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Menstrual synchrony is a hypothesized process in which women who begin living together in close proximity experience their menstrual cycle onsets (i.e., the onset of menstruation or menses) becoming closer together in time than previously. "For example, the distribution of onsets of seven female lifeguards was scattered at the beginning of the summer, but after 3 months spent together, the onset of all seven cycles fell within a 4-day period."
Martha McClintock's 1971 paper in Nature (journal) says that menstrual cycle synchronization happens when the menstrual cycle onsets of two women or more women become closer together in time than they were several months earlier. Several mechanisms have been hypothesized to cause synchronization.
After the initial studies, several papers were published reporting methodological flaws in studies reporting menstrual synchrony including McClintock's study. In addition, other studies were published that failed to find synchrony. The proposed mechanisms of have also received scientific criticism. A recent review of menstrual synchrony concluded that menstrual synchrony is doubtful.
Original study by Martha McClintockEdit
Efforts to replicate McClintock's resultsEdit
The term synchrony has been argued to be misleading because no study has ever found that menstrual cycles become strictly concordant, nevertheless menstrual synchrony is used to refer the phenomenon of menstrual cycle onsets becoming closer to each other over time.
Status of the theoryEdit
Indeed, in a recent systematic review of menstrual synchrony, Harris and Vitzthum concluded that "In light of the lack of empirical evidence for MS [menstrual synchrony] sensu stricto, it seems there should be more widespread doubt than acceptance of this hypothesis." (pp. 238–239)
The experience of synchrony may be the result of the mathematical fact that menstrual cycles of different frequencies repeatedly converge and diverge over time and not due to a process of synchronization. It may also be due to the high probability of menstruation overlap that occurs by chance.
Researchers are divided on whether menstrual synchrony is adaptive. McClintock has suggested that menstrual synchrony may not be adaptive but rather epiphenomenonal, lacking any biological function. Among those postulating an adaptive function, one argument is that menstrual synchrony is only a particular aspect of the much more general phenomenon of reproductive synchrony, an occurrence familiar to ecologists studying animal populations in the wild. Whether seasonal, tidal or lunar, reproductive synchrony is a relatively common mechanism through which co-cycling females can increase the number of males included in the local breeding system. Conversely — where females benefit by excluding all but a minority of the most dominant males — scientists expect evolution in the reverse direction, with females minimising or completely avoiding synchrony. Divergent climate regimes differentiating Neanderthal reproductive strategies from those of modern Homo sapiens have recently been analysed in these terms.
Myth and traditionEdit
Awareness and subjective experiencesEdit
In addition, most women report that they are aware of menstrual synchrony and nearly as many report personally experiencing the phenomenon.
The phenomenon of menstrual synchrony is the closeness in time of the menstrual cycle onsets of two or more women. The phenomenon is not synchronization in the strict sense of concordance of menstrual cycle onsets but the term menstrual synchrony is still used perhaps misleadingly Researchers since Martha McClintock, then an undergraduate, published the first study reporting on undergraduate women living in a dormitory in Wellesley College have attempted to replicate her findings and to determine the conditions under which synchrony occurs if it exits. Her work was subsequently followed up by studies reporting menstrual synchrony and by other studies that failed to find synchrony.
Thus, a number of studies were published from the 1980s to the mid 2000s, which attempted to replicate menstrual synchrony in college women, determine the conditions under which menstrual synchrony occurred, and to address methodological issues that were raised as these studies were published. The rest of this section discusses these studies in chronological order, briefly presenting their findings and main conclusions grouped by decade followed by general methodological issues in menstrual synchrony research.
McClintock's study consisted of 135 female college students who were 17 to 22 years old at the time of the study. They were all residents of a single dormitory, which had four main corridors. The women were asked when their last and second to last menstrual period had started three times during the academic year (which ranged from September to April). They also were asked who (other women in the dormitory) they associated with most and how often each week they associated with males. From these data, McClintock placed women into pairs of close friends and roommates and she also placed them into groups of friends ranging in size from 5 to 10 women. She reported statistically significant synchrony for both her pairwise sorting of women and her group sorting of women. That is, whether women were placed into pairs of close friends and roommates or whether they were placed into larger groups of friends, she reported that they synchronized their menstrual cycles. She also reported that the more often women associated with males, the shorter menstrual cycles were. She speculated that this may be a pheromone effect paralleling the Whitten effect in mice but that it could not explain menstrual synchrony among women. Finally, she speculated that there could be a pheromone mechanism of menstrual synchrony similar to the Lee-Boot effect in mice.
