups XV, XVI, XVII, and XVIII, being the third issue of a survey of the Carnegie collection. Carnegie Institution of Washington. Publ. 575. Contrib Embryol. 32(211):133-203.
Streeter GL. 1951. Developmental horizons in human embryos – description of age groups XIX, XX, XXI, XXII, and XXIII, being the fifth issue of a survey of the Carnegie collection. Carnegie Institution of Washington. Publ. 592. Contrib Embryol. 34(230):165-196.
Tezuka N, Sato S, Kanasugi H, Hiroi M. 1991. Embryonic heart rates: development in early first trimester and clinical evaluation. Gynecol Obstet Invest. 32(4):210-212.
Timor-Tritsch IE, Zador I, Hertz RH, Rosen MG. 1976. Classification of human fetal movement. Am J Obstet Gynecol. 126(1):70-77.
Timor-Tritsch IE, Peisner DB, Raju S. 1990. Sonoembryology: an organ-oriented approach using a high-frequency vaginal probe. J Clin Ultrasound. 18(4):286-298.
Uhthoff HK. 1990. The embryology of the human locomotor system. Berlin: Springer-Verlag.
Valman HB, Pearson JF. 1980. What the fetus feels. Br Med J. 280(6209):233-234.
van Dongen LGR, Goudie EG. 1980. Fetal movement patterns in the first trimester of pregnancy. Br J Obstet Gynaecol. 87(3):191-193.
van Heeswijk M, Nijhuis JG, Hollanders HMG. 1990. Fetal heart rate in early pregnancy. Early Hum Dev. 22(3):151-156.
van Lith JM, Visser GH, Mantingh A, Beekhuis JR. 1992. Fetal heart rate in early pregnancy and chromosomal disorders. Br J Obstet Gynaecol. 99(9):741-744.
Vernall DG. 1962. The human embryonic heart in the seventh week. Am J Anat. 111:17-24.
Vindla S, James D. 1995. Fetal behaviour as a test of fetal wellbeing. Br J Obstet Gynaecol. 102(8):597-600.
Visser GHA, Mulder HH, Wit HP, Mulder EJH, Prechtl HFR. 1989. Vibro-acoustic stimulation of the human fetus: effect on behavioral state organization. Early Hum Dev. 19(4):285-296.
Visser GH, Mulder EJ, Prechtl HF. 1992. Studies on developmental neurology in the human fetus. Dev Pharmacol Ther. 18(3-4):175-183.
Vitaterna MH, Takahashi JS, Turek FW. 2001. Overview of circadian rhythms. Alcohol Res Health. 25(2):85-92.
Waters BL, Trainer TD. 1996. Development of the human fetal testis. Pediatr Pathol Lab Med. 16(1):9-23.
Watson JD, Crick FHC. 1953. Molecular structure of nucleic acids, a structure for deoxyribose nucleic acid. Nature. 171(4356):737-738.
Wells LJ. 1954. Development of the human diaphragm and pleural sacs. Carnegie Institution of Washington. Publ. 603. Contrib Embryol. 35:107-134.
Wilson KM. 1926. Correlation of external genitalia and sex-glands in the human embryo. Carnegie Institution of Washington. Publ. 363. Contrib Embryol. 18:23-30.
Windle WF. 1940. Physiology of the fetus. Philadelphia: W.B. Saunders.
Wisser J, Dirschedl P. 1994. Embryonic heart rate in dated human embryos. Early Hum Dev. 37:107-115.
Witschi E. 1948. Migration of the germ cells of human embryos from the yolk sac to the primitive gonadal folds. Carnegie Institution of Washington. Publ. 575. Contrib Embryol. 32:67-80.
Wood NS, Marlow N, Costeloe K, Gibson AT, Wilkinson AR. 2000. Neurologic and developmental disability after extremely premature birth. N Engl J Med. 343(6):378-384.