Graham and McGrew were the first researchers to attempt to replicate McClintock's study. There were 79 women living in residence halls or apartments on the campus of a college in Scotland. The women were 17 to 21 years old at the time of the study and the procedures followed were similar to those used in McClintock's study. She partially replicated McClintock's study reporting that close friends but not neighbors synchronized their cycles. Unlike in McClintock's study, close friends did not synchronize in groups. They considered a pheromone mechanism a possible explanation of synchrony, but noted that if pheromones were the cause, neighbors should have synchronized as well. They concluded that the mechanism of synchrony remains unknown, but emotional attachment may play a role.
Quadagno et al. conducted the second replication of McClintock's study. There were 85 women living in dormitories, sorority houses, and apartments who attended a large midwestern university in the United States. Their study used methods similar to McClintock's study except in addition to two women living together, there were also groups of three and four women living together. They reported that the women synchronized their menstrual cycles and concluded that pheromones may have played a role in synchronization.
Jarett's study was the third to attempt to replicate McClintock's original study using college roommates. There were 144 women who attended two colleges. The women were 17 to 22 years old and the procedures followed were similar to McClintock's study except only pairs of roommates were used. She reported that the women did not synchronize. Jarett concluded that whether menstrual synchrony occurs in a group of women may depend on the variability of their menstrual cycles. She conjectured that the reason the women in her study did not synchronize their menstrual cycles was because they happened to have longer and more irregular menstrual cycles than in McClintock's original study.
Wilson, Kiefhabe, and Gravel conducted two studies with college women. The first study consisted of 132 women who were members of a sorority or roommates of members at the University of Missouri. The women were 18 to 22 years of age and the study aimed to replicate McClintock's original study. However, instead of asking women to recall when their last and next to last menstrual onsets occurred, one of the researchers visited the sorority daily to record the occurrence of menstrual onsets and to collect other biographical data. The second study consisted of 24 women living in a cooperative house near the University of Missouri. The women were 18 to 31 years of age. One of the researchers visited the house three times a week recording menstrual onset and collecting more extensive biographical and psychological test data than in the first study. They found no menstrual synchrony in either study. They considered the possibility that women with irregular cycles may reduce the likelihood of detecting synchrony, so they re-analyzed their data after they removed women with irregular cycles, but again there was no statistically significant effect of synchrony. They concluded that "It is clear no meaningful process of selection or exclusion of pairs can produce a significant level of menstrual synchrony in our samples... Therefore, whether or not menstrual synchrony occurs among women who spend time together must remain a hypothesis requiring further investigation." (p. 358)
Weller and Weller conducted a study with 20 lesbian couples. They hypothesized that contact within couples should be maximal and contact with men minimal compared to previous studies, which should maximize the likelihood of detecting synchrony. The women ranged in age between 19 and 34 years of age. This was the first study that did not explicitly use college women, but instead the women were recruited at a bar by a research assistant who was a proprietor of a bar. Unlike previous studies, they only asked the women for the date of their last menstrual onset. They then assumed that all the women had menstrual cycles that were exactly 28 days long. Based on this assumption and one menstrual onset for each woman in a couple, they calculated the degree of synchrony. They reported that more than half of the couples had synchronized within a two-day timespan of each other.
Trevathan, Burleson, and Gregory also conducted a study with 29 lesbian couples (22 to 48 years of age), but they incorporated the methodological critique of Wilson into the design of their study. In particular, Wilson emphasized the importance of using actual menstrual cycle lengths with their inherent variability. The lesbian couples were drawn from a larger sample of women who had kept daily records of their menstrual cycles for three months and who had participated in a previous study. They found no evidence of synchrony. They discussed several factors that could have prevented synchrony in their study but they strongly suggested that menstrual synchrony may not be a real phenomena because of the methodological issues Wilson raised and because menstrual synchrony appears to lack adaptive significance.
In addition to the study they conducted with lesbian couples, Weller and Weller conducted a number of other studies on menstrual synchrony during the 1990s. In most studies they reported finding menstrual synchrony, but in some studies they did not find synchrony. In a methodological review article in 1997, they their approach to measuring to better handle the problem of cycle variability. Specifically, they concluded that several menstrual cycles should be measured from each woman and that the longest average cycle length in a pair or group of women should be the basis for calculating the expected cycle onset difference. Thus, their research falls into the pre-1997 methodology and post-1997 methodology.
In 1997, Weller and Weller published one of the first studies to investigate when menstrual synchrony occurs in complete families. Their study was conducted in Bedouin villages in northern Israel. Twenty seven families, which had from two to seven sisters 13 years or older and collected data on menstrual cycle onsets over a three-month period. Using the methods of, they reported menstrual synchrony occurred for the first two months, but not for the third month for roommate sisters, close friend roommates, and for families as a whole.
Strassmann investigated whether menstrual synchrony occurred in a natural fertility population of Dogon village women. Her study consisted of 122 Dogon women with an average lifetime fertility rate of 8.6 ± .3 live births per woman. Their median cycle length was 30 days, which is indistinguishable from western women. In analyzing whether menstrual synchrony occurs among Dogon women, she was aware of Wilson's methodological criticisms of previous studies and aware that menstrual synchrony isn't synchrony per se, but rather the closeness of menstruation among women. She used Cox regression to determine whether the risk of menstruating was influenced by other women. She considered the levels of all the women in the village, all the women in the same lineage, and all the women in the same economic unit (i.e., they worked together). She found no significant relationship at any level, which means that there was no evidence of synchronization. She concluded that this result undermined the view that menstrual synchrony is adaptive and the view held by many anthropologists at the time that menstrual synchrony occurred in preindustrial societies.
Menstrual synchrony research declined after the published critiques in the 1990s and around the turn of the century. The two studies published during this decade incorporated the methodological critiques into their designs and used more appropriate statistical methods.
Yang and Schank conducted the largest study to date with 186 Chinese college women. Ninety three women lived in 13 dorm rooms, 5 to 8 women per room. The other Ninety three women lived in 16 dorm room, 4 to 8 some per room for a total of 29 rooms. The women were given notebooks to record the onset of each of their cycles and they collected data for over a year for most of the women.
Following the statistical critiques of Schank, they argued that circular statistics were required to analyze periodic data for the existence of synchrony. However, menstrual cycles are variable in frequency (e.g., 28 or 31 day cycles) and in length (e.g., a woman can have a sequence of cycles that in how many days they last). The pointed out that there are not statistics methods for analyzing messy data like this, so they developed Monte Carlo methods for detecting synchrony.
They found that in 9 of the 29 groups, women's cycles converged for one cycle closer than expected by chance, but then they diverged again. Upon further analysis, they found that for women with the cycle variability reported in this study, on average 10 out of 29 groups of women would show this pattern of convergence followed by divergence. They concluded that finding 9 of 29 group with convergence and then divergence is about what would be expected by chance and concluded that there was no evidence the women in this study synchronized their menstrual cycles.
Ziomkiewicz conducted a study with 99 Polish college women living in two dormitories. Thirty six women live in 18 double rooms and 63 lived 21 triple rooms. Women recorded their menstrual cycle onsets on menstrual calendars provided to them and 181 days menstrual cycle data were collected. The mean menstrual cycle length was 30.5 days (SD = 4.56).
Based on the mean cycle length of the women in this study, the expected difference by chance in menstrual cycle onset is approximately 7.5 days. The mean difference in cycle onset were calculated for the beginning, middle, and end of the study for the pairs and triples of women. Ziomkiewicz found no statistically significant difference from the 7.5 day expected difference at either the beginning, middle, or end of the study. She concluded that there was no evidence of menstrual synchrony.
Initial Onset DifferencesEdit
H. Clyde Wilson argued that at the start of any menstrual synchrony study, the minimum cycle onset difference must be calculated by using two onset differences from each woman in a group. For example, suppose two women have exactly 28-day cycles. The greatest distance that one cycle onset can be from another is 14 days. Suppose the first two onsets for woman A are July 1 and July 29 and for woman B, they are July 24 and August 21. If only the first two recorded onsets of A and B are compared, the difference between onsets is 23 days, which is greater the 14 days that can actually occur. Wilson argued that McClintock did not correctly calculate the initial onset difference among women and concluded that the initial onset difference among women in a group was biased towards asynchrony.