Page 27
Journal Abbreviation | Journal Name |
---|---|
Acta Anat | Acta Anatomica |
Acta Opthalmol | Acta Ophthalmologica |
Adv Contracept | Advances in Contraception |
Alcohol Res Health | Alcohol Research & Health |
Am J Anat | The American Journal of Anatomy |
Am J Cardiol | The American Journal of Cardiology |
Am J Kidney Dis | American Journal of Kidney Diseases |
Am J Obstet Gynecol | American Journal of Obstetrics and Gynecology |
Am J Reprod Immunol | American Journal of Reproductive Immunology and Microbiology |
Am J Respir Cell Mol Biol | American Journal of Respiratory Cell and Molecular Biology |
Am J Roentgenol | American Journal of Roentgenology |
Anat Embryol | Anatomy and Embryology |
Ann Otol Rhinol Laryngol | The Annals of Otology, Rhinology, and Laryngology |
Ann R Coll Surg Eng | Annals of the Royal College of Surgeons of England |
Arch Dis Child | Archives of Disease in Childhood |
Arch Ophthalmol | Archives of Ophthalmology |
Aust N Z J Psychiatry | The Australian and New Zealand Journal of Psychiatry |
Biol Neonate | Biology of the Neonate |
Birth Defects Orig Artic Ser | Birth Defects Original Article Series |
Br J Obstet Gynaecol | British Journal of Obstetrics and Gynaecology |
Br Med Bull | British Medical Bulletin |
Br Med J | British Medical Journal |
Chem Senses | Chemical Senses |
Child Dev | Child Development |
Clin Obstet Gynecol | Clinical Obstetrics and Gynecology |
Contrib Embryol | Contributions to Embryology |
Dev Med Child Neurol | Developmental Medicine and Child Neurology |
Dev Pharmacol Ther | Developmental Pharmacology and Therapeutics |
Early Hum Dev | Early Human Development |
Eur J Obstet Gynecol Reprod Biol | European Journal of Obstetrics, Gynecology, and Reproductive Biology |
Eye | Eye |
Facial Plast Surg | Facial Plastic Surgery |
Fertil Steril | Fertility and Sterility |
Fetal Ther | Fetal Therapy |
Gastroenterology | Gastroenterology |
Gynecol Invest | Gynecologic Investigation |
Gynecol Obstet Invest | Gynecologic and Obstetric Investigation |
Int J Psychoanal | The International Journal of Psycho-Analysis |
Ir J Med Sci | Irish Journal of Medical Science |
J Clin Ultrasound | Journal of Clinical Ultrasound |
J Comp Neurol | The Journal of Comparative Neurology |
J Med Genet | Journal of Medical Genetics |
J Comp Neurol | Journal of Neuroradiology |
J Pathol Bacteriol | The Journal of Pathology and Bacteriology |
J Pediatr Surg | Journal of Pediatric Surgery |
J Perinat Med | Journal of Perinatal Medicine |
J Anat | Journal of Anatomy |
JAMA | JAMA : The Journal of the American Medical Association |
Lancet | Lancet |
N Engl J Med | The New England Journal of Medicine |
N Z Med J | New Zealand Medical Journal |
Nature | Nature |
Neurology | Neurology |
Neuropsychologia | Neuropsychologia |
Nutr Rev | Nutrition Reviews |
Obstet Gynecol | Obstetrics & Gynecology |
Pediatr Pathol Lab Med | Pediatric Pathology & Laboratory Medicine |
Pediatr Res | Pediatric Research |
Pediatrics | Pediatrics |
Physiol Rev | Physiological Reviews |
Science | Science |
Semin Pediatr Surg | Seminars in Pediatric Surgery |
Semin Perinatol | Seminars in Perinatology |
Semin Reprod Endocrinol | Seminars in Reproductive Endocrinology |