Yang and Schank followed up on this point by using computer simulations to estimate the average onset difference that would occur by among women with variable cycle lengths and a mean cycle length of 29.5 days reported by McClintock. They reported that the average onset difference by chance among women with cycle characteristics reported by McClintock was about 5 days. They also calculated the expected onset difference at the beginning of the study using McClintock's method for calculating initial cycle onset differences. They reported that the initial cycle onset difference for the groups of women using McClintock's method was about 6.5 days. McClintock reported that groups of women had an initial cycle onset difference at the beginning of her study of about 6.5 days and then subsequently synchronized to an average difference of a little less than 5 days. Yang and Schank point out that since the expected cycle onset differences they calculated were so close to the differences reported by McClintock, that there may be no statistical difference. They concluded that If their analysis is correct, it implies that synchrony did not occur in McClintock's original study.
Hypothesized Mechanisms of SynchronizationEdit
Cutler and Law hypothesized that menstrual synchrony is caused by menstrual cycles synchronizing with lunar phases. However, neither of them agree on what phase of the lunar cycle menstrual cycles synchronize with. Cutler hypothesizes the synchronize with the full moon and Law with the new moon. Neither offer hypotheses regarding how lunar phases cause menstrual synchrony and neither are consistent with previous studies that found no relationship between menstrual cycles and lunar cycles. More recently, Strassmann investigated menstrual synchrony among Dogon village women. The women were outdoor most night and did not have electrical lighting. She hypothesize that Dogon women would be ideal for detecting a lunar influences on menstrual cycles, but she found no relationship.
Jarett hypothesized that women who were more affiliative and concerned with how others viewed them would synchronize more. In her study, however, women with low affiliation scores were associated with greater synchrony. She found that women with a need for social recognition and approval from others were associated with synchrony, which is partially consistent with her hypothesis. Nevertheless, the group of women she studied did not synchronize their menstrual cycles.
When McClintock publish her study on menstrual synchrony, she speculated that pheromones may cause menstrual synchrony. In a study on Norway rats, McClintock proposed and tested a coupled oscillator hypothesis (see section on rats below). The coupled-oscillator hypothesis proposed estrous cycles in rats were cause by two, estrous phase dependent pheromones that mutually modulated the length of cycles in a group and thereby causing synchrony.
This idea was extended to humans in a study by Stern and McClintock. They investigated whether a coupled-oscillator mechanism first reported for Norway rats (see section below on rats) could also exist in humans. The coupled-oscillator hypothesis in humans proposed that human females release and receive pheromones that regulate the length of their menstrual cycles. This was assumed to occur without consciously detecting any odor. The study was conducted by collecting compounds from axillae (underarms) of donor women at prescribed phases during their menstrual cycles (i.e., the follicular phase, ovulatory phase, and luteal phase), and applying the compounds daily under the noses of recipient women. In order to collect the axillary compounds, the donor women wore cotton pads under their arms for at least 8 hours, and then the pads were cut into smaller squares, frozen to preserve the scent, and readied for distribution to the recipients. The recipients were split into two groups, and were exposed to the compounds via application of the thawed axillary pad under their noses daily.
The researchers concluded that odorless compounds collected from women during the late follicular phase of their menstrual cycles triggered hormonal events that shortened the menstrual cycles of the recipient women, and that odorless compounds collected from women during the time of ovulation triggered a hormonal event in the recipient women that lengthened their menstrual cycles. Stern and McClintock concluded that these findings "proved the existence of human pheromones" as well as illustrated manipulation of the human menstrual cycle.
Researchers pointed out several flaws in their study. Whitten's main critiques was with their using only only there first cycles as a control for the subsequent conditions. He argued that this eliminate all within-subject variance . Control conditions should have been run between each experimental condition and just at the beginning of the study. He was also skeptical about whether the coupled-oscillator model from rat research could be applied to humans.
Perception and Awareness of SynchronyEdit
Arden and Dye investigated women's awareness and perception of menstrual synchrony. Their study consisted of 122 women (students and staff) at Leeds University. A four-page questionnaire was sent to each participant. After providing personal details, they were given a description of menstrual synchrony: "Menstrual synchrony occurs when two or more women, who spend time with each other, have their periods at approximately the same time" (p. 257) After reading the description they were asked whether they were aware of menstrual synchrony and whether they had experienced it. They were then asked details about their experience of synchrony such as how many times they experienced and how long it lasted.
They found that 84% of the women were aware of the phenomenon of menstrual synchrony and 70% reported the personal experience of synchrony. The experience of synchrony occurred most commonly with close friends followed by roommates. There was considerable variation in the reported time spent together before synchrony occurred ranging from zero to four weeks to 12 months or more. The most common time was 12 months or more. The duration of menstrual synchrony also was highly variable with responses ranging from one to two months to 12 months or more. They conclude that "Whether or not future research concludes that menstrual synchrony is an objective phenomenon, subjective experiences, which are apparently widespread, need to be given careful consideration." (p. 265)
Both Wilson and Arden and Dye pointed out that menstrual synchrony can occur by chance when there is menstrual cycle variability. Yang and Schank argued that when there is cycle variability (i.e., either women have irregular cycles, have cycles of different frequencies, or both), most women will have the opportunity to experience synchrony even though it is a result of cycle variability and not a result of a mechanism such as the exchange of pheromones. For example, consider two women A and B. Suppose A has menstrual cycles that are 28 days long and B has cycles that are 30 days long. Suppose further that when A and B become close friends, B has a cycle onset 14 days before A's next onset. The next time both of them have menstrual cycle onsets, B will have a cycle onset 12 days before A. B will continue to gain two days on A until their onsets coincide, then their cycles will begin to diverge again. The cycles of A and B will repeatedly converge and diverge creating the appearance of synchrony during convergence. This is a mathematical property of cycles of different frequencies and not due to the interaction of A and B. If, in addition, the duration of menstruation is considered (typically 3 to 5 days with a range of 2 to 7 days), then the experience of synchrony may last a number of months.
Strassmann argued menstrual synchrony defined as menstruation overlap should be quite common. For example, the expected difference by chance between two women with 28-day cycles—which is approximately the average length of menstrual cycles of women at the age —is 7 days. Considering that the mean duration of menses is 5 days and the range is 2 to 7 days, the probability of menstruation overlap by chance should be high.
Is menstrual synchrony adaptive?Edit
In order to work out why menstrual synchrony might have evolved, it is necessary to investigate why individuals who synchronized their cycles might have had increased survival and reproduction in the evolutionary past. The relevant field in this case is behavioral ecology.
In mammalian mating systems generally, and among primates in particular, female spatio-temporal distribution – how clumped females are in the environment and how much they overlap their fertile periods – affects the ability of any single male to monopolize matings. The basic principle is that the more females are fertile at any one time, the harder it is for any single male to monopolize access to them, impregnating all simultaneously at the expense of rival males. In the case of nonhuman primates, once the number of co-cycling females rises above a critical threshold, a harem-holder may be unable to prevent other males from invading and mating with his females. A dominant male can maintain his monopoly only if his females stagger their fertile periods, so that he can impregnate them one at a time (see figure a, right). Suppose a group of female baboons need between them just one dominant male, desirable in view of his high-quality genes. Then, logically, they should avoid synchronizing their cycles. By the same token, if males during the course of human evolution became valued by females for additional purposes - hunting and bringing home food, for example - then females should resist being controlled by dominant male harem-holders. If males are useful partners to have and keep around, then ideally each female should have at least one for herself. Under those circumstances, according to this argument, the logical strategy would be for females to synchronize as tightly as they can (see figure b, right).
One implication is that there may be a link between the degree of synchrony in a population (whether seasonal, lunar or both), and the degree of reproductive egalitarianism among males. Foley and Fitzgerald objected to the idea that synchrony could have been a factor in human evolution on the grounds that for hominins with inter-birth intervals of 3–5 years, achieving synchrony was unrealistic. Infant mortality would disrupt synchrony since it would be too costly for a mother who had miscarried or lost her baby to wait until everyone else had weaned their babies and resumed cycling before having sex and getting pregnant herself. On the other hand, while conceding that it would be impossible to get clockwork synchrony throughout an inter-birth interval, Power et al. argued that once we take account of birth seasonality - enhancing the effects of menstrual synchrony by clumping fertile cycles within a relatively brief time-window - it emerges that reproductive synchrony can be effective as a female strategy to undermine primate-style sexual monopolization by dominant males. The controversy remains unresolved.
Adopting a compromise position, one school of Darwinian thought argues that the human female may once have had adaptive reasons for evolving a 29.5-day menstrual cycle – implying some theoretical potential for synchrony to a lunar clock – but did so in an African setting under prehistoric conditions which today no longer exist. Not all archaeologists accept that lunar periodicity was ever relevant to human evolution. On the other hand, according to Curtis Marean (head of excavations at the important Middle Stone Age site of Pinnacle Point, South Africa), anatomically modern humans around 165,000 years ago – when inland regions of the continent were dry, arid and uninhabitable – became restricted to small populations clustered around coastal refugia, reliant on marine resources including shellfish whose safe harvesting at spring low tides presupposed careful tracking of lunar phase.