Semin Roentgenol | Seminars in Roentgenology |
Teratology | Teratology |
Trans Am Neurol Assoc | Transactions of the American Neurological Association |
Ultrasound Obstet Gynecol | Ultrasound in Obstetrics & Gynecology |
Z Anat Entwicklungsgesch | Zeitschrift fur Anatomie und Entwicklungsgeschichte |
Page 28
A |
Page Links |
abdomen | 8, 9, 14 |
abdominal | 6, 12 |
activity | 10, 14, 16 |
adenine | 4 |
adult(s) | 3, 4, 10, 11, 14 |
age | 14 |
age of viability | 14 |
air | 11, 14, 16 |
alveoli | 16 |
amnion | 6, 7 |
amniotic fluid | 7, 11, 12, 14, 15 |
anise | 16 |
articular | 11 |
B |
|
base pairs | 17 |
base(s) | 4, 18 |
behavior(al) | 11, 15, 16 |
billion | 4, 7, 11 |
birth | 3, 6, 7, 11, 12, 13, 15, 16 |
blastocyst | 5 |
blink-startle | 15 |
blood | 4, 5, 6, 7, 9, 11, 13 |
blood cells | 6 |
blood vessels | 6, 11 |
blueprint | 4 |
body | 3, 4, 5, 6, 11, 12, 13, 15 |
body plan | 6 |
bone(s) | 6, 10, 11, 12, 13 |
bowel | 13 |
brain | 6, 7, 9, 11, 15 |
breastfeeding | 13 |
breathing | 9, 11, 16 |
bronchi | 8 |
bronchial tree | 14 |
buds | 7, 13 |
C |
|
cardiac | 16, 21 |
cardiovascular | 6 |
Carnegie Stage(s) | 3, 4, 5, 6, 7, 8, 9, 10, 21 |
cartilage | 6, 8 |
cell(s) | 3, 4, 5, 6, 7, 8, 9, 11, 12, 13, 16 |
central nervous system | 16 |
cerebral hemispheres | 7, 9 |
chambers | 6, 7 |
cheeks | 13 |
chest | 6, 10 |
childbirth | 16 |
chromosomes | 4 |
circulatory | 5, 6 |
clavicle | 10 |
close | 12 |
cochlea | 14 |
collar bone | 10 |
conception | 3 |
contraction | 16 |
cytosine | 4 |
D |
|
day(s) | 5, 6, 8, 10 |
development(al) | 3, 4, 6, 7, 9, 12, 13, 16 |
diaphragm | 9 |
digestive | 6, 13 |
distinguish(ed) | 12, 16 |
DNA | 4, 17, 18 |
E |
|
ear | 9, 14 |
early pregnancy factor (EPF) | 4 |
earth | 4, 17 |
ectoderm | 6 |
egg | 4 |
elbows | 10 |
electrocardiogram | 10 |
electrodes | 9 |
embryo | 3, 4, 5, 6, 7, 8, 9, 11, 13 |
embryology | 4 |
embryonic | 3, 4, 5, 7, 9, 11, 19, 20 |
embryonic period | 11, 20 |
encephalography | 9 |
endoderm | 6 |
energy | 15 |
enzymes | 13 |
epiblast | 6 |
epidermis | 11 |
estrogen | 16 |
extension | 11 |
eye(s) | 10, 11, 12, 15 |
eyelids | 10, 11, 12, 15 |
Page 29
F |
Page Links |
face | 11, 12, 13 |
Fallopian tubes | 4 |
fat | 13, 15 |
female | 10, 12, 13, 15 |
fertilization | 3, 4, 5, 6, 12, 14, 15, 16 |
fetal | 3, 5, 12, 13, 14, 15, 16 |
fetal period | 3, 12, 17 |
fetus | 3, 5, 6, 12, 13, 14, 15, 16 |
fingerprints | 12 |
fingers | 10 |
flattening | 9 |
fluid | 7, 11, 12, 14, 15 |
folding | 6 |
follicles | 14 |
forebrain | 6, 7 |
formation | 3, 8, 11, 12 |
function(s) | 3, 7, 21 |
fuse | 11 |
G |
|
genitalia | 12 |
germ cells | 8 |
germ layers | 6 |
gestational age | 3, 14 |
glands | 14 |
glucose | 12 |
grasp | 12, 16 |
grasping | 11 |
gravity | 11 |
grow(ing)(s) | 3, 5, 6, 9, 11, 14 |
growth | 6, 7, 10, 11, 12, 15 |
guanine | 4 |
H |
|
hair | 6, 11, 14 |
hand(s) | 8, 9, 10, 11, 12, 16 |
head | 5, 7, 9, 11, 12, 13 |
health | 15, 16 |
hearing | 7, 14, 15 |
hearing loss | 15 |
heart | 6, 7, 8, 10, 14, 15 |
heart rate | 14, 15, 20 |
heartbeat(s) | 20 |
helix | 4 |
hindbrain | 6, 7 |
hormone(s) | 5 |
hours | 4, 14 |
human | 3, 4, 5, 6, 11, 12, 16 |
human chorionic gonadotropin (hCG) | 5 |
hypoblast | 6 |