"With gradual offshore platforms during spring low tides, substantial areas of the intertidal zone are revealed, and these are the most productive and safest shellfish collecting times… Foragers should schedule visits to coastal residential sites at times during the lunar month when spring tides are present and then move slightly inland during neaps to broaden the size of the exploitable terrestrial area."
Menstrual synchrony in traditional myth and ritualEdit
The idea that menstruation is – or ideally ought to be – in harmony with wider cosmic rhythms is one of the most tenacious ideas central to the myths and rituals of traditional communities across the world.
“String was first made by the two Wawalik Sisters at Mudawa, near Buckingham Bay... The sisters sat down, looking at each other, with their feet out and legs apart, and both menstruated… Each one made a loop of the other one’s menstrual blood, after which they put the string loops around their necks”.
— <cite style="font-style:normal" > McCarthy, F.D. 1960. The string figures of Yirrkalla..</cite>
The !Kung (or Ju|'hoansi) hunter-gatherers of the Kalahari “believe....that if a woman sees traces of menstrual blood on another woman’s leg or even is told that another woman has started her period, she will begin menstruating as well”. Among the Yurok Indians of northwestern California, according to one ethnographic study, "all of a household’s fertile women who were not pregnant menstruated at the same time…" Menstrual synchrony, in particular by association with the moon, is a belief found in mythology throughout the world.
"She said that she had been instructed in the menstrual laws by her maternal aunts and grandmother, who in their times were well-known, conservative Yurok women.... the young woman said that in old-time village life all of a household's fertile women who were not pregnant menstruated at the same time, a time dictated by the moon; that these women practised bathing rituals together at this time... If a woman got out of synchronization with the moon and with the other women of the household, she could 'get back in by sitting in the moonlight and talking to the moon, asking it to balance her'".
— <cite style="font-style:normal" > Buckley, T. 1988. Menstruation and the power of Yurok women.</cite>
In Aboriginal Australia, the supernatural being known as the 'Rainbow Snake' has been interpreted as, among other things, an indigenous way of conceptualising the ideal of synchronised tidal, lunar, menstrual and seasonal periodicities whose overall harmony (it is believed) confers spiritual power and fertility. One of the most thoroughgoing analyses of primitive mythology ever undertaken was that of the French anthropologist Claude Lévi-Strauss, who concluded that, taken together, the indigenous myths of North and South America expressed men's worry that, unless women's periods were carefully monitored and synchronised, the universe might descend into chaos:
- ↑ Knight, C. (1995). Blood Relations: Menstruation and the Origins of Culture, New Haven and London: Yale University Press. Figure re-drawn after McCarthy, F. D. (1960). "The string figures of Yirrkalla" Records of the American-Australian Scientific Expedition in Arnhem Land, 415–513 , Melbourne University Press.
- ↑ 2.0 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 (1971). Menstrual Synchrony and Suppression. Nature 229 (5282): 244–5.
- ↑ 3.0 3.1 3.2 3.3 3.4 3.5 (2013). Darwin's Legacy: An Evolutionary View of Women's Reproductive and Sexual Functioning. Journal of Sex Research 50 (3–4): 207–46.
- ↑ 4.0 4.1 Gosline, Anna Do Women Who Live Together Menstruate Together?. Scientific American. URL accessed on 2 January 2012.
- ↑ 5.0 5.1 5.2 (1998). Whither menstrual synchrony?. Annual review of sex research 9: 77–95.
- ↑ 6.00 6.01 6.02 6.03 6.04 6.05 6.06 6.07 6.08 6.09 6.10 6.11 6.12 6.13 (1999). Menstrual synchrony pheromones: Cause for doubt. Human Reproduction 14 (3): 579–80.
- ↑ 7.0 7.1 7.2 (1991). Two studies of menstrual synchrony: Negative results. Psychoneuroendocrinology 16 (4): 353–9.
- ↑ 8.0 8.1 8.2 (1993). No evidence for menstrual synchrony in lesbian couples. Psychoneuroendocrinology 18 (5–6): 425–35.
- ↑ 9.0 9.1 9.2 9.3 9.4 9.5 9.6 (1992). A critical review of menstrual synchrony research. Psychoneuroendocrinology 17 (6): 565–91.
- ↑ 10.0 10.1 10.2 (2000). Menstrual-cycle variability and measurement: Further cause for doubt. Psychoneuroendocrinology 25 (8): 837–47.
- ↑ 11.0 11.1 11.2 (2001). Menstrual-cycle synchrony: Problems and new directions for research. Journal of Comparative Psychology 115 (1): 3–15.
- ↑ 12.00 12.01 12.02 12.03 12.04 12.05 12.06 12.07 12.08 12.09 12.10 12.11 (2006). Women do not synchronize their menstrual cycles. Human Nature 17 (4): 433–47.
- ↑ 13.0 13.1 13.2 13.3 13.4 (2006). Menstrual synchrony: Fact or artifact?. Human Nature 17 (4): 419–32.
- ↑ (2013). The Seasonality Thermostat: Female Reproductive Synchrony and Male Behavior in Monkeys, Neanderthals, and Modern Humans. PaleoAnthropology: 33–60.
- ↑ 15.0 15.1 Knight, Chris (1988). "Menstrual Synchrony and the Australian Rainbow Snake" Blood Magic: The Anthropology of Menstruation, 232–55, Berkeley: University of California Press.
- ↑ 16.0 16.1 Lévi-Strauss, Claude (1978). "Introduction to a Science of Mythology" The Origin of Table Manners, 221–2, London: Cape.
- ↑ Shmerling, Robert H. Menstrual Synchrony. InteliHealth. URL accessed on 20 June 2013.
- ↑ Hall, Harriet Menstrual Synchrony: Do Girls Who Go Together Flow Together?. Science-Based Medicine. URL accessed on 2 January 2012.
- ↑ MacLeod, Nadia Menstrual Synchrony. URL accessed on 17 June 2013.
- ↑ Adams, Cecil Does menstrual synchrony really exist?. The Straight Dope. URL accessed on 17 June 2013.
- ↑ includeonly>O'connor, Anaha. "The Claim: Menstrual Cycles Can Synchronize Over Time". Retrieved on 17 June 2013.
- ↑ 22.0 22.1 22.2 22.3 22.4 (1999). Menstrual synchrony: Awareness and subjective experiences. Journal of Reproductive and Infant Psychology 17 (3): 255–65.
- ↑ 23.0 23.1 (1980). Menstrual synchrony in female undergraduates living on a coeducational campus. Psychoneuroendocrinology 5 (3): 245–52.
- ↑ 24.0 24.1 (1981). Influence of male social contacts, exercise and all-female living conditions on the menstrual cycle. Psychoneuroendocrinology 6 (3): 239–44.
- ↑ 25.0 25.1 25.2 (1992). Menstrual synchrony in female couples. Psychoneuroendocrinology 17 (2–3): 171–7.
- ↑ 26.0 26.1 26.2 (1993). Multiple influences on menstrual synchrony: Kibbutz roommates, their best friends, and their mothers. American Journal of Human Biology 5 (2): 173–9.
- ↑ 27.0 27.1 27.2 (1993). Menstrual synchrony between mothers and daughters and between roommates. Physiology & Behavior 53 (5): 943–9.
- ↑ 28.0 28.1 28.2 28.3 (1997). Menstrual synchrony under optimal conditions: Bedouin families. Journal of Comparative Psychology 111 (2): 143–51.
- ↑ 29.0 29.1 29.2 (1999). Human menstrual synchrony in families and among close friends: Examining the importance of mutual exposure. Journal of Comparative Psychology 113 (3): 261–8.
- ↑ 30.0 30.1 30.2 (1999). Menstrual synchrony in a sample of working women. Psychoneuroendocrinology 24 (4): 449–59.
- ↑ 31.0 31.1 31.2 (1984). Psychosocial and biological influences on menstruation: Synchrony, cycle length, and regularity. Psychoneuroendocrinology 9 (1): 21–8.
- ↑ (December 1996). Absence of menstrual cycle synchronization in mentally affected women living in a social welfare institute. Homeostasis in Health and Disease 37 (6): 249–52.
- ↑ 33.0 33.1 33.2 (1995). Examination of menstrual synchrony among women basketball players. Psychoneuroendocrinology 20 (6): 613–22.
- ↑ 34.0 34.1 34.2 (1995). The impact of social interaction factors on menstrual synchrony in the workplace. Psychoneuroendocrinology 20 (1): 21–31.
- ↑ 35.0 35.1 35.2 (1998). Prolonged and very intensive contact may not be conducive to menstrual synchrony. Psychoneuroendocrinology 23 (1): 19–32.
- ↑ 36.0 36.1 36.2 (1997). Menstrual variability and the measurement of menstrual synchrony. Psychoneuroendocrinology 22 (2): 115–28.