I |
|
implantation | 5 |
inner cell mass | 5, 6 |
intestine | 9, 12 |
J |
|
jaw | 10, 11, 12, 13 |
jaw movement | 11, 13 |
joints | 10, 11 |
Page 30
K |
Page Links |
kidneys | 6, 8, 11 |
knee | 10 |
L |
|
labor | 16 |
larynx | 12 |
learning | 7 |
left-handed | 11 |
leg | 15 |
licorice | 16 |
life cycle | 12 |
lifespan | 7 |
light | 12, 13, 15 |
limb(s) | 7, 11, 13 |
lips | 12 |
liver | 6, 8, 9 |
lungs | 8, 14, 16 |
lymphocytes | 9 |
M |
|
male | 11, 12, 13 |
man | 4 |
marrow | 13 |
maternal | 4, 5, 19 |
meconium | 13 |
medications | 5 |
memory | 7 |
menstrual cycle | 5 |
mesoderm | 6 |
metaphase | 4 |
meters | 17 |
midbrain | 6, 7 |
miles | 4, 17 |
million | 4, 7, 17 |
mitosis | 4 |
molecule(s) | 4, 17 |
morula | 5 |
mouth | 9, 11, 12, 13 |
move | 12 |
movement(s) | 7, 9, 10, 11, 13, 14, 16 |
mulberry | 5 |
muscle(s) | 6, 11 |
muscular | 11 |
N |
|
nails | 6 |
nerve(s) | 6, 11 |
neural | 11 |
neuromuscular | 9 |
newborn(s) | 11, 13, 14, 16 |
nipple(s) | 10, 13 |
noise | 15 |
noradrenaline | 14 |
norepinephrine | 14 |
nose | 12 |
O |
|
odors | 15 |
oocyte | 4 |
oogonia | 12 |
open(s) | 12, 13, 15 |
ossification | 10 |
ovaries | 4, 10 |
ovary | 4, 12 |
ovulation | 4 |
oxygen | 5 |
Page 31
P |
Page Links |
palms | 12 |
pancreas | 6 |
percent | 11, 12, 13, 15, 16 |
physiologic herniation | 9 |
placenta | 5, 19 |
postfertilization age | 9, 10, 13, 14, 15, 20 |
postmenstrual age | 3, 9, 13, 14 |
postnatal | 20 |
preference(s) | 11, 16 |
pregnancy | 3, 4, 5, 13, 15, 16 |
premature(ly) | 14, 15 |
prenatal | 21 |
problem-solving | 7 |
proportion | 13 |
protection | 7 |
pupils | 15 |
Q |
|
quickening | 13 |
R |
|
reflex | 13 |
reflexive(ly) | 9, 11 |
reopen | 15 |
reproductive | 4, 8, 12 |
respiratory | 6, 8, 14, 15 |
respond(s) | 13, 14, 15 |
response | 10, 12, 13, 14, 15 |
retina | 10, 15 |
right-hand | 11 |
rolling over | 11 |
roof | 13 |
rooting reflex | 13 |
rotation | 11 |
S |
|
sac | 6, 7 |
scalp | 14 |
sense(s) | 12, 13, 15 |
sex | 12 |
sigh | 12 |
skeletal | 11 |
skin | 6, 7, 11, 14, 15 |
skin layers | 14 |
sole(s) | 12 |
somersaults | 15 |
sounds | 14, 16 |
speech | 7 |
sperm | 4 |
spermatozoon | 4 |
spinal cord | 6 |
spontaneous | 9, 11 |
squinting | 11 |
startle | 10, 15 |
stem cells | 5, 13 |
stimulation | 12, 13 |
stress response | 14 |
stretch | 12 |
structure(s) | 3, 5, 6, 11, 14, 21 |
survival | 3, 14 |
swallow(ed)(ing) | 12, 15 |
system(s) | 3, 5, 6, 8, 9, 14, 16, 21 |
T |
|
taste | 13, 16 |
taste buds | 13 |
tears | 15 |
temperature | 5, 15, 19 |
testes | 11 |
testosterone | 11 |
thought | 7 |
thumb sucking | 12 |
thymine | 4 |
toes | 10, 12 |
tongue | 12, 13 |
tooth | 13 |
touch(ing) | 9, 11, 12, 13 |
trachea | 8 |
transparency | 7, 11 |
trillion | 3, 4, 17 |
trimester | 13, 15 |
trunk | 10 |
U |
|
umbilical cord | 5, 9, 12 |
umbilical vesicle | 6 |
urine | 11 |
uterine tube(s) | 4, 5 |
uterus | 4, 5, 11, 12, 16 |
V |
|
vascular | 11 |
vernix caseosa | 14 |
viability | 14 |
vocal cord development | 12 |
vocal ligaments | 12 |
W |
|
walking | 15 |
water | 12 |
weight | 11, 12, 13, 15 |
white blood cell | 9 |
windpipe | 8 |
woman | 4, 13 |
womb | 4, 14 |
wrinkled | 15 |
wrist | 8 |
Y |
|
yawns | 12 |
yolk sac | 6, 8 |
Z |
|
zygote | 3, 4 |