- ↑ (1992). The function of menstrual taboos among the dogon. Human Nature 3 (2).
- ↑ 38.0 38.1 (1987). Lunar influences on the reproductive cycle in women. Human biology 59 (6): 959–72.
- ↑ 39.0 39.1 (1986). The Regulation of Menstrual Cycle and its Relationship to the Moon. Acta Obstetricia et Gynecologica Scandinavica 65 (1): 45–8.
- ↑ (1937). Menstrual Periodicity; Statistical Observations on a Large Sample of Normal Cases. BJOG 44 (5): 839–79.
- ↑ (1974). Independence of human menstruation on lunar phases and days of the week. American journal of obstetrics and gynecology 118 (8): 1136–8.
- ↑ Cite error: Invalid
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- ↑ 43.0 43.1 43.2 (1998). Regulation of ovulation by human pheromones. Nature 392 (6672): 177–9.
- ↑ Strassmann, Beverly (1999). Menstrual synchrony pheromones: cause for doubt. Human Reproduction 14 (3): 579–580.
- ↑ 45.0 45.1 (1999). Pheromones and regulation of ovulation. Nature 401 (6750): 232–3.
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- ↑ (1998). The assessment of menstrual synchrony: Comment on Weller and Weller (1997). Journal of Comparative Psychology 112 (3): 323–4; discussion 325–6.
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- ↑ (1989). Review Lecture: Mammalian Mating Systems. Proceedings of the Royal Society of London. Series B 236 (1285): 339–72.
- ↑ (1977). Ecology, sexual selection, and the evolution of mating systems. Science 197 (4300): 215–23.
- ↑ Dunbar, Robin I. M. (1988). Primate Social Systems, 140–3, London and Sydney: Croom Helm.
- ↑ (1979). Reproductive synchrony, parental investment, and the evolutionary dynamics of sexual selection. Animal Behaviour 27: 1022–33.
- ↑ (1984). Effects of ovulatory concealment and synchrony on protohominid mating systems and parental roles. Ethology and Sociobiology 5: 33–44.
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- ↑ (1997). On Seasonal Reproductive Synchrony as an Evolutionarily Stable Strategy in Human Evolution. Current Anthropology 38 (1): 88–91.
- ↑ Knight, C. (1995). Blood Relations: Menstruation and the origins of culture, London & New Haven: Yale University Press.Template:Page needed
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- ↑ 60.0 60.1 (2010). Pinnacle Point Cave 13B (Western Cape Province, South Africa) in context: The Cape Floral kingdom, shellfish, and modern human origins. Journal of Human Evolution 59 (3–4): 425–43.
- ↑ Knight, C. (1995). Blood relations: Menstruaiotn and the origins of Culture, London & New Haven: Yale University Press. Re-drawn after Wright, B. J. (1968). Rock Art of the Pilbara Region, North-west Australia, Canberra: Australian Institute of Aboriginal Studies.
- ↑ Knight, C. (1995). Blood relations: Menstruation and the origins of Culture, London & New Haven: Yale University Press. Re-drawn after Wright, B. J. (1968). Rock Art of the Pilbara Region, North-west Australia, Canberra: Australian Institute of Aboriginal Studies.
- ↑ McCarthy, F.D. (1960). "The string figures of Yirrkalla" Records of the American-Australian Scientific Expedition in Arnhem Land, 415–513, Melbourne University Press.
- ↑ Shostak, M. (1983). Nisa. The life and words of a !Kung woman, Harmondsworth: Penguin.
- ↑ (1982). Menstruation and the power of Yurok women: Methods in cultural reconstruction. American Ethnologist 9 (1): 47–60.
- ↑ Buckley, T. (1988). "Menstruation and the power of Yurok women" Blood Magic: The anthropology of menstruation, 187–209 [190–1], Berkely & London: University of california Press.
- ↑ Maddock, K. (1978). "Introduction" The Rainbow Serpent, The Hague: Mouton.Template:Page needed
- ↑ Maddock, K. (1978). "Metaphysics in a mythical view of the world" The Rainbow Serpent, 99–118, The Hague: Mouton.
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|Events and phases|
Amenorrhoea · Anovulation · Dysmenorrhea · Hypomenorrhea · Irregular menstruation · Menometrorrhagia · Menorrhagia · Metrorrhagia · Premenstrual dysphoric disorder · Premenstrual syndrome · Oligomenorrhea
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